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MANIPULATION OF AFFERENT FEEDBACK FROM EXTRAOCULAR
MUSCLES VIA JENDRASSIK MANEUVER IN BINOCULARLY INTACT
OBSERVERS AND DEAFFERENTED PATIENTS: EFFECTS ON VERGENCE,
VERSION AND HIGHER ORDER PERCEPTUAL JUDGEMENTS
By
Ewa Niechwiej-Szwedo
A thesis submitted in conformity with the requirements
for the degree of Doctor of Philosophy
Graduate Department of Rehabilitation Science
University of Toronto
Copyright by Ewa Niechwiej-Szwedo (2008)
ii
ABSTRACT
MANIPULATION OF AFFERENT FEEDBACK FROM EXTRAOCULAR
MUSCLES VIA JENDRASSIK MANEUVER IN BINOCULARLY INTACT
OBSERVERS AND DEAFFERENTED PATIENTS: EFFECTS ON VERGENCE,
VERSION AND HIGHER ORDER PERCEPTUAL JUDGEMENTS
Ewa Niechwiej-Szwedo
Doctor of Philosophy, 2008
University of Toronto
Graduate Department of Rehabilitation Science
The central nervous system can use two extraretinal sources to stay informed about
the position of the eyes in the orbit: outflow (efference copy) and inflow (afference). Palisade
endings (PE), found at the myotendinous junction of the multiply innervated fibers of the
global layer of extraocular muscles (EOM), are the putative receptors supplying the inflow
eye position signal. Seminal neuroanatomical tracing studies identified a distinct set of non-
twitch (NT) motoneurons whose activity does not add to the force used to move the eyes. It
has been suggested that NT motoneurons could be involved in modulating the gain of
sensory feedback from EOM analogous to the gamma-efferent fibres which control the
sensitivity of muscle spindles in skeletal muscles. The goal of this thesis was to test the
above hypothesis in humans using behavioural and psychophysical approaches. Jendrassik
Maneuver (JM), which is a forceful muscle contraction that facilitates the amplitude of all
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spinal and brainstem reflexes, was used to manipulate afferent feedback. The facilitation is
most likely due to a general up-regulation of the gamma system. It was hypothesized that if
NT motoneurons are analogous to gamma motoneurons, the JM should also increase the
activity of NT neurons and alter the afferent feedback from PE. As hypothesized, the JM
perturbation altered registered vergence eye position when binocularly intact observers
localized targets in depth but did not affect localization in the frontal plane associated with
saccades. Patients with congenital strabismus who have had surgeries on their EOM were not
affected by the JM perturbation. In contrast to the hypotheses, the JM did not affect higher
order perceptual judgments (size and depth constancies). Overall, these studies provide
insight into the putative mechanism involved in the control of sensory feedback from EOM.
In particular, the NT motoneurons might be involved in parametric adjustment of the
proprioceptive feedback loops to match the demands of different types of eye movements.
Understanding the role of proprioceptive feedback loops could have important clinical
implications for surgical treatment of strabismus.
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ACKNOWLEGMENTS
I would like to acknowledge the support of many individuals who helped and supported
me along the way in the past few years.
First, my sincere thanks go to my supervisors Marty Steinbach and Molly Verrier for
guiding me towards my goals. I have been extremely fortunate to work with Marty and
Molly, whose passion for neuroscience and life is an inspiration to all their students and
colleagues. Their support and encouragement have made this accomplishment possible.
I would also like to acknowledge the contribution of my committee members Esther
González and Agnes Wong, whose insight and direction enriched my thesis.
I also like to thank my colleagues at the Ocular Motor Lab and University of Toronto for
their support and friendship: Esther González, Linda Lillakas, Lumi Tarita-Nistor,
Olivera Karanovic, Diana Tajik-Parvinchi, Micheal Jurkiewicz and Rosalynn Miller. The
last few years have been an enjoyable and rewarding experience thanks to these new
friendships.
A special mention goes to my family who has always supported and encouraged me,
especially my parents who taught me to always strive for achievement.
I would also like to thank the late Aftab Patla for instigating my curiosity in the field of
visuomotor control.
v
DEDICATION
To my husband, Tomek Szwedo, for constantly reminding me that the journey is just as
important as the final destination.
“The only new voyage of discovery consists not in seeing new landscapes but in
having new eyes”
-Marcel Proust
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TABLE OF CONTENTS
Abstract………………………………………………………………………………………..ii
Acknowledgments……………………………………………………………………..……..iv
Dedication …………………………………………………………………………………….v
Table of Contents……………………………………………………..………………………vi
List of Tables……………………………………………………………………………........ix
List of Figures………………………………………………………………………...……….x
List of Abbreviations…………………………………………………………………...…...xiii
Glossary of Terms………………………………………………………………………...….xv
List of Appendices…………………………..………………………………………….......xvii
CHAPTER I: LITERATURE REVIEW
1.1 How does the brain know which way the eye is pointing? Inflow vs. outflow…………...1
1.1.1 Role of inflow during development……………………………………………..4
1.1.2 Role of inflow in oculomotor control…………………………………………...5
1.1.2.1 Evidence from animal studies…………………………………………5
1.1.2.2 Evidence from studies with humans…………………………………..7
1.1.3 Role of inflow in localization…………………………………………………...9
1.1.4 Summary…………………………………………………………………….....12
1.2 Extraocular muscles: anatomy, morphology and innervation……………………………12
1.2.1 Sensory receptors in extraocular muscles……………………………………...16
1.2.2 Dual innervation of extraocular muscles: proprioceptive hypothesis………….19
1.3 Role of gamma innervation in the skeletal system………………………………………21
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1.3.1 Anatomy & physiology………………………………………………………..21
1.3.2 Function: alpha-gamma co-activation…………………………………………23
1.3.3 Descending control: implications for function………………………………...23
1.3.4 Summary……………………………………………………………………….26
1.4 Jendrassik Maneuver: possible mechanisms……………………………………………..26
1.4.1 Gamma system………………………………………………………………....27
1.4.2 Alpha motoneuron excitability………………………………………………...28
1.4.3 Presynaptic disinhibition……………………………………………………….29
1.4.4 Time course of the reflex facilitation effect……………………………………30
1.4.5 Summary……………………………………………………………………….31
CHAPTER II: RESEARCH OBJECTIVES & HYPOTHESES………………………..33
CHAPTER III: RESULTS
3.1 Paper 1: Proprioceptive role for palisade endings in extraocular muscles: evidence from
the Jendrassik Maneuver……………………………………………………………………..35
3.2 Paper 2: Localization in the frontal plane is not susceptible to manipulation of afferent
feedback via the Jendrassik Maneuver……………………………………………………....67
3.3 Paper 3: Manipulation of extraocular muscles has no effect on higher order perceptual
judgments…………………………………………………………………………………….90
3.4 Paper 4: Localization in depth is not affected by the Jendrassik Maneuver in patients
operated for strabismus: case studies………………………………………………………118
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CHAPTER IV: GENERAL DISCUSSION
4.1 Summary of findings……………………………………………………………………131
4.2 Significance of the project……………………………………………………………...132
4.3 Limitations of the project……………………………………………………………….135
4.4 Future directions………………………………………………………………………..136
REFERENCES……………………………………………………………………………139
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LIST OF TABLES
Table 1: Primary and secondary actions of the EOM and their efferent innervation ……...13
Table 2: Parameters obtained from the linear regression model for individual
participants (Experiment 3, Paper 3)……………………………………………………..106
Table 3: Patients’ clinical characteristics and surgical procedures (Paper 4)…………….124
x
LIST OF FIGURES
Paper 1
Figure 1: Schematic illustration of the experimental protocol used in experiment 1: (a)
control task; (b) Task 1: look and point during JM; (c) Task 2: look during JM and point
after JM………………………………………………………………………………………47
Figure 2: Experiment 1: Mean pointing error of the hand. The figure illustrates the significant
difference between Task 2 and the other two conditions (Control and Task1). Error bars show
±1 standard error……………………………………………………………………………..48
Figure 3: Experiment 1: Average vergence-specified distance for near and far targets in all
the tasks. The targets were shown at a distance of 25 cm and 45 cm from the participant
which is shown by the dotted lines…………………………………………………………..49
Figure 4: Schematic representation of the experimental procedures used in
experiment 2………………………………………………………………………………....54
Figure 5: Mean proportion of ‘near’ responses for each comparison target location (at 0 both
targets were presented at the same location). Error bars show +1 standard error. ………….56
Figure 6: Differences in the POE between the Control condition and Tasks 1 and 2 for
individual participants (ID 1 to 20). The y-axis represents the difference in proportion of
‘near’ responses between Task 1 and Control & Task 2 and Control. Positive values indicate
xi
that the comparison target was reported as ‘nearer’ and negative values indicate that the
comparison target was reported as ‘farther’ with respect to the control task……………......57
Figure 7: Summary and interpretation of results for experiment 2……………………….…59
Paper 2
Figure 8: Schematic illustration of the experimental protocol used in experiment 1: (a)
control: no JM; (b) task 1: JM performed during saccade and pointing; (c) task 2: JM
performed during saccade, but not during pointing…………………………………………76
Figure 9: Distribution of pointing responses obtained in experiment 1. The boxplot contains
the middle 50% of the data (the upper edge is the 75th
percentile and the lower edge is the
25th
percentile), the line in the box represents the median. The lines extending from the
boxplot (whiskers) indicate the 1st and 99
th percentile………………………………………78
Figure 10: Schematic illustration of the experimental protocol used in experiment 2: (a)
control: no JM; (b) task 1: JM performed during the presentation of the standard target and
saccade; (c) task 2: JM performed during perceptual localization………………………….82
Figure 11: Mean proportion of ‘left’ responses for the five comparison targets (at 10 both
the standard and comparison target were presented at the same location). (a) standard target
presented in the left hemifield; (b) standard target presented in the right hemifield. Error bars
show +1 standard error of the mean………………………………………………………....84
xii
Paper 3
Figure 12: Schematic illustration of the experimental protocol used in experiment 1………99
Figure 13: Mean proportion responding ‘smaller’ for each of the five sizes of the comparison
square (at 0 both the standard and comparison squares were the same physical size, negative
values indicate that the comparison square was smaller). Error bars show +1 standard
error………………………………………………………………………………………...101
Figure 14: Mean perceived depth for stereoscopically presented stimuli in experiment 2.
Error bars show +1 standard error………………………………………………………….107
Figure 15: Mean values obtained when participants were asked to null the Pulfrich illusion by
adjusting the value of the variable filter. Error bars show +1 standard error………………112
Paper 4
Figure 16: Psychometric functions of the patients tested. The location of the comparison
target with respect to the standard is shown in cm with positive values indicating nearer and
negative values farther positions from the observer. Proportion of ‘near’ responses for each
comparison target location (at 0 both targets were presented at the same location)………..126
xiii
ABBREVIATIONS
Ia: primary afferent
IIa: secondary afferent
: gamma system
2-AFC: two alternative forced choice
APH: active pulley hypothesis
ANOVA: analysis of variance
CNS: central nervous system
EMG: electromyography
EOM: extraocular eye muscles
GTO: golgi tendon organs
IO: inferior oblique
IR: inferior rectus
JM: Jendrassik Maneuver
JND: just noticeable difference
LED: light emitting diodes
LR: lateral rectus
mesADC: mesencephalic area for dynamic control
MIF: multiply innervated fibers
MR: medial rectus
ND: neutral density (filter)
PE: palisade endings
POE: point of objective equality
PSE: point of subjective equality
PSI: presynaptic inhibition
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NT: non-twitch
SIF: singly innervated fibers
SO: superior oblique
SR: superior rectus
SOP: superior oblique palsy
V1: primary visual area (striate cortex)
VOR: vestibulo-ocular reflex
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Glossary of Terms
Afference: detection of the activity produced by sensory receptors by the central nervous
system.
Binocular (or retinal) Disparity: the difference in spatial distribution of light in the two
retinal images, basis of stereopsis.
Cyclopean eye: point midway between the eyes which serves as a centre of reference for
headcentric directional judgements (origin of binocular vision) (Howard, 2002).
Depth constancy: observers perceive the depth of an object as relatively constant despite
changes in image size at different fixation distances.
Distal size: the real or physical size of an object.
Efference copy (corollary discharge): a copy of the motor signal generated to distinguish
the reafferent and exafferent signals (McClosky, 1981).
Esotropia: eye(s) deviate towards the nose.
Exafference: sensory activity produced by external factors.
Exotropia: eye(s) deviate temporally.
H-reflex (Hoffman reflex): an electrical counterpart of the tendon reflex elicited by
stimulating the mixed peripheral nerve, thus, activating the Ia afferent directly and bypassing
the activation of muscle spindles.
Horizontal Disparity: an interocular difference in the horizontal angle subtended by a pair
of points.
Inflow: afferent signals produced by the receptors in the muscles.
Jendrassik Maneuver (JM): a muscle contraction during which the amplitude of spinal and
brainstem reflexes is amplified.
Just noticeable difference (JND): is the smallest possible physical difference that can be
detected reliably and it reflects the precision of the judgment.
Myotomy: surgery on the extraocular eye muscles to correct strabismus which involves
weakening the muscle by reducing the number of contractile elements.
Outflow: copy of the motor command sent to structures within the central nervous system.
Phoria: the relative position of the eyes in the absence of binocular fusion.
xvi
Point of objective equality (POE): the point at which the comparison stimulus value
physically equals the value of the standard stimulus.
Point of subjective equality (PSE): the point at which the psychometric function yields a
probability of 0.5 (i.e. the comparison stimulus is perceived as smaller than the standard
stimulus 50% of the time) and it reflects the accuracy of the judgment.
Proximal size: the size (visual angle) of the image subtended on the retina.
Pulfrich illusion: a pendulum objectively swinging in the frontal plane appears to move in
an elliptical orbit in depth when one eye is viewing the stimulus through a neutral density
filter.
Reafference: sensory activity produced by organism’s own movement.
Recession: surgery on the extraocular eye muscles to correct strabismus which involves
weakening the muscle by changing the tangential force. It involves cutting the muscle tendon
close to insertion and reinserting it on the sclera posterior to the original insertion.
Registered eye position: internally generated estimate of the position of the eyes in the
orbits based on visual and non-visual (afferent and efferent) signals.
Resection: surgery on the extraocular eye muscles to correct strabismus to strengthen the
muscle. It involves shortening the length of the muscle by excising a portion of the tendon
and reinserting it to the original insertion.
Size constancy: observers perceive the size of an object as relatively constant despite
changes in retinal size at different fixation distances.
Stereoscopic vision: literally “solid sight”, visual perception of 3D structure of the world
from binocular vision (Howard, 2002).
Strabismus: misalignment of the eye(s).
Trigeminal-oculomotor synkineses: abnormal efferent innervation of the medial rectus by
the trigeminal nerve.
Vergence: disjunctive eye movements (eyes move through equal angles in opposite
directions) to fixate a target closer to the body (convergence) or farther away (divergence).
Vergence Specified Distance: fixation distance in the sagital plane specified by the vergence
angle of the eyes.
xvii
List of Appendices
Appendix 1 …………………………………………………………………………………157
1
CHAPTER I: LITERATURE REVIEW
1.1 How does the brain know which way the eye is pointing? Inflow vs. Outflow
Knowledge of eye position is critical for accurate visuomotor behavior. For instance,
to make an accurate reaching movement to pick-up an object, the central nervous system
(CNS) must combine several signals: the position of the hand and head, as well as the retinal
location of the object and the position of the eyes. The CNS can obtain eye position
information from two non-visual sources: inflow and outflow. Outflow refers to the efferent
motor command that is sent to the eye muscles, a copy of which is also sent to other
structures within the CNS to generate the expected sensory consequences of a given motor
command (efference copy or corollary discharge; for a detailed discussion, see Donaldson,
2000). Inflow refers to the signals that are sent from the eye muscle proprioceptors that
monitor eye position.
Although there is no question that the CNS must obtain eye position information, the
debate between outflow and inflow as the source of the signal has been longstanding and
goes back to Helmholtz and Sherrington (Bach-y-Rita, 1971. For an extensive historical
review see Grusser, 1995). Helmholtz was a proponent of the outflow theory. His support for
this theory was based on a classical experiment which showed that passive displacement of
the eye, by pressing on the outer canthi, results in perceived movement of the visual
surroundings whereas the same movement executed voluntarly does not lead to the illusion.
Helmholtz argued that if the passive movement of the eye changed the afferent signal without
changing the efferent innervation and if feedback is used by the CNS, there should be no
illusory motion of the visual environment. The fact that subjects reported illusory motion
during the experiment suggested that the afferent signals were not being used by the CNS.
2
Helmholtz's view was directly opposed by Sherrington, who was a proponent of the
‗muscle sense‘. Sherrington's support for the inflow theory was based on his own research:
the dicovery of muscle spindles in skeletal muscles and their role in the control of movement
via spinal feedback loops. Sherrington believed that there must be a feedback loop involving
proprioceptors from the eye muscles because they contain a large number of spindles and eye
movements are precisely controlled. Unfortunately, Sherrington never provided any
experimental evidence for the role of eye muscle proprioceptors in oculomotor control.
Helmholtz provided strong experimental evidence supporting the outflow theory.
Other authors looked for additional support using different methods. For instance, Siebeck
(1953, 1954 as described in Matin, 1976), Brindley, Goodwin, Kulikowksi and Leighton
(1976) and Stevens et al. (1976) used curare to paralyze the eye muscles. It was argued that if
outflow were the only source of eye position information, subjects should report illusory
movement of the visual scene when they attempted to move their eyes (i.e., if the eyes could
not move, the afferent signal would not change but the efferent signal would change). The
results of these studies did not fully support the outflow theory: illusory movement was
perceived only with partial parlysis but not with full paralysis, suggesting that the CNS did
use afferent feedback from eye muscles.
There have been two other major arguements against ocular proprioception. First,
unlike skeletal muscles, eye muscles act against a constant load. Consequently, a copy of the
motor command should theoretically provide sufficient information about the state of the
oculomotor plant. Evidence against this assumption was presented by Steinbach and Lerman
(1990) who demonstrated that in the case of the human eye, the centre of rotation is located
behind the center of mass suggesting that orbital proprioception might be important, as it is
3
for other skeletal muscls which are operating under changing loads, because the head‘s
position with respect to gravity changes. Second, an important function of proprioceptors in
the skeletal muscles is regulation of muscle length in response to stretch; however, the
presence of stretch reflexes in extraocular muscles (EOM) is controversial. A classic
experiment by Keller and Robinson (1971) in awake rhesus monkeys found no change in the
activity of the abducens motoneurons in response to muscle stretch. Similar results were
obtained in the oculomotor nucleus of cats by Tomlinson and Schwarz (1977). In contrast,
Dancause and colleagues (Dancause et al., 2007) have recently recorded electromyographic
activity in the horizontal recti muscles in lightly anesthesized rats and squirrel monekys in
response to passive eye rotation. This is the first study to suggest that stretch reflexes might
be present in the EOM but more studies are needed to confirm these findings.
Although the presence of monosynaptic stretch reflexes in the EOM have been
questioned, there is substantial evidence to support the inflow theory. First, neural activity in
response to passive stretch of the EOM has been recorded in many CNS structures: the
cerebellum, superior colliculus, lateral geniculate nucleus, and the primary visual cortex (for
a review see Donaldson, 2000). Second, highly trained observers whose eyes were moved
passively were able to report the correct direction of their eye movements in 70% of trials
(Skavenski, 1972).
In summary, the inflow theory has been neglected for many years but there is now
ample evidence to suggest that both inflow and outflow signals are used by the CNS. The
contribution of these signals might depend on the oculomotor task and the experimental
methodology. The next section will provide an overview of the role of EOM proprioception
during development, in oculomotor control, and in visuomotor behavior.
4
1.1.1 Role of inflow during development
Over the past 20 years many experiments have been conducted in an attempt to
understand the role of eye muscle proprioception in the development of visual function,
oculomotor control and visuomotor coordination using animal models. In animals,
deafferentation can be performed by sectioning the ophthalmic division of the trigeminal
nerve. Buisseret et al. (1995) conducted a series of studies examining the effects of
deafferentation on the development of binocular cells and orientation selective cells in visual
area V1, and reported that the development of these cells is dependent on sensory feedback
from the eye muscles. For example, complete deafferenation precludes the development of
orientation selective cells; specifically, eliminating proprioceptive input, via bilateral
deafferentation, from the horizontal EOM disrupts the development of vertically tuned cells.
The effect of deafferentation on functional deficits, such as depth perception, depends
on the developmental stage of the animal. For example, Graves, Trotter and Freganc (1987)
examined depth perception in kittens who were deafferented between 5-11 weeks of age and
those who were deafferented later, as adults. Depth perception deficits were only evident in
the animals who lost proprioception early during development and not in those who were
deafferented as adults. Overall, the deafferentation experiments suggest that during
development efference copy and visual experience do not provide sufficient information, and
that afferent feedback is critical for the optimal development of the oculomotor and visual
systems.
5
1.1.2 Role of inflow in oculomotor control
1.1.2.1 Evidence from animal studies
EOM afference has been implicated in maintaing eye stability in the dark. For
instance, Fiorentini and Maffei (1977) sectioned the ophthalmic branch of the trigeminal
nerve which resulted in pendular movements (only the horizontal component was measured)
of the ipsilesional eye when the animals were placed in an unstructured visual environment.
In addtion, cats showed asymmetric vestibular nystagmus after deafferentation which was
only present in the dark. Other studies have also found fixation instability and asymmetric
vestibulo-ocular reflex (VOR) in lambs (Pettorossi, Ferraresi, Draicchio, Errico, Santarelli &
Manni, 1995) and altered VOR gain in decerebrate pigeons (Hayman & Donaldson, 1995).
In contrast, several studies reported that deafferentation had no effect on the
programming and execution of saccades, smooth pursuit and VOR. Guthrie, Porter and
Sparks (1983) reported that efference copy provides sufficient information about eye position
for the programming of saccades. In their study, rhesus monkeys performed a double saccade
task: when the saccadic target was extinguished, the superior colliculus was micorstimulated
to change eye position and the animal had to make a compensatory saccade to the original
saccadic target location. Thus, to perform this task accurately, the animal had to take into
account the change in eye position due to stimulation. It was hypothesized that if inflow
contributes to eye position sense, the animal should not be able to perform this task after
deafferentation. Experimental data showed that the surgery did not affect performance, which
supported the outflow theory.
Lewis, Zee, Hayman, Tamargo (2001) also found that bilateral deafferntation did not
affect eye aligment, saccadic amplitude or conjugacy, saccadic adaptation, or the acceleration
6
and gain of smooth pursuit and VOR in rhesus monkeys. No differences in any of these
parameters were found in the five-week follow up. Similiarly, the accuracy and variability of
open-loop pointing was not affected significantly by the surgery (Lewis, Gaymard &
Tamargo, 1998).
An important insight into the role of afference in oculomotor control was provided by
Lewis and colleagues (Lewis, Zee, Gaymard & Guthrie, 1994; Lewis, Zee, Goldstein &
Guthrie, 1999). They conducted two studies which examined the effect of deafferentation on
eye alignment, saccade conjugacy, and post saccadic drift in rhesus monkeys. Prior to
deafferntation, the animals underwent surgery to weaken the inferior rectus muscle which
resulted in vertical muscle palsy and eye misalignment. Following the deafferenting surgery,
animals were tested over a time period of 3 weeks. Deafferentation resulted in a signficant
increase in eye misalignement (from 0.47 to 2.9), and eye conjugacy—indicated by the
pulse/pulse ratio—decreased by 10% (Lewis et al., 1994). Although there were no consistant
changes in post-saccadic drift, it was significantly altered (Lewis et al., 1999).
The critical difference between the studies that found that deafferentation affected
oculomotor control and those that found no difference is the fact that Lewis and colleagues
(1994, 1999) introduced a perturbation (surgery) to the oculomotor plant prior to
deafferentation. The surgery changed the properties of the oculomotor plant so that the
efferent commands were no longer appropriate. Lewis and colleagues proposed that sensory
feedback is necessary to inform the CNS about the peripheral changes in order to maintain
accurate occulomotor control. In contrast, no perturbations were applied to the oculomotor
plant in the studies that found no difference in oculomotor control following deafferentation,
which might in part explain the different results.
7
It is surprising that all the studies reviewed above examined versional eye movements
but negelcted vergence eye movements. Given that precise eye alignment is required in order
to maintain clear binocular vision, it could be hypothesized that deafferentation might have a
more significant effect on vergence than on version. This hypothesis was confirmed by
Guthrie, Porter and Sparks (1982) who reported that cutting the monkeys‘ ophthalmic branch
of the trigeminal nerve altered their vergence responses but had no effect on conjugate eye
movements.
A role for ocular proprioception in improving eye alignment after superior oblique
palsy (SOP) was recently proposed by Shan et al. (Shan et al., 2007). They sought to
determine the ‗ocular motor signature‘ of acquired SOP in rhesus monkeys in acute and
chronic stages. The operated eye was patched for 10 days after the surgery while changes in
vertical alignment were measured with the normal eye fixating. The authors were surprised to
find an improvement in the vertical alignment of the covered eyes during the period of
monocular viewing. They suggested that the CNS might be using a proprioceptive signal
from the operated, patched eye to achieve comitance.
1.1.2.2 Evidence from studies with humans
Passive eye deviation using a suction scleral contact lens has been used to examine
whether afferent feedback from eye muscles affects the programming and execution of
saccadic eye movements and smooth pursuit. Knox, Weir and Murphy (2000) reported that
saccadic amplitudes were decreased by approximately 20% and the amplitude-velocity
relationship did not change when the movement of the non-viewing eye was impeded. The
velocity of smooth pursuit was also significantly lower (~15%) when afferent feedback was
8
perturbed. Moreover, these effects were evident in all trials in the epoch 40-80 ms after the
initiation of the eye movement but not within the first 40 ms (Weir & Knox, 2001). These
data suggest that afferent feedback from the impeded eye can be used on-line during the
programming and excution of eye movements.
Insight into the role of EOM proprioception in visuomotor behavior was provided by
vanDonkelaar, Gauthier, Blouin and Vercher (1997). They used an experimental paradigm
which involved adaptation of the smooth pursuit system while the movement of one eye was
impeded via a suction scleral lens. During the adaptation procedure subjects tracked a target
moving at a constant velocity while a proportion of the recorded eye motion signal was
added to the target's motion. The adaptation procedure was performed when the movement of
the non-viewing eye was blocked and the gain of smooth pursuit was examined during the
adaptation as well as during pre- and post-tests. The target was presented for a short duration
(300 ms) during the post test so that smooth pursuit was executed with limited visual
feedback. Results from the study showed a signifcant difference (increase of 50%) in smooth
pursuit gain during the post-test between the control condition and the condition where
afferent feedback was altered during the adaptation. Interestingly, only a small difference in
gain (10%) was found between these condtions during the adaptation procedure. The authors
suggested that during the adaptation procedure the retinal motion signal was the same for
both conditions but this signal was associated with different afferent feedback. Therefore,
afferent information plays a role during adaptation when the relationship between efferent
and afferent signals must be modified.
9
1.1.3 Role of inflow in localization
Many studies have examined the role of inflow in accurate estimation of egocentric
distance. In the following section, studies involving manipulation of afferent feedback in
healthy subjects are discussed first, followed by studies involving patients with disrupted
proprioception.
In the past, two methods have been used to manipulate feedback from the eye
muscles: vibration stimuli applied over the muscle and passive deviation of the eye using a
suction lens. Vibration provides a good stimulus for activating the Ia afferent, which in
skeletal muscles activates the monosynaptic stretch reflex (i.e., contraction of the vibrated
muscle). Roll, Velay and Roll (1991) applied vibration over the inferior rectus muscle while
subjects were fixating a single light in the dark. During the vibration trials, subjects reported
that the target moved up and they also pointed above the target. Similar results were also
obtained by Velay, Roll, Lennerstrand and Roll (1994) where vibration of the right lateral
rectus muscle resulted in an illusory movement of the target to the left. Overall, results from
these studies suggest that vibration of an EOM muscle leads to a perception that the muscle is
lengthening, and participants report that the target is moving in a direction opposite to the
vibrated muscle.
The afferent signals from eye muscles can be altered by passively moving the eye
using a suction lens. This method, introduced by Gauthier, Nommay and Vercher (1990a,b),
offers a way of distinguishing the contributions of inflow and outflow to registered eye
position. The paradigm involves subjects fixating a target with one eye while the other eye is
occluded with a patch. In the first experimental condition, the fixating eye is deviated via a
suction lens, thus, in order to maintian fixation, the amount of innervation sent to the eye
10
muscles must be increased. Since both eyes receive the same amount of innervation during
conjugate eye movements (Hering's law), the occluded eye should deviate by an amount
corresponding to the efferent signal sent to the fixating eye. In this condition, the efferent
signal to the eye muscles must be increased to compensate for the perturbation, but the
afferent feedback from the fixating eye is not changing because the eye is not changing
position. Therefore, this task allows us to examine the effect of efference on registered eye
position. The second experimental condition involves passive deviation of the occluded eye.
In this case, the amount of innervation does not change, but the afferent feedback from the
deviated eye does change; therefore, this condition allows us to examine the contribution of
afference to regitstered eye position. Using the above paradigm, Gauthier et al. (1990a,b)
found that binocularly normal observers mislocalized the target in the direction of the eye
deviation when pointing with their hands or verbally reporting the straight-ahead direction. It
was estimated that the contribution of proprioception to knowledge of eye position was
approximately 32%.
A similiar study, using the eye-press technique instead of a suction lens to deviate the
eye, was conducted by Bridgman and Stark (1991). Results from the study were in
remarkable agreement with the data from Gauthier et al. (1990a,b) and the estimated
contribution of proprioception to eye position sense was 26% with a threshold of
approximately 10. In short, both studies reported greater perceptual localization and
pointing errors when the viewing eye was pressed, indicating that the CNS relied on the
efference to a greater extent but the contribution of afference could not be ignored.
Several studies have shown that patients with pathologies that disrupt proprioceptive
signals from eye muscles have deficits in localization of objects when tested using an open-
11
loop pointing task. For instance, patients with a pathology involving the trigeminal nerve
have increased pointing errors (Steinbach, 1986; Ventre-Dominey, Dominey & Sindou,
1996). Mislocalization errors are also evident immediately after surgery in patients with
strabismus who have undergone multiple surgeries to correct their eye alignment (Steinbach
& Smith, 1981). The Steinbach and Smith study provided a critical insight by identifying the
putative source of proprioceptive feedback. The surgical intervention for starbismus involved
cutting the muscle at the muscle-tendon junction which is where palisade endings (PE), the
putative proprioceptors, are also found. Since the localization deficit was not found in
patients after the first surgery, it is likely that each surgery destroyed the putative EOM
proprioceptors to a certain degree and after multiple surgeries patients were left deafferented.
Evidence highlighting the contribution of proprioception to knowledge of eye
position has also been provided by Lewis and Zee (1993) who studied spatial localization in
a patient with abnormal innervation of the medial rectus muscle. Due to trigeminal-
oculomotor synkineses the patient‘s left eye adducted every time the jaw moved to the right,
which presented a case in which the efferent command to the EOM was dissociated from the
afferent feedback. As hypothesized, the accuracy of open-loop pointing responses was
affected by the synkineses: the responses were shifted in the direction opposite to the rotation
of the affected eye, which is in contrast to what was reported by Gauthier et al. (1990a,b) and
Bridgeman and Stark (1991) (i.e., mislocalization was always in the direction of the deviated
eye). Lewis and Zee suggested that active muscle contraction and passive rotation might
activate the putatitve EOM proprioceptors differentially; specifically, they suggested that PE,
which are in series with the muscle fibres, will be activated to a greater extent during active
contraction compared to passive rotation of the eye.
12
1.1.4 Summary
There is ample evidence from animal and human studies to suggest that afferent
signals from the EOM are used by the CNS for optimal oculomotor control. In particular,
inflow is important during the critical period of development and during adaptation after
properties of the oculomotor plant change. Overall, the CNS relies on efference to a greater
extent, but the contribution of afference to registered eye position is also evident during
motor and perceptual tasks. In particular, while the contribution of inflow to versional eye
movements has been examined extensively, vergence has been largely ignored and should be
examined more carefully.
1.2 Extraocular muscles: anatomy, morphology and innervation
The concept of the ‗oculomotor plant‘ refers to the eye muscles, the motor nuclei and
the cranial nerves, and it is the final common pathway through which cortical centers control
different types of eye movements (Robinson, 1981). The oculomotor plant has been studied
in great detail throughout the years; however, the advent of novel imaging and tracing
techniques has led to an emergence of new concepts and theories of eye movement control.
The purpose of this section is to provide a brief overview of the six extraocular eye muscles
(EOM) focusing on their anatomy, morphology and innervation.
The primary and secondary actions of the EOM and their efferent innervation are
shown in Table 1. The pulling action of eye muscles corresponds to the plane of the
semicircular canals, presumably to simplify the control of eye movements during VOR. The
six EOM are arranged in synergistic pairs—for instance, to execute a conjugate eye
movement in the horizontal plane, the ipsilateral medial rectus (MR), and contralateral lateral
13
rectus (LR) would contract. According to Hering‘s law, synergistic muscles in the two eyes
receive equal innervation to simplify the control of conjugate eye movements.
Table 1: Primary and secondary actions of the EOM and their efferent innervation
EOM Primary action Secondary action Innervation
Medial Rectus Adduction __ Inferior division of
oculomotor nerve
Lateral Rectus Abduction
__ Abducens nerve
Superior Rectus Elevation Intorsion Superior division of
oculomotor nerve
Inferior Rectus Depression Extorsion Inferior division of
oculomotor nerve
Superior Oblique Introsion Depression
Trochlear nerve
Inferior Oblique Extorsion Elevation Inferior division of
oculomotor nerve
Muscle fibers in the EOM can be classified into several types based on their
innervation, morphological, histochemical and contractile properties. The following six fiber
types have been identified: singly and multiply-innervated orbital fibers, singly innervated
red and pale global fibers, multiply-innervated global fibers, and singly innervated global
intermediate fibers (Spencer & Porter, 1988). The classification of fibers as orbital and global
has been made based on their location so that global fibers are closest to the globe of the eye
and the orbital fibers are found near to the orbital wall. A recent study reported that the
global layer contains a larger number of muscle fibers and that the number of fibers among
the recti muscles in the global layer is constant. On the other hand, the number of fibers in
the orbital layer was found to vary up to 58% between the recti muscles, with the largest
number of fibers found in the MR (Oh, Poukens, & Demer, 2001).
14
The orbital layer is composed of approximately 80% singly innervated fibers (SIF),
and the remaining 20% are multiply innervated fibers (MIF). The SIF have a high oxidative
capacity due to numerous, prominent mitochondria and a substantial vascular supply, thus,
these fibers are resistant to fatigue. The MIF of the orbital layer exhibit different
histochemical and electrical properties along the length of the fiber. The mid-region of the
fiber has a larger number of mitochondria in comparison to the proximal and distal ends.
Electrical stimulation of the mid-region also leads to generation of action potentials; in
contrast, only slow, graded potentials can be recorded distal to the end-plate (Jacoby,
Chiarandini, & Stefani, 1989).
The global layer contains four types of SIF which differ in their metabolic capacity.
The red fibers contain a large number of mitochondria and show oxidative metabolism, the
pale fibers have few mitochondria and rely on anaerobic metabolism. The intermediate fibers
have both aerobic and anaerobic metabolic capacity. The global layer contains approximately
10% MIF, which respond to electrical stimulation with slow potentials that have a small
amplitude and long duration. Unlike the orbital MIF, these fibers respond uniformly when
stimulated along the length of the muscle. On average, the motor unit size of global fibers is
smaller than that of the orbital fibers, which suggests that the force can be increased with
greater precision by the global fibers (Oh et al., 2001).
Five of the EOM: MR, LR, superior rectus (SR), superior oblique (SO), and inferior
rectus (IR) originate in the tendinous ring (annulus of Zinn) at the apex of the orbit. The
origin of the inferior oblique (IO) is from the maxillary bone in the medial wall of the orbit
(Spencer & Porter, 1988). The muscles are composed of twenty to thirty thousand fibers and
their length varies between 40 and 50 mm (Carpenter, 1988). The fact that the SO muscle
15
inserts through a pulley, the trochlea, has been known for a quite a long time, but only recent
imaging studies have shown that the other EOM might also have a pulley insertion. Demer
and colleagues (Clark, Miller & Demer, 1997, 2000; Demer, Oh & Poukens, 2000; Demer,
2002) used high resolution magnetic resonance images and histology to demonstrate that the
orbital layers of the muscles insert onto a ring of collagen tissue located near the equator of
the globe in Tenon‘s fascia, which is now being considered as the functional origin of the eye
muscles. The discovery that eye muscles have a dual insertion, with the orbital layer inserting
on a pulley and the global layer inserting on the globe via a tendon, has functional
implications for the control of eye movements and led Demer to propose the active pulley
hypothesis (APH). The APH states that the contraction of fibers in the orbital layer
influences the position of the pulleys, and thereby affects the rotational axis of the EOM,
whereas contraction of the muscle fibers in the global layer directly affects the rotation of the
globe.
The eye muscles receive motor innervation from the motor nuclei in the midbrain and
pons via cranial nerves III (oculomotor), IV (trochlear), and VI (abducens). Two types of
efferent nerve endings are found on the EOM fibers: single, large end-plates (en plaque) and
multiple, small fiber endings (en grappe). Fibers that receive single innervation (i.e., SIF)
have regularly spaced fibrils, large number of sarcoplasmic reticulum, and a well developed
transverse tubule system, which allows these fibers to conduct fast action potentials. In
contrast, the MIF have poorly developed sarcoplasmic reticulum and do not generate action
potentials; instead they generate a prolonged, graded response when stimulated at thresholds
that are 3-6 times greater than the most excitable SIF (Eakins & Katz, 1972). Thus, the MIF
are sometimes referred to as non-twitch fibers.
16
Many studies have shown that the relationship between eye position and firing
frequency of the motoneurons is highly correlated (Carpenter, 1988). However, a study by
Mays and Porter (1984) reported that the relationship between eye position and firing rate is
also dependent on the type of eye movement. In their study, recordings were made from the
motoneurons in the abducens nucleus during conjugate adduction and during convergence.
Data showed that for a given eye position there was increased firing rate when convergence
was compared to conjugate adduction. Expanding on these results, Miller, Bockisch and
Pavlovski (2002) measured the oculorotary forces in the LR and MR muscles to test the
hypothesis that the force in LR should be higher in the converged state. In contrast to their
hypothesis, they found decreased force in both the LR and MR muscles. These results show
that the innervation of the EOM is much more complex than previously acknowledged, and it
is possible that the motor commands to the eye muscles differ during versional and vergence
eye movements.
1.2.1 Sensory receptors in extraocular muscles
The EOM contain several receptors that could potentially provide the CNS with eye
position information: muscle spindles, golgi tendon organs and palisade endings. Muscle
spindles, which are the primary proprioceptors in the skeletal muscles, have been found
predominately in the orbital layer of the EOM in several species: human, sheep, pig and
some primates, but not in other species, such as cat, rabbit, horse and mouse (Maier,
DeSantis & Eldred, 1974). Detailed histological studies of EOM spindles have shown that
they are different from the skeletal spindles. For example, Ruskell (1989) examined spindles
in the EOM of enucleated patients and reported that more than 50% of EOM spindles were
17
indistinguishable from extrafusal fibers as they were not enclosed in a capsule and did not
have a defined equatorial region. He also observed that nuclear bag fibers were virtually
absent, which was confirmed by Lukas, Aigner, Blumer, Heinzl and Mayr (1994) and
Blumer, Lukas, Aigner, Bittner, Baumartner and Mayr (1999). These authors concluded that
due to the morphological differences between spindles in the EOM and those found in the
skeletal muscles, it is unlikely that EOM spindles could provide adequate eye position
information.
Another type of receptor in skeletal muscles is the golgi tendon organ which is found
in series with the muscle fibers and signals muscle tension. Tendon organs have been found
in the ungulate but not in human EOM, therefore, their contribution to knowledge of eye
position cannot be not generalized across species (Ruskell, 1999).
Palisade endings (PE) are receptors unique to EOM, and they are associated with the
MIF of the global layer. They are sometimes referred to as innervated myotendinous
cylinders and have been found in the eye muscles of all species tested to date: cat, sheep, rat,
monkey and human (Alvarado-Mallart & Pinçon-Raymond, 1979; Blumer, Lukas, Wasicky
& Mayr, 1998; Buttner-Ennever, Horn, Scherberger & D'Ascanio, 2001; Eberhorn, Horn,
Eberhorn, Fischer, Boergen & Buttner-Ennever, 2005; Richmond, Johnston, Baker &
Steinbach, 1984). However, Bruenech and Ruskell (2000) did not find any PE in the cadaver
material from human infants. Anatomical studies show that the PE are enclosed in a capsule
at the distal end of the global MIF fiber. A thinly myelinated axon runs along the muscle
fiber and then loops back to enter the capsule as it bifurcates into several branches (Alvardo-
Mallart & Pinçon-Raymond, 1979; Richmond et al., 1984). It has been proposed that PE
18
might be activated by muscle contraction rather than muscle stretch due to their location at
the myotendious junction (Richmond et al., 1984).
Several studies provide morphological and histological evidence suggesting that PE
are sensory receptors which could provide the CNS with proprioceptive information about
eye position. Alvardo-Mallart & Pinçon-Raymond (1979) reported that PE in cats were
associated with the presence of clear vesicles common in other sensory endings, such as
Golgi tendon organs and muscle spindles. They also suggested that the presence of a capsule
is indicative of sensory receptors because the capsule, which is commonly found around
other receptors, protects them from external pressures. Retrograde and anterograde tracing
studies provide corroborating evidence to support the claim that PE are sensory receptors:
Porter and Spencer (1982) injected horseradish peroxide into EOM and neurons were labeled
in the trigeminal ganglion; similarly, Billig, Buisseret-Delmas & Buisseret (1997) reported
that PE were labeled when tracers were injected into the Gasserian (trigeminal) ganglion.
More recently, several studies have shown that in addition to the sensory endings, the
musculotendinous region in the human, rabbit, cat and rhesus monkey EOM also contains
motor endings (Blumer, Wasicky, Hoetzenecker, & Lukas, 2001; Konakci, Streicher,
Hoetzenecker, Blumer, Lukas & Blumer, 2005; Konakci, Streicher, Hoetzenecker, Haberl et
al., 2005; Lukas, Blumer, Denk, Baumgartner, Neuhuber & Mayr, 2000). The motor endings
were identified based on staining of the myoneuronal junction with bungarotoxin, which
labels post-synaptic acytocholinergic neurons. Upon microscopic examination, these authors
also found basal lamina, which is indicative of motor terminals. In contrast, at least one study
did not confirm the presence of motor terminals at the musculotendinous junction of the
19
EOM. Eberhorn, Horn, Fischer and Buttner-Ennever (2005) used bungarotoxin in the EOM
of rats and found no evidence of motor terminals on the PE.
Hertle and colleagues (Hertle, Chan, Galita, Maybodi & Craford, 2002) reported
another type of receptor in the EOM: the enthesial ending and suggested that it might have a
proprioceptive function. The enthesial ending is also associated with fibers of the global
layer, but it is found in the tendino-scleral region of the muscle. Hertle et al showed that the
enthesial area consisted of myelinated and unmyelinated nerve fibers with abundant vascular
supply in healthy control subjects, but neurovascular abnormalities were evident in case of
subjects with congenital nystagmus. The proprioceptive role of enthesial endings has not
been examined to the same extent as that of PE. More studies are needed to confirm the claim
of Hertle and colleagues.
1.2.2 Dual innervation of the extraocular muscles: proprioceptive hypothesis
Although the question whether PE have a sensory or motor function has not been yet
resolved, several authors have proposed the possibility that PE along with the MIF might
have a proprioceptive role in the control of eye movements. Robinson (1991) was the first to
use the term ‗inverted muscle spindle‘ to suggest that the non-twitch MIF fibers and the PE
might be comparable to the gamma ()-spindle system found in the skeletal muscles. This
hypothesis has been further extended by Buttner-Ennever and her colleagues based on their
neuroanatomical tracing studies (Buttner-Ennever, Horn, Graf & Ugolini, 2002), which
demonstrated that the SIF and MIF receive innervation from separate groups of ocular
motoneurons (Buttner-Ennever et al., 2001). The two groups of neurons were identified when
injections of horseradish peroxide were made at different sites of the EOM. Large
20
motoneurons were labeled when the midregion of the muscle fiber close to the end-plate was
injected (i.e., the injection targeted the SIF), whereas smaller motoneurons in a distinct
region around the periphery of the large motoneurons were labeled when the distal
musculotendinous region of the muscle was injected (i.e., the injection targeted the MIF).
These small motoneurons form a cap over the dorsal trochlear nucleus. They are found in the
medial half of the abducens nucleus, bilaterally around the midline of the oculomotor nucleus
to the inferior oblique and the superior rectus (referred to as S-group motoneurons), and at
the dorsal medial border of the oculomotor nucleus to the medial rectus and the inferior
rectus (referred to as C-group motoneurons). The motoneurons of the SIF and MIF identified
by retrograde tracing also exhibit different histochemical properties. For instance, the MIF
motoneurons do not contain nonphosphorylated neurofilaments, calcium binding protein
parvalbumin and perineuronal nets, all of which can be found in the motoneurons of the
twitch fibers (Eberhorn, Ardeleanu, Buttner-Ennever & Horn, 2005). It has been proposed
that parvalbumin and perineuronal nets are usually found in highly metabolically active
neurons, whereas modulatory neurons lack these markers (Bruckner, Brauer, Hartig et al.,
1993; Bruckner, Schutz, Hartig, Brauer, Paulke & Bigl, 1994). Thus, the histochemical
differences between the SIF and MIF motoneurons might reflect the differential involvement
of these neurons in the execution of eye movements.
A subsequent study has shown that the premotor input to the twitch and non-twitch
motoneurons also comes from different premotor areas (Wasicky, Horn & Buttner-Ennever,
2004; Ugolini et al., 2006). The non-twitch motoneurons receive monosynaptic input from
the vestibular (parvocellular) area and nucleus prepositus hypoglossi which are areas
associated with gaze-holding mechanisms, as well as the central mesencephalic reticular
21
formation and the supraoculomotor area which are involved in the programming of vergence
eye movements. In contrast, the twitch motoneurons receive input from classical premotor
saccadic regions and regions involved in programming of VOR, such as the paramedian
pontine reticular formation and the vestibular nuclei (magnocellular zone). In summary, the
discovery of dual innervation of eye muscles provides some support for Robinson‘s original
claim; specifically, that the non-twitch motoneurons of the global MIF might be involved in
regulating the baseline activity of PE, which would be analogous to the gamma-spindle
system in the skeletal muscles (Buttner-Ennever et al., 2002).
1.3 Role of gamma innervation in the skeletal system
Unlike EOM proprioception, the spindle-gamma system in skeletal muscles has been
studied extensively. At the beginning of the last century, Sherrington proposed that the
―muscular sense‖ plays a critical role in motor behavior. The source of feedback has been a
matter of debate for many years with several potential sources proposed, such as joint and
skin receptors, muscles, tendons and corollary discharge. Following the work of Matthews
and others, it was finally accepted in the 1970‘s that activity in muscle spindles is necessary
and sufficient to explain kinesthetic sensations (Matthews, 1982). A basic review the
anatomy and physiology of the muscle spindle-gamma system demonstrates the potential role
of the system in motor control, however, for a detailed review see Hulliger (1984).
1.3.1 Anatomy and physiology in skeletal muscles
Muscle spindles, sometimes referred to as intrafusal fibers, are embedded inside the
muscle belly in parallel with the extrafusal fibers. They are activated by muscle stretch as
22
they are ideally positioned to sense muscle length and changes in muscle length. Three types
of intrafusal fibers have been identified based on their morphology and response to stretch:
dynamic bag, static bag and nuclear chain fibers. Spindles are innervated by two types of
sensory afferents: primary (Ia) which innervate all three types of fibers, and secondary
afferents (IIa) which innervate only the static bag and chain fibers. Each spindle consists of
1–2 primary endings which signal muscle length and changes in muscle length (i.e., position
and velocity sensitivity) and 1–5 secondary endings which signal muscle length (i.e., position
sensitivity) (Gordon & Ghez, 1991).
Spindles in the skeletal muscles receive efferent innervation from gamma
motoneurons which are smaller in size and their axons have longer conduction velocity
compared to the alpha motoneurons. Activation of the gamma motoneurons does not result in
development of significant tension in the corresponding muscle. Two types of efferent
endings have been identified: dynamic and static, which are differentiated based on whether
they decrease or increase the dynamic response of Ia afferents (dynamic response is
calculated based on the firing frequency during the stretch in comparison to the firing rate
when steady length has been achieved). Dynamic gamma motoneurons (d) innervate
dynamic bag fibers and act on primary afferents; in contrast, static gamma motoneurons (s)
innervate static bag and chain fibers and act on both primary and secondary afferents. Each
gamma motoneuron may supply up to seven spindles in the same muscle and individual
spindles may receive innervation from up to 10 gamma neurons (Hulliger, 1984).
23
1.3.2 Function: alpha-gamma co-contraction in skeletal muscles
The complex organization of the spindle-fusimotor system has precluded any
definitive conclusions regarding its functional significance, nonetheless several explanations
have been proposed. The most commonly accepted function of the fusimotor system is its
role in spindle sensitization during muscle contraction. Due to the fact that spindles are
oriented in parallel with muscle fibers, their activity would decrease and actually cease
during muscle contractions if the intrafusal fibers did not have a mechanism that would allow
them to contract simultaneously with the extrafusal fibers. It has been shown that activity in
the gamma system allows the spindles to contract simultaneously with the muscle which
prevents the ‗slacking‘ of the spindles and allows them to remain sensitive during the
contraction. This mechanism has been referred to as alpha-gamma co-activation and is
further supported by the fact that there are motoneurons (termed beta efferents) which
innervate both the extrafusal and intrafusal fibers (Gordon & Ghez, 1991).
1.3.3 Descending control: implications for function
There is no doubt that alpha-gamma co-activation is one of the important functions of
the gamma motoneurons and it is the only function in amphibians and lower vertebrates;
however, there is also evidence that fusimotor activity can be adjusted independently of alpha
motor output. The work of Granit and Kaada (1952), which was based on activation recorded
in muscle spindles and muscles in cats after electrically stimulating structures within the
CNS, showed that stimulation of pontile and mesencephalic tegmentum, dorsal
hypothalamus, caudate and motor cortex increased the firing rate of muscle spindles without
a corresponding muscular contraction. They reported two differences between activation of
24
alpha and gamma efferents in the anesthetized animals: 1) gamma activity could be elicited at
significantly lower levels of stimulation compared to that required for alpha activity, and 2)
stimulation of the brainstem reticular formation led to a facilitation of gamma activity that
lasted up to 30 sec after the stimulus was taken away, in contrast to the response seen after
stimulation of the primary motor cortex when the facilitation was only seen during
stimulation. The authors proposed that gamma motoneurons might be involved in the
regulation of tonic muscular activity because they tend to maintain tonic discharge.
A series of studies by Appelberg and colleagues (Appelberg, 1981; Appelberg &
Jeneskog, 1972) identified a region within the midbrain in proximity to the red nucleus,
which, upon stimulation, selectively increased activity in the d motoneurons. To reflect the
functional significance, the area was referred to as the mesencephalic area for dynamic
control (mesADC). Additional stimulation studies of the mesADC were conducted by Taylor
and Donga (1989) while simultaneously recording from first order neurons of the jaw
muscles in the mesencephalic trigeminal nucleus and from the dorsal root ganglia containing
sensory neurons from the medial gastrocnemius muscle. Their results showed that, depending
on the area of stimulation, dynamic or static activity to either muscle was affected without
concomitant muscle activation demonstrating separate control over gamma and alpha
motoneurons. The area stimulated included the region dorsal and caudal to the red nucleus
extending to fasciculus retroflexus which projects to the interpeduncular nuclei. This area in
turn has pathways connecting with the habenular nuclei which have extensive connections
with the limbic system, thus suggesting a possible function for the gamma system in arousal
in preparation for a motor act. Other studies have also shown that the gamma system might
have an important role when animals are performing tasks which require precision (Tanji,
25
1976) or novel motor tasks (Hulliger, 1993). It is possible that gamma activity is increased in
these tasks due to increased attention and vigilance in anticipation of the upcoming
difficult/novel motor task.
Since activity of the static and dynamic fusimotor systems can be regulated
independently by descending pathways, several authors have proposed that the gamma
system might be ideally suited for parametric control of sensory feedback. Specifically,
dynamic gamma neurons increase the dynamic sensitivity of primary afferents and static
gamma efferents increase spindle bias but reduce dynamic sensitivity; hence, the CNS can
selectively modulate spindle sensitivity to different parameters (velocity or position) during
movement via the gamma system. This hypothesis was investigated in two studies which
examined cyclical jaw movements. First, Appenteng, Morimoto and Taylor (1980) recorded
activity in the masseter motor nerve during jaw movements induced by intra-oral stimulation
(water in mouth). Two types of units were identified: one unit‘s activation was cyclical
together with the activation of alpha motoneuron (modulated activity). The other unit
increased firing at the beginning of the movement and maintained activity throughout the
movement (sustained activity). They proposed that the sustained activity was due to
activation of the dynamic gamma efferents which was set at the beginning of the movement
to determine spindle‘s sensitivity to stretch while the modulated activity was due to the
activation of the static efferents which was set in concert with the alpha motoneuron‘s
activation to make sure that spindles don‘t slack and fall silent during muscle contraction.
These results were replicated and extended by Gottlieb and Taylor (1983), who
simultaneously recorded from the gamma efferents. Overall, these studies highlight a major
26
function of the gamma system: the CNS can set the overall gain of afferent feedback
according to the demands of the motor task.
1.3.4 Summary
Results from a large number of studies suggest that the spindle-gamma system
provides a sophisticated method for the CNS to control sensory transmission. For any given
motor task the CNS can set a particular template for (co)activation of alpha and gamma
motoneurons, thereby creating the appropriate muscle tone and receptor sensitivity for
individual motor tasks. In short, the parametric control of sensory feedback would allow
anticipatory gain control of sensory transmission (Prochazka, 1989). Although the eye
muscles are structurally and morphologically different than skeletal muscles, the principle of
feedback gain control might also be relevant. The six EOM participate in a variety of eye
movements that range from very fast saccades (peak velocity up to 600°/sec) to relatively
slow vergence (peak velocity rarely exceeding 10°/sec) (Hallet, 1986). Previous studies have
shown that manipulations of afferent feedback affect vergence more than version eye
movements (Guthrie et al, 1982), thus, it is possible that the CNS sets the gain of afferent
feedback differently for vergence and saccades.
1.4 Jendrassik Maneuver: possible mechanisms
The Jendrassik Maneuver (JM) refers to a forceful, voluntary muscle contraction in
distant muscle groups which has been shown to facilitate the amplitude of tendon reflexes. It
was first reported by the Hungarian physician Erno Jendrassik (Pasztor, 2004). Although the
reflex reinforcement effect has been reported many times, there is controversy regarding the
27
neurophysiological substrates contributing to the effect. The monosynaptic tendon reflex
involves only two neurons: the Ia afferent and the alpha motoneuron, but there are several
mechanisms that could be involved in reflex facilitation. First, the effect could be mediated
via the gamma system: increased activity of the gamma motoneurons would increase the
sensitivity of the muscle spindles to stretch which would result in a greater afferent volley
when a stimulus is applied. Second, the facilitation effect could be mediated via increased
excitability of the alpha motoneuron or via reduction of presynaptic inhibition of the Ia
afferent. In addition, there could be oligosynaptic facilitation via interneurons in the spinal
cord contributing to the reflex reinforcement effect (Dowman & Wolpaw, 1988; Gregory,
Wood & Proske, 2001; Murthy, 1978; Zehr & Stein, 1999).
1.4.1 Gamma system
Initial studies supported the hypothesis that gamma activity is the predominant
mechanism. This conclusion was based on the results from studies that found an increased
amplitude of tendon reflexes but not H-reflexes [Buller & Dornhorst, 1957; Sommer, 1940
(as described in Zehr & Stein, 1999)]. Since the H-reflex is elicited by electrical stimulation
of the Ia afferent, it bypasses the activation of the receptors (muscle spindles), thus, the lack
of facilitation of the H-reflex would support the gamma hypothesis. In addition, at least two
studies using microneurographic recordings reported that spindle activity increased during
the reinforcement maneuver without concomitant increase in muscle activation (Burg,
Szumski, Struppler & Velho, 1973; Ribot-Ciscar, Rossi-Durand & Roll, 2000).
In direct contrast to the above studies, there are several reports that do not support the
gamma hypothesis. For instance, two studies examined whether the H-reflex is facilitated
28
following a fusimotor block induced using lidocaine (Clare & Landau, 1964) or a pressure
cuff (Bussel, Morin & Pierrot-Deseilligny, 1978). Both studies reported a comparable
increase in tendon and H-reflexes during the reinforcement maneuver when the response
from spindles was blocked. In addition, several studies found no difference in spindle activity
independent of muscle activity as measured by microneurography during the reinforcement
maneuver (Burke, McKeon & Skuse, 1981; Burke, McKeon & Westerman, 1980; Hagbarth,
Wallin, Burke & Lofstedt, 1975).
The controversy regarding the contribution of fusimotor system to reflex
reinforcement is partly due to the lack of a standardized methodology. For instance, studies
have used a variety of reinforcement maneuvers in terms of muscle groups, strength of
contraction and timing when the reflex was elicited. In addition, reflexes are affected by
many other variables, such as the posture of the subject, the state of the muscle during testing
as well as prior to testing (for a review, see Proske, Morgan & Gregory, 1993).
1.4.2 Alpha motoneuron excitability
Another mechanism that has been proposed to explain the reflex reinforcement effect
is the change in alpha motoneuron excitability which was examined by Dowman and
Wolpaw (1988). Electromyography (EMG) was used to record muscle activity while the
soleus H-reflex was elicited by electrical stimulation in two conditions: with JM or without
JM. It was hypothesized that if the JM modifies motoneuron excitability then the EMG
activity should follow the time course of the JM (i.e., there should be an increase in EMG
activity during the JM). Experimental results did not confirm the hypothesis, thus, it is
unlikely that the JM affects the excitability of the alpha motoneurons directly.
29
1.4.3 Presynaptic disinhibition
Another potential mechanism that could mediate the reflex reinforcement effect (i.e.,
JM) is a change in the afferent input to the motoneurons via reduction of presynaptic
inhibition (PSI) of the primary afferents. This hypothesis was tested by Zehr and Stein (1999)
who took advantage of the fact that stimulation of an antagonist nerve increases PSI. The
amplitude of the H-reflex was tested in 3 conditions: 1) while participants performed the JM
(i.e., presumably decreasing PSI), 2) when the antagonist nerve was stimulated (i.e.,
increasing PSI), and 3) when the two experimental conditions were combined. As expected,
the reflex was facilitated during the JM and reduced during nerve stimulation; however,
instead of a complete cancellation during the combined stimulation, data showed a slight
decrease in reflex amplitude. Overall, these results supported the view that one of the
mechanisms involved in the JM might be a reduction in PSI through interneurons in the
spinal pathways.
An elegant experiment that examined the role of PSI and the gamma system was
designed by Gregory et al. (2001). The PSI hypothesis was tested by eliciting the soleus H-
reflex during the JM while electrically stimulating the afferents from heteronymous muscle
(the quadriceps). It was hypothesized that if the JM operates through the PSI mechanism,
combining the two manipulations should result in an additive reduction of the PSI, which
was not confirmed by the results from the study. To test the contribution of fusimotor
activation to reflex reinforcement, the authors examined tendon reflexes after the muscle
conditioning which left the spindles either in a mechanically sensitive state or in a relatively
insensitive state (slack). It was hypothesized that support for the role of gamma activation
could be demonstrated if the JM facilitated reflexes in the condition when spindles were left
30
in a relatively insensitive state after muscle conditioning. Results showed that the JM did not
preferentially facilitate the reflex in the condition when spindles were in a slack state;
instead, reflexes in both conditions were significantly enhanced. The authors concluded that
the JM most likely operates through oligosynaptic spinal pathways which their study was not
able to elucidate.
1.4.4 Time course of the reflex facilitation effect
In an attempt to resolve some of the controversies surrounding the reflex
reinforcement effect due to the JM, Delwaide and Toulouse (1981) conducted a detailed
examination of the time course of the reflex facilitation effect and the factors that affect the
amplitude of the reflex. When the reinforcement maneuver was maintained for 2.5 sec, three
distinct phases could be identified which were affected differently by the intensity of the JM.
Facilitation of the reflex during phase I (150 ms following the signal to contract) was minor
and occurred before any electromyographic (EMG) activity in the muscle involved in the
reinforcement maneuver was detected. The peak facilitation occurred around 300 ms
following the command to perform the maneuver, and the peak was highly dependent of the
intensity of the remote contraction. Facilitation then declined steadily, reached a plateau
around 600 ms and was maintained as long as the muscle contraction was performed.
The factors that were investigated were the strength and type of reinforcement
contraction performed. Results clearly showed that the facilitation effect (i.e., the amplitude
of the reflex) was dependent on the intensity of the voluntary contraction: the higher the
intensity of the contraction, the greater the facilitation effect. In addition, two types of
contractions were examined: fast ballistic movements and slow isometric contractions. The
31
facilitation effect was comparable in phase I and II, but in phase III the effect was only
evident during the isometric contraction. Additional experiments were conducted to
determine the effect of a motor block and vibratory stimulus on reflex facilitation. As
expected, only phase I facilitation was present when the muscle was paralyzed, and only
phase II and III were present when vibration was applied to the muscle (instead of the
voluntary reinforcement maneuver). Based on these results, the authors suggested that
different neurophysiological mechanisms might be involved in the three phases of the
reinforcement maneuver. It was suggested that facilitation seen in phase I is most likely of
supraspinal origin and might be related to the descending motor command and increased
arousal before the onset of movement. Facilitation in phase II and III is only present when
there is afferent feedback from the contracting muscle; however, there is a clear difference
between these two phases, which might be related to the fact that the H-reflex is only
facilitated in phase II and not in phase III (Toulouse & Delwaide, 1980).
1.4.5 Summary
Studies have shown that the neurophysiological mechanism underlying the JM
facilitation effect is complex and most likely involves oligosynaptic spinal pathways and
descending motor pathways that change the excitability of the gamma motoneurons and
primary afferents. Research has shown that JM is a potent manipulation that changes the
excitability of spinal and brainstem reflexes and it does not matter which peripheral muscles
are used to achieve the reinforcing effect. Despite the clear delineation of the three phases
provided by Delwaide and Toulouse (1981), studies by Zehr and Stein (1999) and Gregory et
al (2001) which tried to investigate the mechanism underlying the JM did not try to
32
distinguish these phases or whether a different mechanism might be involved in each phase.
The degree to which decreased PSI and gamma modulation are involved in changing the
excitability of the afferents might be different in each of the phases. Specifically, the gamma
system is more likely to be involved in the facilitation effect in phase III when only tendon
reflexes are facilitated by the JM and the H-reflexes are not affected.
33
CHAPTER II: RESEARCH OBJECTIVES & HYPOTHESES
Despite the surge of interest in EOM proprioception in the last few years, the role of
afferent signals in oculomotor motor control and visuomotor behavior are not yet fully
understood. The aim of this research is to help to elucidate the role of afferent and efferent
signals from the EOM in oculomotor control. Seminal studies by Buttner-Ennever and Horn
(2002), which demonstrated that the singly and multiply innervated fibers receive innervation
from separate groups of ocular motoneurons, have theoretical implications for the control of
eye movements. Specifically, it has been hypothesized that the non-twitch motoneurons
associated with MIF of the global layer might control the gain of proprioceptive feedback
from PE, analogous to the gamma-spindle system found in the skeletal muscles. The goal of
the present study was to test the above hypothesis using behavioral and psychophysical
approaches. The activity of non-twitch motoneurons was altered using the Jendrassik
Maneuver (JM), which was assumed to alter the excitability of the gamma system.
The non-twitch motoneurons receive direct pre-motor input from areas that are known to
be involved in the control of vergence eye movements. Therefore, the first paper examined
manual and perceptual responses while participants executed vergence eye movements and
localized a target presented in the median plane. It was hypothesized that if the non-twitch
motoneurons are analogous to the gamma motoneurons, the JM would also increase the
activity of these neurons and alter the afferent feedback from PE, which would result in
misregistered eye position and localization errors.
Experiments presented in the second paper further extend and clarify findings from the
first paper by examining whether the JM affects registered eye position during localization in
the frontal plane. Since the non-twitch motoneurons do not receive direct premotor input
34
from areas involved in the programming of saccades, we hypothesized that localization
responses associated with the saccadic system would not be affected by the JM.
Accurate estimation of egocenteric distance is not only critical for the performance of
localization tasks, but perceptual constancies, such as size and depth also rely on accurate
registration of absolute distance. The third paper examined whether the JM perturbation
affects perceptual judgments that rely on accurate registration of absolute distance. The
following hypotheses were tested in 3 studies: 1. participants will perceive the size of a
constant retinal stimulus as larger when the feedback from the eye muscles is altered via the
JM; 2. for a given disparity, the perceived depth will be greater when the JM is performed
compared to the condition without JM; 3. for a constant stimulus the perceived depth will be
reported as greater while participants perform the JM.
The fourth paper examined whether patients who have been operated for strabismus are
susceptible to a manipulation of afferent feedback via JM while localizing a target in depth. It
was hypothesized that patients’ responses would not be affected by the JM perturbation
because the surgeries most likely compromised the EOM feedback loops, thus, the gain of
the afferent feedback would not be altered.
35
PAPER 1
PROPRIOCEPTIVE ROLE FOR PALISADE ENDINGS
IN EXTRAOCULAR MUSCLES:
EVIDENCE FROM THE JENDRASSIK MANEUVER
1E. Niechwiej-Szwedo, E. González, S. Bega, M.C. Verrier, A. Wong, M.J. Steinbach
Vision Research (2006); 46:2268-2279
1 See Appendix 1 for contributions of each author
36
ABSTRACT
A proprioceptive hypothesis for the control of eye movements has been recently proposed
based on neuroanatomical tracing studies. It has been suggested that the non-twitch
motoneurons could be involved in modulating the gain of sensory feedback from the eye
muscles analogous to the gamma () motoneurons which control the gain of
proprioceptive feedback in skeletal muscles. We conducted behavioral and
psychophysical experiments to test the above hypothesis using the Jendrassik Maneuver
(JM) to alter the activity of motoneurons. It was hypothesized that the JM would alter
the proprioceptive feedback from the eye muscles which would result in misregistration
of eye position and mislocalization of targets. In the first experiment, vergence eye
movements and pointing responses were examined. Data showed that the JM affected the
localization responses but not the actual eye position. Perceptual judgments were tested
in the second experiment, and the results showed that targets were perceived as farther
when the afferent feedback was altered by the JM. Overall, the results from the two
experiments showed that eye position was perceived as more divergent with the JM, but
the actual eye movements were not affected. We tested this further in experiment 3 by
examining the effect of JM on the amplitude and velocity of saccadic eye movements. As
expected, there were no significant differences in saccadic parameters between the
control and experimental conditions. Overall, the present study provides novel insight
into the mechanism which may be involved in the use of sensory feedback from the eye
muscles. Data from the two first experiments support the hypothesis that the JM alters the
registered eye position, as evidenced by the localization errors. We propose that the
altered eye position signal is due to the effect of the JM which changes the gain of the
37
sensory feedback from the eye muscles, possibly via the activity of non-twitch
motoneurons.
38
1.0 Introduction
Knowledge of eye position is critical for accurate visuomotor behavior. For
instance, to make an accurate reaching movement to pick up an object, the central
nervous system (CNS) must combine several signals including the initial hand position,
head position, eye position, and retinal location of the object. The CNS can obtain eye
position information from two non-visual sources: the efference copy of the motor
command sent to the eye muscles (outflow) and from the eye muscle proprioceptors
(inflow) (Steinbach, 1987). The debate between outflow and inflow theories goes back to
Helmholtz and Sherrington (Bach-y-Rita, 1971), but during the last twenty years ample
studies have provided evidence suggesting that the afferent signals from the extraocular
muscles (EOM) are used during egocentric localization tasks (Bridgeman & Stark, 1991;
Gauthier et al. 1990a,b; Roll et al., 1991; Velay et al., 1994), programming of eye
movements (Knox et al., 2000; Weir & Knox, 2001), and during adaptation of smooth
pursuit (vonDonkelaar et al., 1997). In addition, patients show pointing errors when the
proprioceptive signals from the eye muscles are disrupted, for example, after surgical
interventions that destroy proprioception (Steinbach, Kirshner & Arstikaitis, 1987;
Steinbach & Smith, 1981) or due to pathology involving the trigeminal nerve (Campos et
al.,1989; Ventre-Dominey et al., 1996).
Although it is now recognized that proprioception contributes to registered eye
position, the mechanism of proprioceptive feedback from EOM has not been established.
There are two potential receptors in the human eye muscles that could provide
proprioceptive information: muscle spindles and palisade endings (PEs). Muscle spindles,
which are the primary proprioceptors in the skeletal muscles, have been found in the
39
EOM of several species: human, sheep, pig, and some primates, but not in other species,
such as cat, rabbit, horse, or mouse (Maier et al., 1974). Detailed histological studies of
muscle spindles in the human eye muscles have shown that they are different from the
skeletal spindles. Ruskell (1989) reported that more than 50% of EOM spindles were
indistinguishable from extrafusal fibers as they were not enclosed in a capsule and did not
have a defined equatorial region. He also observed that nuclear bag fibers were virtually
absent, which was also confirmed by others (Blumer et al., 1999; Lukas et al., 1994).
Although the morphological differences between spindles in the EOM and those found in
the skeletal muscles are well documented, the specific function of EOM spindles has not
been established. Thus, it cannot be concluded at the present time whether EOM spindles
can provide adequate proprioceptive signals informing the CNS about changing eye
position.
Another putative source of proprioception from the eye muscles are PEs, which
are receptors that are unique to EOM. PEs are associated with the multiply innervated
fibers (MIFs) of the global layer and they are sometimes referred to as innervated
myotendinous cylinders (Ruskell, 1978). PEs have been found in the EOM of many
species, such as cat, rhesus monkey, sheep, rat, and human (Alvarado-Mallart & Pinçon-
Raymond, 1979; Blumer et al., 1998; Buttner-Ennever et al., 2001; Ebhorn et al., 2005;
Richmond et al., 1984). Anatomical studies show that the PEs are enclosed in a capsule at
the distal end of the MIFs. A thinly-myelinated axon runs along the muscle fiber and then
loops back to enter the capsule as it divides into several branches and makes contact with
the tendon and muscle fibers (Alvarado-Mallart & Pinçon-Raymond, 1979; Richmond et
al., 1984).
40
Although the location of the cell body of PE’s has not been established, several
studies provide morphological and histological evidence suggesting that PEs are among
the sensory receptors which provide the central nervous system (CNS) with
proprioceptive information about eye position. Alvarado-Mallart & Pinçon-Raymond
(1979) reported that PEs in the cat are associated with the presence of clear vesicles
which are common in other sensory endings, such as Golgi tendon organs (GTO) and
muscle spindles. Billig and colleagues (Billig et al., 1997) reported that PEs were labeled
when retrograde tracers were injected into the Gasser’s (trigeminal) ganglion, which
contains only sensory neurons. However, recent histochemical examination of the
musculotendinous junction shows that, in addition to the sensory endings, the
myoneuronal region also contains motor endings (Lukas et al., 2000). These motor
endings were identified based on staining of the myoneuronal junction with
bungarotoxin, which labels acytocholinergic receptors. Lukas and colleagues concluded
that PEs might receive dual, sensory-motor innervation, similar to that found in the
muscle spindles, which are sensory receptors innervated by motoneurons.
In line with the work of Lukas and colleagues (2000), recent anatomical tracing
studies by Buttner-Ennever et al. (2001) demonstrated that the EOM receive dual
innervation from two distinct groups of ocular motoneurons. The EOM of the global
layer can be classified into singly and multiply innervated fibers based on the pattern of
innervation they receive. The singly innervated fibers (SIFs) have a single end-plate zone
located in the midregion of the muscle and respond with fast propagating action
potentials when stimulated, thereby contributing to the force developed by the muscle. In
contrast, the MIFs have multiple end plates distributed along the fiber which are
41
concentrated at the distal end (this is also the region where PEs are found). Upon
electrical stimulation, the MIFs respond with slow graded potentials and do not
contribute to the force developed by the muscle (Fuchs & Luschei, 1971). Due to these
properties, the SIFs are referred to as twitch fibers, whereas the MIFs are referred to as
non-twitch fibers (Buttner-Ennever et al., 2001). When injections of horseradish peroxide
were made at the distal or the midregion of the EOM, two groups of neurons were
identified. Large motoneurons were labeled when the midregion of the muscle fiber close
to the end-plate was injected, whereas smaller motoneurons, in a distinct region around
the periphery of the large motoneurons, were labeled when the distal musculotendinous
region of the muscle was injected. Based on these results, it was concluded that the large
motoneurons innervate the twitch fibers (SIFs), and the smaller motoneurons innervate
the non-twitch fibers (MIFs). Further work has also shown that the twitch and non-twitch
motoneurons receive different premotor input, which sheds light on a possible role of
these fibers in oculomotor control (Wasicky et al., 2004). For instance, the twitch
motoneurons receive projections from the areas within the brainstem that are involved in
the programming of fast eye movments, such as saccades and the vestibulocular reflex.
The non-twitch motoneurons receive pre-motor input from areas that are known to be
involved in gaze-holding mechanisms, vergence eye movements and smooth pursuit.
The role of MIFs and PEs in the control of eye movements remains elusive.
Several authors have proposed that the PEs and MIFs might have a proprioceptive role in
the control of eye movements (Buttner-Ennever et al., 2002; Porter, Baker, Ragusa &
Brueckner, 1995; Robinson, 1991). In particular, the non-twitch motoneurons of the MIF
in the global layer could be involved in modulating the gain of sensory feedback from the
42
PEs, analogous to the motoneurons which control the sensitivity of muscle spindles in
skeletal muscles.
We took a behavioral approach to examine whether the gain of sensory feedback
from the EOM can be altered by a manipulation that affects the activity of the
motoneurons in skeletal muscles. The Jendrassik Maneuver (JM) is an isometric
voluntary contraction of any muscle group. JM is referred to as a reflex reinforcing
maneuver because the amplitudes of skeletal reflexes are facilitated while the JM is
performed (Delwaide & Toulouse, 1981; Murthy, 1978). One of the mechanisms
proposed to explain the reflex reinforcement effect is that the muscle contraction has a
general effect that results in up-regulation of the motoneuron activity which increases
the baseline activity of muscle spindles and, consequently, results in a larger efferent
response when the muscle is stretched.
Stretch reflexes have not been recorded in the EOM muscles (Keller & Robinson,
1971); however, neural responses to EOM stretch have been recorded in several cortical
regions (Donaldson, 2000). The role of proprioception in the control of eye movements is
most likely different than in the control of limb position and movement but the possibility
that proprioceptive feedback might be modulated by the activity of non-twitch
motoneurons should not be dismissed, particularly in light of the new findings that reveal
dual innervation of the EOM from the twitch and non-twitch motoneurons. We
hypothesised that if the non-twitch motoneurons are analogous to the motoneurons, the
JM should also change the activity of these neurons which would alter the afferent
feedback from PEs and result in misregistration of eye position and pointing errors.
Furthermore, if the JM affects the activity of the non-twitch motoneurons, the actual eye
43
position should not be different between the conditions because the non-twitch
motoneurons do not add to the force used to move the eyes (Fuchs & Luschei, 1971).
It has been reported that the non-twitch motoneurons receive monosynaptic input
from the pre-motor centers located in caudal mesencephalic reticular formation and the
supraoculomotor area, which are involved in the control of vergence eye movements
(Wasicky et al., 2004). Therefore, localization responses were examined while
participants performed vergence eye movements in the first 2 experiments. Saccadic eye
movements were examined in experiment 3 which served as a control because non-twitch
motoneurons do not receive direct premotor input from areas involved in programming of
saccadic eye movements.
2.0 Experiment 1
2.1 Method
2.1.1 Observers
Participants in all three studies had normal or corrected-to-normal visual acuity of
20/20 and stereopsis of at least 40 seconds of arc as measured with the Titmus test
(Titmus Optical Co., Inc., Petersburg, Virginia 23805). All experimental protocols were
approved by the Ethics Review Boards at the University of Toronto and the University
Health Network. All participants gave their informed consent prior to participating. Ten
healthy adults with no history of any ocular disorders, mean age 30.8±7.2 years,
participated in the first experiment.
2.1.2 Stimuli
44
The stimuli were 2 green light emitting diodes (LEDs) embedded in a custom-
made black board and controlled by the experimenter via a trigger box. The stimuli were
in an earth-horizontal plane and aligned with the participant's midline, slightly below eye
level, and the viewing distance was 25 cm to the near target, and 45 cm to the far target.
2.1.3 Apparatus
Horizontal and vertical position of both eyes was monitored and recorded using
an infra-red eye-tracker system (El-Mar series 2020, Toronto, Ontario, Canada). The
horizontal and vertical eye positions were obtained from the relative positions of multiple
corneal reflections and center of pupil. The system accuracy is 0.5° with a linear visual
range of ±40° horizontally and ±30° vertically. The system is free from drift and has a
resolution of 0.1°. Eye position data were sampled at 120 Hz and stored on a computer
for further analysis. Prior to data collection, the eye tracker was calibrated. The
calibration procedure involved fixating fourteen points displayed along the horizontal and
vertical axes (7 fixation points along each axis), separated by 3.3° visual angle. The
participant’s head was stabilized using a chin rest and adjusted so that the eyes were in
the central position when looking at the center of the array.
Arm movement data were recorded at 60 Hz using an electromagnetic device
(Flock of Birds, Ascension Technology Co, Burlington, Vermont, USA). The resolution
of the system is 0.5 mm. The receiver was placed on the participant's thumb of the
dominant hand, which was used for pointing. The calibration involved passively placing
the participant’s thumb at the targets’ location, which was performed at the end of the
experimental session in order to avoid any bias or learning effect.
45
JM involved an isometric, voluntary muscle contraction which was performed
with the abductor muscles of the legs against resistance. The device used for resistance
was a Thigh Master™. Participants were asked to perform each contraction at a 75%
level of their maximal voluntary contraction, which was determined prior to the initiation
of the experiment. To ensure that the isometric contraction was performed at a consistent
level throughout the experiment, a string was tied around the Thigh Master™ which was
pulled taut when the muscle contraction was executed. Participants were instructed to
hold the string taut when performing the JM.
2.1.4 Procedure
Participants were seated in total darkness with their head stabilized by a chin rest
and performed an open-loop pointing task. During the experimental procedure,
participants were instructed to look and point by raising the thumb to be exactly
underneath the target (green LED) as accurately as possible when cued by the
experimenter. All extraneous visual cues were removed to ensure that participants had to
use a non-visual source of information to localize the target. There were three
experimental conditions randomized in 5 blocks of 6 trials as to order: (a) Control: look
and point to target; (b) Task 1: look and point to the target while performing a muscle
contraction (JM) with the lower limbs; (c) Task 2: look at the target while performing a
muscle contraction and point 2–3 sec after the contraction has been released (see Figure 1
for illustration of the protocol).
46
2.1.5 Data analysis
Data were analyzed using a custom software program and focused on the end-
point accuracy of vergence eye movements and hand movements. Vergence angle (µ)
was obtained by subtracting the right horizontal eye position from the left horizontal eye
position. Vergence-specified distance (D) was calculated using the vergence angle and
the individual interocular distances (I): D = I / µ. Pointing error in the median plane was
calculated by subtracting real target position from the hand position data.
Vergence-specified distance and pointing error data were submitted to a repeated
measures, two-way analysis of variance (ANOVA) with condition (control, task 1, task 2)
and target position (far, near) as the independent variables. Post-hoc analysis was
performed using Tukey’s HSD test which was considered significant when p<0.05.
2.2 Results
Participants systematically overshot the target with the hand (Figure 2) and with
the eyes (i.e. converged beyond the target) in all the conditions (Figure 3). There was a
significant effect of condition (F(2,18)=11.94, p=0.0005). Results from the 2-way
ANOVA showed no significant interaction effect between condition and target position
(far or near) (F(2,18)=0.44, p>0.05). Post-hoc analysis revealed that pointing responses
were significantly less accurate in task 2 (mean pointing error 6.93±5.0 cm) compared to
47
Figure 1: Schematic illustration of the experimental protocol used in experiment 1: (a)
control task; (b) Task 1: look and point during JM; (c) Task 2: look during JM and point
after JM.
48
the control condition (mean pointing error 5.32±5.06 cm) and task 1 (mean pointing error
5.51±4.93 cm).
There were no significant differences between the mean vergence-specified
distance of any of the conditions (F(2,18)=0.26, p>0.05) and the interaction effect was
also non significant (F(2,18)=1.02, p>0.05). On average, participants looked beyond the
target by 62±24% (mean ± standard deviation).
Figure 2: Experiment 1: Mean pointing error of the hand. The figure illustrates the
significant difference between Task 2 and the other two conditions (Control and Task1).
Error bars show ±1 standard error.
49
Figure 3: Experiment 1: Average vergence-specified distance for near and far targets in
all the tasks. The targets were shown at a distance of 25 cm and 45 cm from the
participant which is shown by the dotted lines.
2.3 Discussion
We hypothesized that the JM would affect the localization performance by
altering the proprioceptive signal from the eye muscles, possibly via the activity of non-
twitch motoneurons. Data from the study provided partial support for the hypothesis, but
cannot be interpreted unambiguously. In particular, results showed that when participants
first made an eye movement to the target while the JM was performed and executed the
pointing response 2–3 sec after the contraction has been released, the pointing response
50
was significantly less accurate compared to the control condition or to the task when the
JM was performed throughout the trial. It might be surprising, at first, to find no
difference in pointing accuracy when JM was performed throughout the trial compared to
the control condition. One possible explanation for this effect is by considering that the
CNS continually monitors the afferent feedback from the EOM and that the JM alters the
signal sent to the CNS. The larger pointing error was found in the condition when the eye
movements and the hand movement were executed under different afferent feedback (i.e.
eye movement with JM, hand movement without JM). On the other hand, no significant
difference was found between the control condition and when JM was performed
throughout the trial because the movements of the eyes and the hand were programmed
and executed under the same afferent feedback.
Another explanation that must be considered is that the effects obtained in the
present study were due to the effect of JM on motoneurons of the arm muscles used for
pointing. Presumably, the JM has a general effect on all motoneurons (Delwaide &
Toulouse, 1981), and it is possible that the activity of muscle spindles in the arm muscles
was also altered and might have influenced the localization response. This limitation was
addressed in the next experiment.
A critical finding from this study was that the vergence eye movements and the
vergence-specified distance were not affected by the JM as shown by the lack of
differences between any of the conditions. These data provide support for the fact that JM
does not affect the actual eye position and, consequently, the differences in localization
response must be due to an altered registered eye position signal. This notion is consistent
with the fact that JM should alter the proprioceptive feedback from EOM via the non-
51
twitch neurons without altering the actual eye position because eye movements are
controlled by the twitch neurons.
On average participants converged beyond the target in all the tasks, which is a
finding consistent with a previous study by Malinov, Epelboim, Herst and Steinman
(2000). In that study, participants under-converged by 20-45% while looking and tapping
to targets under natural viewing conditions (i.e. head was not restrained and with full
visual feedback). In the present study, participants converged even farther beyond the
target, which is most likely due to methodological differences between the two studies:
participants in our study had restrained head movement and no visual reference.
3.0 Experiment 2
The purpose of the second experiment was to further examine whether the eye
position signal is indeed altered by the JM. The major caveat in experiment 1 was that the
JM could have affected the accuracy of the pointing response of the hand by altering the
spindle activity of the arm muscles. This limitation was addressed in experiment 2 by
using an entirely visual task, which involved a criterion-free perceptual judgment task.
Based on our results from the previous experiment, we hypothesized that that the
perceptual judgments would be significantly affected by the temporal order of the JM. In
other words, it was expected that target localization would be significantly affected when
one of the targets, either the first (standard target) or the second (comparison target), is
shown during altered eye muscle afferent feedback.
3.1 Method
52
3.1.1 Observers
Twenty one healthy adults with no history of any ocular disorders, mean age
33.4±10.6 years, participated in the second experiment (the sample included 10
participants who also took part in experiment 1).
3.1.2 Stimuli
The stimuli were white dots (visual angle 0.24 min arc) displayed on a flat CRT
monitor (refresh rate 85 Hz). The display was programmed using VPixx (VPixx
Technologies, Inc., Montreal, QC), a graphics generation and psychophysics testing
software, controlled by a MacIntosh G4 computer. Targets were shown in the earth
horizontal plane in the participant's midline, approximately 15.5 cm below eye level and
the viewing distance for the 5 targets ranged between 67.6 cm to 71.7 cm. The standard
target was shown at a constant location at a viewing distance of 69.7 cm. The vergence
angle required to converge on the 5 targets ranged between 5 to 5.5 degrees. One of the
comparison targets was shown in the same location as the standard target and the other
four were shown closer or farther than the standard.
3.1.3 Apparatus
JM involved an isometric, voluntary muscle contraction against resistance
performed with the shoulder abductor muscles (10 participants) or with the abductor
muscles of the legs (11 participants). A custom made device, based on a spring loaded
scale, was used to provide resistance when participants used the shoulder muscles to
perform the JM. Participants performed the maneuver by pulling their arms apart while
53
holding the device in their hands. The device used for resistance with the lower limbs and
the JM procedure was the same as in experiment 1.
3.1.4 Procedure
Participants were seated in total darkness and performed a two-alternative forced
choice task using the method of constant stimuli. At the beginning of each trial
participants were instructed to look at the standard target, which was shown for 2.5 sec,
and to remember its location when it disappeared. The comparison target was then shown
at 1 of 5 possible locations, determined randomly by the computer. Participants made a
judgment by saying whether the comparison target appeared ‘nearer’ or ‘farther’ than the
standard target. There were four experimental conditions: (a) Control: standard and
comparison targets were shown with no JM; (b) Task 1: standard target appeared during
the JM, and comparison target appeared after the JM was released; (c) Task 2: standard
target appeared when the JM was not performed, and the comparison target appeared
during the JM; (d) Task 3: standard and comparison targets appeared while the JM was
performed (see Figure 4 for illustration of the protocol). The experimental conditions
were completely randomized. In each experimental condition the comparison target was
shown 10 times at each of the 5 locations for a total of 200 trials per participant.
Our prediction was that participants’ judgments would be affected by the order of
JM. In particular, we expected the largest difference between Task 1 and Task 2 because
one of the targets, either the standard or the comparison, was presented while the
feedback from EOM was altered. Task 3 served as another control condition because
both targets were shown with the same, altered feedback.
54
Figure 4: Schematic representation of the experimental procedures used in experiment 2.
3.1.5 Data analysis
The proportion of ‘near’ responses was calculated for each participant and task at
the five locations where the comparison target was shown and a psychometric function
fitted. All psychometric curves were visually inspected to determine whether the type of
muscle contraction (shoulder or leg abductor muscles) resulted in any qualitative
differences. Subsequently, an overall psychometric function based on the mean of all
participants was fitted for each task.
The point of objective equality (POE) was defined as the proportion of ‘near’
responses when the comparison target was shown at the same location as the standard
55
target. The POEs for each participant and task were submitted to a one-way ANOVA
with task (control, task 1, task 2, task 3) as the independent variable.
Data for each participant and task was fitted using a logistic regression (SAS, ver
8.1). The goodness of fit of the model was tested using the Hosmer-Lemeshow statistic
and a non-significant result was used to verify that the logistic model was appropriate.
The point of subjective equality (PSE) was calculated using the estimated parameters
(slope and intercept) from the logistic model. The PSE is the point at which the logistic
function yields a probability of 0.5 (i.e. the comparison target is perceived as nearer than
the standard target 50% of the time). Cook’s distance was used to identify influential
observations (outliers) in the dataset. The PSE, intercept and slope were submitted to a
one-way ANOVA with task (control, task 1, task 2, task3) as the independent variable.
Post-hoc analysis was performed using Tukey’s HSD test which was considered
significant when p<0.05.
3.2 Results
Preliminary inspection of the individual psychometric curves did not reveal any
differences in the performance of participants who used the shoulder abductor muscles as
compared to those who used the leg abductor muscles to perform the JM. Therefore, the
data was collapsed and the mean performance of all participants in each condition is
shown in Figure 5. The individual data of twenty of the participants showed a consistent
trend which is evident in the mean data shown in Figure 5. Participants consistently
perceived the target as farther when the JM was performed during the presentation of the
second target (Task 2). The results of one of the participants were a mirror-image of those
56
of the rest of the group (i.e. the comparison target was perceived as nearer on Task 2),
which was most likely due to a misinterpretation of the instructions. These data were not
included in the statistical analysis2.
Figure 5: Mean proportion of ‘near’ responses for each comparison target location (at 0
both targets were presented at the same location). Error bars show ± 1 standard error.
Figure 6 shows the differences in the POE between the Control condition and
Tasks 1 and 2 for individual participants (POE for Task 3 is not shown). The mean POEs
across conditions were: Task 1=0.61, Task 2=0.34, Task 3=0.51, and Control=0.45
[F(3,57)=10.62, p<0.0001]. Post-hoc comparisons showed that performance was
2 Including this subject’s data did not change the overall statistical results (i.e. both PSE and POE results
57
significantly different between Task 1 and Task 2. Overall, the data showed that
participants perceived the location of the comparison target as nearer when the JM was
performed during the presentation of the standard target (Task 1) as compared to when
the JM was performed when the comparison target was shown (Task 2) or when the JM
was not performed (control).
Figure 6: Differences in the POE between the Control condition and Tasks 1 and 2 for
individual participants (ID 1 to 20). The y-axis represents the difference in proportion of
‘near’ responses between Task 1 and Control & Task 2 and Control. Positive values
indicate that the comparison target was reported as ‘nearer’ and negative values indicate
that the comparison target was reported as ‘farther’ with respect to the control task.
remained significant).
58
The logistic model fitted the experimental data well for the majority of the
psychometric curves (76 out of 80), which was supported by the non-significant result
from the Hosmer-Lemeshow test. Although in four cases (one in the control condition
and three in Task 3) the test was statistically significant, the logistic model was still used
to fit the data. Two outliers were detected using the Cook’s test in the PSE dataset (one
observation in Task 2 and one in Task 3). These two observations were twice the
magnitude of the recommended cut-off value (4/n) and they were replaced by the
geometric mean obtained from the 19 observations for a given task.
Analysis performed on the parameters obtained from the logistic regression model
showed statistically significant differences between conditions for the PSE
[F(3,57)=13.18, p<0.0001] and intercept [F(3,57)=8.70, p<0.0001], but not for the slope
[F(3,57)=0.42, p=0.7360]. Post hoc analysis revealed that the PSE was significantly
higher in Task 2 compared to the other conditions (Task 2=10.0 mm, Task 1=3.5 mm,
Control=5.0 mm, Task 3=3.4 mm), which means that in Task 2 the comparison target had
to be presented significantly nearer in order to be perceived at the same location as the
standard target. The value of the intercept was significantly higher in Task 1 (0.89) than
in Task 2 (0.29), the Control condition (0.61), and Task 3 (0.62). These results suggest
that the JM influenced the gain but not the sensitivity of the perceptual judgments.
3.3. Discussion
Results from the second experiment provided support for our hypothesis that JM
affects the registered position of the eyes and shed more light on the effect of the JM. A
schematic diagram summarizing the results is shown in Figure 7. In the case when both
59
targets (standard and comparison) were shown at the same location and the JM was
performed when the standard target was presented, participants reported that the
comparison target was ‘nearer’. This result suggests that participants perceived the
location of the standard target as farther with the JM. In contrast, when the JM was
performed while the comparison target was presented, the comparison target was reported
as ‘farther’, which again suggests that during JM the location of the target is perceived as
farther. In summary, results from the second experiment provide strong evidence that eye
position is registered as more divergent when the JM is performed.
Figure 7: Summary and interpretation of results for experiment 2.
60
4.0 Experiment 3
The critical finding from experiment 1 was that the JM manipulation did not
affect the actual eye position. Experiment 3 was conducted to further examine whether
JM has any effect on eye movements by examining a different type of eye movements:
the saccadic system. We chose saccadic eye movements for two reasons. First, saccades
are fast eye movements programmed by different cortical and subcortical areas
(Carpenter, 1988) than the vergence eye movements which were examined in experiment
1. Secondly, a neuroanatomical tracing study has shown that the twitch and non-twitch
motoneurons receive premotor input from distinct brainstem areas, which are associated
with the saccadic and vergence systems, respectively (Wasicky et al., 2004). Thus, we
hypothesized that if the JM acts via the non-twitch motoneurons, the parameters of the
saccadic eye movement should not be affected.
4.1 Method
4.1.1 Observers
Ten healthy adults with no history of any ocular disorders, mean age 32.2±12.9
years, participated in the experiment (3 participants also took part in experiments 1 and
2).
4.1.2 Stimuli
The stimulus was a white dot which subtended 0.25 degrees of visual angle. The
stimulus was rear-projected onto a black background and displayed at 10 eccentricity to
the left and right of the fixation. The stimulus presentation was controlled by VPixx
61
(VPixx Technologies, Inc., Montreal, QC), a graphics generation and psychophysics
testing software, controlled by a MacIntosh G4 computer.
4.1.3 Apparatus
The method of eye movement recording and the JM manipulation procedure were
the same as described in the methods section of Experiment 1.
4.1.4 Procedure
Participants were seated in a dimly lighted room and performed saccadic eye
movements to randomly presented stimuli (±10° to the left and right of the fixation
point). In the experimental condition participants started the JM while looking the central
fixation point and performed the JM during the saccadic eye movement. In the control
condition eye movements were performed without the JM. The stimuli were shown 10
times at each location for a total of 40 trials in the control and experimental condition.
4.1.5 Data analysis
Saccades that followed the presentation of the stimulus were detected using a
custom software program using the velocity criterion of 30/sec. All saccades identified
by the program were visually confirmed by the experimenter. Peak velocity and
amplitude of the first saccade for each trial were determined using a custom software
program. Data were submitted to repeated-measures ANOVA with condition (control,
experimental) as the independent variable.
62
4.2 Results
As expected, the data showed no significant differences for peak velocity
(F(1,9)=0.89, p>0.05) and amplitude (F(1,9)=0, p>0.05) between the conditions. The
mean peak velocity in the control and experimental conditions were 302.6161.97/s and
306.7563.95/s, respectively. The mean amplitude of the first saccade in the control and
experimental conditions were 9.301.56and 9.371.16, respectively.
4.3 Discussion
Overall, the results from experiment 3 suggest that the JM does not affect the
actual eye movements as shown by the lack of differences in saccadic parameters
between the control and experimental conditions. The negative findings from this
experiment provide additional support to our hypothesis that the JM acts via the activity
of non-twitch motoneurons and has no effect on the twitch motoneurons.
5.0 General Discussion
The results from the present study provide novel insight into the mechanism
which may be involved in the use of sensory feedback from the EOM. Behavioral and
psychophysical data support the hypothesis that the JM alters the registered eye position,
but not the actual eye position. We propose that the altered eye position signal is due to
the effect of the JM which changes the gain of the sensory feedback from the eye
muscles, possibly via the activity of non-twitch motoneurons.
The EOM fibers can be classified into several types based on their innervation,
morphological, histochemical, and contractile properties (for a review see Spencer &
63
Porter, 1988). Two types of efferent nerve endings are found on the EOM fibers: single,
large end-plates (en plaque) and multiple, small fiber endings (en grappe). Fibers that
receive single innervation (SIF) have regularly spaced fibrils, large number of
sarcoplasmic reticulum, and a well developed transverse tubule system, which allows
these fibers to conduct fast action potentials. In contrast, the MIF have poorly developed
sarcoplasmic reticulum and do not generate action potentials, instead, they generate a
prolonged graded response when stimulated at thresholds that are 3-6 times greater than
the most excitable SIF (Eakins & Katz, 1972). Thus, the MIF are sometimes referred to
as non-twitch fibers. Given that the MIF do not contribute to the tension developed by the
muscle (Fuchs and Luschei, 1971), the question that arises is, what role could these non-
twitch fibers play in oculomotor processes?
Some insight to this question comes from recent anatomical tracing studies by
Buttner-Ennever and colleagues (2001) who demonstrated that the EOM receive dual
innervation from separate groups of ocular motoneurons. The close association between
non-twitch motoneurons, the MIF and the PEs has led several authors to propose a
proprioceptive hypothesis for the control of eye movements (Buttner-Ennever & Horn,
2002; Porter et al., 1995; Robinson, 1991). In particular, more than a decade ago
Robinson (1991) referred to PE and MIF as the inverted muscle spindles, and recently
Buttner-Ennever & Horn (2002) suggested that the non-twitch motoneurons might have a
role analogous to the efferent fibers which control the gain of the intrafusal fibers in the
skeletal muscles. The control of sensory feedback from EOM has been demonstrated in
an ungulate by Whitteridge (1959). However, at the present time there is no direct
anatomical evidence confirming that non-twitch motoneurons modulate the sensory
64
feedback in primates, which is partly due to the fact that the sensory pathway and the
location of the somata of the PEs have not been established. The non-twitch motoneurons
share similarities with the motoneurons in that they are both smaller then their
corresponding alpha motoneurons, and their activity does not generate fast action
potentials or contribute to changes in muscle tension directly. Recording from the cell
body of the EOM sensory neuron while stimulating the non-twitch motoneurons would
provide unequivocal evidence for a gain control regulation of proprioceptive feedback
from the eye muscles.
In the present study we used a proxy method (JM) to alter the activity of the
motoneurons. While the JM is performed, the amplitude of all stretch reflexes is
facilitated, which was first reported by the Hungarian physician Ernst Jendrassik
(Delwaide & Toulouse, 1981). The monosynaptic tendon reflex involves only two
neurons: the Ia afferent and the alpha motoneuron, but there are several mechanisms that
could be involved in the facilitation of the reflex. First, the effect could be mediated via
the gamma feedback loop: increased activity of the motoneurons would increase the
gain of the muscle spindle (i.e. increased discharge rate of the spindle), which would
result in a greater afferent volley when the muscle is stretched. Second, the facilitation
effect could be mediated via supraspinal control which can decrease the presynaptic
inhibition of the Ia afferent or increase the excitability of the alpha motoneuron. In
addition, there could be polysynaptic facilitation via interneurons in the spinal cord
contributing to the effect (Dowman & Wolpaw, 1988; Gregory et al., 2001; Murthy,
1978; Zehr & Stein, 1999). A detailed examination of the factors that affect the amplitude
of the reflex suggested that all the above mechanisms might contribute to the reflex
65
reinforcement effect of the JM (Delwaide & Toulouse, 1981). In particular, the
contribution of the motoneurons to reflex reinforcement might be more relevant when
the contraction is maintained longer than 600 ms, which was the case in the present
study.
As mentioned previously, the JM has been studied extensively in the context of
reflex reinforcement. Although stretch reflexes have never been recorded in the EOM
(Keller & Robinson, 1971), neural activity in response to passive stretch of the EOM has
been reported in cortical and subcortical areas (for review, see Donaldson, 2000). Clearly,
the proprioceptive signals from the EOM are being used by the CNS despite the lack of
reflex responses in the eye muscles.
Behavioral studies have shown that proprioceptive signals from the EOM are used
during localization tasks (Bridgeman & Stark, 1991; Gauthier et al. 1990a; Roll et al.,
1991; Velay et al., 1994) and, as we show in the present study, a pointing task and a
perceptual judgment task. Since, presumably, JM has a general effect that up-regulates
the activity of the system, we hypothesized that the eye position signal would be altered
if proprioceptive feedback from the EOM is affected by the activity of non-twitch
motoneurons. Our study provides preliminary support for the hypothesis. In particular,
the JM affected the bias of the judgment but not its sensitivity (slope), which is consistent
with the action of the motorneurons on muscle spindles (Prochazka, 1989).
In experiments 1 and 2, participants performed vergence eye movements and the
task involved judgments of absolute depth. Since all visual cues were removed,
participants had to rely on the eye position signal to perform the task. A vergence task
was chosen because it has been reported that the pre-motor input to the non-twitch
66
motoneurons comes from caudal supraoculomotor area, central mesencephalic reticular
formation, medial vestibular nuclei (parvocellular division), and nucleus prepositus
hypoglossi (Wasicky et al, 2004), which are brainstem regions involved in vergence eye
movements, ocular following, and gaze holding mechanisms. A critical finding from
experiments 1 and 3 was that the actual eye position and saccadic parameters were not
affected by the JM, which suggests that the manipulation had no effect on the alpha
motoneuron activity and did not result in change of muscle tension. Instead, the JM
affected the participants’ pointing and perceptual responses. Overall, these results imply
that participants made judgments based on the altered registered eye position signal from
EOM proprioceptors and not on the actual eye position signal which was sent to the eye
muscles.
In conclusion, our results suggest that registered eye position is altered by the JM
while the actual eye position is not affected. We propose that this effect may be mediated
via the activity of non-twitch motorneurons. These results may have important clinical
implications for the treatment of strabismus, which is an ocular disorder involving
deviation of one or both eyes due to extraocular muscle (EOM) imbalance. Surgical
intervention, which involves cutting the EOM at the musculotendinous junction, is a
common treatment for strabismus, but often does not result in regaining optimal function.
Many children have to undergo multiple surgeries and yet they do not develop normal
binocular function (stereoscopic vision and vergence eye movements). It is possible that
the lack of success is partly due to the damage sustained at the myotendinous region of
the muscles which contains the putative proprioceptors of the eye muscles (Steinbach,
1987).
67
PAPER 2
LOCALIZATION IN THE FRONTAL PLANE IS NOT SUSCEPTIBLE
TO MANIPULATION OF AFFERENT FEEDBACK
VIA THE JENDRASSIK MANEUVER
1E. Niechwiej-Szwedo, E.G. González, M.C. Verrier, A. M. Wong, M.J. Steinbach
Vision Research (2008); 48:724-732
1 See Appendix 1 for contributions of each author
68
ABSTRACT
We have previously shown that registered vergence eye position is altered while participants
perform the Jendrassik Maneuver (JM). We proposed that the altered eye position signal
registration is due to the effect of the JM which changes the gain of the sensory feedback from
the eye muscles, possibly via the activity of non-twitch motoneurons. We conducted two studies
to further extend and clarify one of our previous findings by examining whether the JM also
affects registered eye position during localization in the frontal plane. Since the non-twitch
motoneurons do not receive premotor input from areas involved in the programming of saccades,
we hypothesized that localization responses associated with the saccadic system should not be
affected by the JM. The data confirmed our prediction. We propose that the non-twitch
motoneurons are involved in parametric adjustment of the proprioceptive feedback loops of
vergence but not version eye movements.
69
1.0 Introduction
Good eye-hand coordination is essential for accurate performance of daily activities.
For example, reaching to pick up a cup of coffee is a simple movement and yet it requires a
complex sensorimotor transformation of visual and somatosensory afference into a coordinated
pattern of muscle activations. To perform this simple motor act, the central nervous system
(CNS) has to process and integrate information from several receptors: the retinal location of the
cup, the position of the eyes in the orbits, the position of the head, the arm and the hand.
In the case of skeletal muscles, it has been unequivocally recognized that muscle spindles
provide the CNS with information concerning limb position and velocity (Matthews, 1981). In
addition, a large body of research has addressed the structural properties, anatomical pathway,
and central control of muscle spindles (for a review see Hulliger, 1984). In contrast, eye muscle
proprioceptors have not received similar attention. Although there is still controversy regarding
the afferent pathway, a recent, elegant study by Wang and colleagues (Wang, Zhang, Cohen &
Goldberg, 2007) provided evidence that eye position is represented in the somatosensory area 3a
in rhesus monkeys.
The CNS can obtain eye position information from two non-retinal sources: outflow
(copy of the motor command) and inflow (signals from the eye muscles). Although, the
contribution of inflow to eye position sense has been debated for years (for a review see
Donaldson, 2000), studies have shown that proprioceptive signals from the eye muscles in
neurologically intact individuals play a significant role in the programming of eye movements
(Knox et al., 2000; Weir & Knox, 2001), during egocentric localization tasks (Bridgeman &
Stark, 1991; Gauthier et al., 1990a,b; Roll et al., 1991; Velay et al., 1994) and adaptation of
smooth pursuit (vonDonkelaar et al., 1997).
70
Extraocular muscles (EOM) contain at least two receptors which could provide eye
position information: muscle spindles and palisade endings (PE). Muscle spindles are found in
the orbital layer of the human EOM; however, their function has been questioned due to their
unusual morphological characteristics (for a review see Ruskell, 1989). In addition, muscle
spindles have not been found in the EOM of some species, such as cats or rhesus monkeys. In
contrast, PE have been found in the EOMs of all the species tested to date including humans,
cats, rats, sheep, and rehsus monkeys (Alvarado-Mallart & Pinçon-Raymond, 1979; Blumer et
al., 1998; Buttner-Ennever et al., 2001; Eberhorn, Horn, Eberhorn et al., 2005; Richmond et al.,
1984). PE are uniqe to the EOM and they are associated with the myotendious region of the
global multiply innervated fibers (MIF). Several studies have considered that they might be the
EOM proprioceptors based on their morphological characteristics (Alvarado-Mallart & Pinçon-
Raymond, 1979) and retrograde tracing studies (Billig et al., 1997). However, recent
histochemical examination of the musculotendinous junction in the cat and monkey has revealed
that the region containing the PE is immounoreactive to markers for cholinergic nerve fibers and
nerve terminals, which have been traditionally associated with motoneurons (Konakci, Streicher,
Hoetzenecker, Blumer et al., 2005; Konakci, Streicher, Hoetzenecker, Haberl et al. 2005).
Although the question of whether PE have a sensory or a motor function has yet to be
resolved, several authors have proposed the possibility that PE, along with the MIF, might have a
proprioceptive role in the control of eye movements. Robinson (1991) was the first to use the
term ‘inverted muscle spindle’ to suggest that the non-twitch MIF and the PE might be
comparable to the gamma ()-spindle system found in the skeletal muscles. This hypothesis has
been further extended by Buttner-Ennever and colleagues (Buttner-Ennever et al., 2002) based
71
on their neuroanatomical tracing studies which demonstrated that the MIF receive innervation
from separate groups of ocular motoneurons (Buttner-Ennever et al., 2001).
The goal of the present studies was to test the above hypothesis using a psychophysical
approach and the Jendrassik Maneuver (JM). The JM is a forceful voluntary muscle contraction
of any muscle group. Previous studies have shown that the JM alters the excitability of tendon
reflexes. Specifically, the amplitude of the reflex is enhanced and the facilitation is dependent on
the strength of the reinforcing maneuver (Delwaide & Toulouse, 1981). One hypothesis that has
been proposed to explain the reinforcing effect is that the JM increases the excitability of the
gamma system (Murthy, 1978). Since the gamma system regulates the baseline activity of
spindles, the JM increases the baseline activity of spindles which become more sensitive to the
upcoming stimulus resulting in a larger response when the muscle is stretched.
JM not only affects the excitability of reflexes but also the perceived position of the arms
and eyes. In a recent study, Yasuda and colleagues (Yasuda, Izumizaki, Ishihar, Sekihara,
Atsumi & Homma, 2006) examined the upper limb position sense while participants performed a
reinforcing maneuver with their quadriceps muscles. Data showed that the arm was perceived in
a more extended position when the JM was performed and the error increased with the intensity
of the quadriceps contraction.
The effect of JM on registered vergence eye position was shown in our previous study
(Niechwiej-Szwedo, González, Bega, Wong, Verrier & Steinbach, 2006). In short, while the JM
was performed, targets were perceived as farther while the actual eye position was not affected.
In the current investigation we conducted two studies to examine whether the JM affects
localization responses associated with saccadic eye movements. Manual pointing responses were
examined in the first study and perceptual localization was investigated in the second study.
72
Although version and vergence share a final common pathway, different pre-motor areas
are involved in programming of these eye movements (for a review see Buttner-Ennever et al,
2005). In addition, conjugate and disconjugate eye movements are differentially susceptible to
manipulations of afferent feedback. For example, saccades do not seem to be affected by
sectioning of the ophthalmic branch of the trigeminal nerve (deafferentation) whereas vergence
is disrupted by the same procedure (Guthrie et al., 1982). Additionally, the accuracy of pointing
to targets arranged along the horizontal axis was not affected by deafferentation (Lewis,
Gaymard & Tamargo, 1998). In contrast, binocular depth discrimination was impaired in cats
following the same procedure (Fiorentini, Mafei, Cenni & Tacchi, 1985). Given the differences
between the saccadic and vergence systems, our studies were designed to further explore the
hypothesis that version and vergence are differentially susceptible to manipulations of afferent
feedback using the JM.
The current studies also help to extend and clarify the findings from one of our previous
experiments (Niechwiej-Szwedo et al., 2006). First, we showed that the JM affected pointing
responses to targets in depth, but it is possible that the pointing error was due to the effect of the
JM on the upper limb muscles instead of the eye muscles. Thus, in the first experiment of our
current examination, participants pointed to targets presented along the frontal plane. It was
hypothesized that if the JM affects the activity of non-twitch motoneurons which do not receive
premotor monosynaptic input from areas involved in the programming of saccades (Wasicky et
al., 2004), the pointing responses should not be affected by the JM. Alternatively, pointing
responses might be affected if the result that we have previously observed was due to the effect
of the JM on the limb muscles.
73
Secondly, we showed that the JM does not affect the actual vergence or saccadic eye
movements; however, the perceptual localization of eccentric targets was not explicitly
examined. Therefore, in the second experiment we asked participants to localize briefly flashed
targets after they made a saccadic eye movement. We hypothesized that if the JM acts through
the activity of non-twitch motoneurons then perceptual localization associated with saccadic eye
movements should not be affected. Alternatively, if the effect of the JM occurs via a different
neural mechanism then we might see increased localization errors during saccades similar to the
overshoot errors found in the case of the vergence system. Eye movements were recorded in
experiment 1 in order to replicate our previous findings and verify that the JM does not affect
activity of the twitch motoneurons.
2.0 Experiment 1
2.1 Methodology
2.1.1 Participants
Participants in both studies had normal or corrected-to-normal visual acuity of 20/20 or
better and stereopsis of at least 40 seconds of arc as measured with the Titmus test (Titmus
Optical Co., Inc., Petersburg, Virginia 23805). All experimental protocols were approved by the
Ethics Review Boards at the University of Toronto and the University Health Network. The
research adhered to the tenets of the Declaration of Helsinki, and all participants gave their
written informed consent prior to participating. Ten healthy adults (8 females) with no history of
ocular disorders and a mean age of 34±16 years, participated in the first experiment. Five of the
participants also participated in the experiment that involved pointing in depth which was
reported in our previous paper (Niechwiej-Szwedo et al, 2006).
74
2.1.2 Stimuli
The stimuli were 3 red light-emitting diodes (LEDs) placed on a custom-made black
board and controlled by the experimenter via a trigger box. The fixation stimulus was aligned
with the participant's midline and the other two LEDs were located 8 to the left and right of
fixation. All LED’s were presented slightly below eye level. The two eccentric targets were
located 51 cm from the participants so everyone could point to the target comfortably. The board
was positioned so that participants could not see their arms and they had no feedback about the
accuracy of their pointing. The only difference between the stimuli presented in this experiment
and those used in the previous study (Niechwiej-Szwedo et al., 2006) was the fact that the two
LEDs were presented eccentrically in the frontal plane and not in depth.
2.1.3 Apparatus
Horizontal and vertical position of both eyes was monitored and recorded using an infra-
red eye-tracker system (El-Mar series 2020, Toronto, Ontario, Canada). Horizontal and vertical
eye positions were obtained from the relative positions of two corneal reflections and the center
of the pupil. Prior to data collection, the eye tracker was calibrated. The system accuracy is 0.5°
with a linear visual range of ±40° horizontally and ±30° vertically, the resolution is 0.1°, and it is
free from drift. Eye position data were sampled at 120 Hz and stored on a computer for further
analysis. Arm movement data were recorded at 60 Hz with a resolution of 0.5 mm using an
electromagnetic device (Flock of Birds, Ascension Technology Co, Burlington, Vermont, USA).
The receiver was placed on the thumb of the participant's dominant hand, which was used for
pointing.
JM involved an isometric, voluntary muscle contraction which was performed with the
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abductor muscles of the legs against resistance. The device used for resistance was a Thigh
Master™. Participants were asked to perform each contraction at 75% level of their maximal
voluntary contraction, which was determined prior to the initiation of the experiment. To ensure
that the isometric contraction was performed at a consistent level throughout the experiment, a
string tied around the Thigh Master™ was pulled taut when the muscle contraction was
executed. Participants were instructed to hold the string taut while performing the JM.
2.1.4 Procedure
Participants were seated in total darkness while performing an open-loop pointing task.
During the experimental procedure participants were instructed to look and point by raising the
thumb to be exactly underneath the target (red LED) as accurately as possible when cued by the
experimenter. Participants initiated the pointing movements from the same starting position
which was identified by a tactile cue placed on a table at their midline. All extraneous visual cues
were removed to ensure that participants had to use a non-visual source of information to
localize the target. There were three experimental conditions randomized as to order: (a) control:
look and point to the target; (b) task 1: look and point to the target while performing the JM; (c)
task 2: look at the target while performing the JM and point 2–3 sec after the contraction had
been released (see Figure 8 for illustration of the protocol). Participants completed 15 trials in
each condition.
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Figure 8: Schematic illustration of the experimental protocol used in experiment 1: (a) control:
no JM; (b) task 1: JM performed during saccade and pointing; (c) task 2: JM performed during
saccade, but not during pointing.
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2.1.5 Data analysis
Data analysis was conducted using custom software and focused on the end-point
accuracy of the hand and saccadic eye movements. The pointing data for each trial were
examined visually. The end of the pointing trajectory was established from the position and
velocity traces. The end point was the position of the hand when it came to rest and it was
calculated as the mean of 50 ms when the hand velocity was 0/sec. The calibration of the hand
position performed at the end of the experiment for each subject could not be used to calculate
the errors due to a noisy signal. We have, however, relative error measures that allowed us to
compare the two experimental conditions.
Pointing data, saccade amplitude and saccade peak velocity were submitted to repeated
measures, two-way analyses of variance (ANOVA) with condition (control, task 1, task 2) and
target position (left, right) as the independent variables.
2.2 Results
The data from individual participants for each condition were plotted and visually
inspected for trends to determine if participants were more likely to overshoot or undershoot the
target in the experimental condition in comparison to the control condition. No trends were
evident: half of the participants overshot the target regardless of the experimental condition. The
lack of a reliable effect was confirmed by the statistical analysis. Results from the ANOVA for
the pointing response showed no significant interaction effect between the task and pointing to
the left or right targets (F(2,18)=0.66, p > .05). The mean pointing responses to the right sided
targets were 8.95±2.66 cm for the control condition, 9.57±2.79 cm for task 1 and 9.10±2.56 cm
for task 2. The mean pointing responses to the left sided targets were 9.742.50 cm for the
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control condition, 9.79±2.85 cm for task 1 and 9.56±2.90 cm for task 2. There was no difference
in pointing accuracy between the conditions (F(2,18)=1.33, p > .05). The distribution of pointing
responses to both targets for each task is shown in the boxplots in Figure 9.
Figure 9: Distribution of pointing responses obtained in experiment 1. The boxplot contains the
middle 50% of the data (the upper edge is the 75th
percentile and the lower edge is the 25th
percentile), the cross in the box represents the median. The lines extending from the boxplot
(whiskers) indicate the 1st and 99
th percentile.
The data showed no significant differences between the conditions for the amplitude of
saccadic eye movements (F(2,18)=0.67, p > .05). The mean amplitude of the first saccade to the
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right sided target was 6.73±1.4 for the control condition, 6.62±1.8 for task 1 and 6.65±1.1 for
task 2. The mean amplitude of the first saccade to the left sided target was 6.081.3 for the
control condition, 6.15±1.3 for task 1 and 5.97±2.4 for task 2. Statistical analysis also showed
no significant differences between conditions for the velocity data (F(2,18)=1.19, n.s). The mean
velocity of the first saccade to the right sided target was 234±1.49/sec for the control condition,
228±67/sec for task 1 and 231±44/sec for task 2. The mean velocity of the first saccade to the
left sided target was 22067 for the control condition, 226±52/sec for task 1 and 215±84/sec
for task 2.
2.4 Discussion
Results from this study show that the accuracy of pointing responses associated with
saccades are not affected by the JM. These data help to clarify our previous findings, which show
that the JM affects pointing responses to targets presented in depth (Niechwiej-Szwedo et al.,
2006). Since the JM has a general effect on the gamma system, presumably affecting all muscles
(Delwaide & Toulouse, 1981), the pointing error obtained in the previous study could have been
due to the effect of the JM on the limb muscles instead of the EOM. Given that the non-twitch
motoneurons do not receive monosynaptic input from premotor areas involved in the
programming of saccades (Wasicky et al, 2004), the results from the current study support the
hypothesis that the pointing error obtained in the previous study was due to the effect of the JM
on the EOM muscles and not on the limb muscles.
As expected, we found that the JM did not affect the actual eye movements as shown by
the lack of significant differences in saccadic parameters between the control and experimental
conditions. Again, the negative findings from this experiment provide additional support to our
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hypothesis that the JM acts via the activity of non-twitch motoneurons and has no effect on the
twitch motoneurons.
3.0 Experiment 2
3.1 Methodology
3.1.1 Participants
Eleven healthy adults (8 females) with no history of ocular disorders and a mean age
34±16 years participated in the second experiment.
3.1.2 Stimuli
The stimuli were 0.25 white dots displayed on a black background on a flat CRT
monitor (refresh rate 160 Hz). The display was programmed using VPixx (VPixx Technologies,
Inc., Montreal, QC), a graphics generation and psychophysics testing software, controlled by a
Macintosh G4 computer. The fixation stimulus was presented in the participants’ midline and the
other two targets were presented randomly at a 10 eccentricity to the left or right of fixation.
The comparison stimulus was also a 0.25 white dot and it was presented on the same side as the
target in one of five locations: 8, 9, 10, 11 and 12 away from the fixation stimulus.
3.1.3 Apparatus
The JM manipulation procedure was the same as described in the methods section of
experiment 1.
3.1.4 Procedure
Participants were seated in total darkness and performed a two-alternative forced choice
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task (2-AFC) using the method of constant stimuli. At the beginning of each trial participants
were instructed to look at the fixation dot, which was shown for a variable time ranging from 1.5
sec to 2 sec. The target was flashed briefly for 50 ms to the left or the right of fixation which was
determined randomly by the computer. Participants were instructed to move their eyes as quickly
as possible to the location were they saw the target appear and to keep fixating on that location.
The comparison target was shown after 2.5 sec at 1 of 5 possible locations and participants had
to report whether the comparison target was to the left or to the right of their current fixation.
There were three conditions: (a) control: participants executed the eye movement and made the
judgement without the JM; (b) task 1: participants performed the JM while the target was shown
and during the eye movement, but not during the perceptual judgment; (c) task 2: participants
performed the JM during the perceptual judgements but not during the eye movement (see Figure
10 for illustration of the protocol).
3.1.5 Data analysis
For each participant, the proportion of ‘left’ responses was calculated for each, target
presentation side and task at the five locations where the comparison target was shown and a
psychometric function was fitted. All psychometric curves were visually inspected for trends.
Subsequently, an overall psychometric function based on the mean of all participants was fitted
for each task.
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Figure 10: Schematic illustration of the experimental protocol used in experiment 2: (a) control:
no JM; (b) task 1: JM performed during the presentation of the standard target and saccade; (c)
task 2: JM performed during perceptual localization.
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Data for each participant, target side and task were fitted using a logistic regression (SAS,
ver 8.1). The goodness of fit of the model was tested using the Hosmer-Lemeshow statistic and
a non-significant result was used to verify that the logistic model was appropriate. The point of
subjective equality (PSE) was calculated using the estimated parameters (slope and intercept)
from the logistic model. The PSE is the point at which the logistic function yields a probability
of 0.5 (i.e. the comparison target is perceived to the left of the standard target 50% of the time).
The PSE, intercept and slope were submitted to repeated measures ANOVA each with task
(control, task 1, task 2) and target side as the independent variables.
3.2 Results
Preliminary inspection of the individual psychometric curves did not reveal any
consistent trends in differences between the conditions. The logistic model fitted the majority of
the psychometric curves well (62 out of 66). Although in four cases (two in the control condition,
one in task 1 and one in task 2) the Hosmer-Lemeshow test was statistically significant (i.e., the
data did not fit the model), the logistic model was still used to fit the data.
The mean psychometric curve is shown in Figure 11. Results from the statistical analyses
showed no significant interaction effect between the experimental conditions and target side:
PSE (F(2,19)=3.28, p > .05), slope (F(2,19)=0.19, p > .05), intercept (F(2,19)=0.54, p > .05). The
main effect of condition was also not significant: PSE (F(2,20)=1.01, p > .05), slope
(F(2,20)=0.26, p > .05), intercept F(2,20)=0.13, p > .05).
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Figure 11: Mean proportion of ‘left’ responses for the five comparison targets (at ±10 both the
standard and comparison target were presented at the same location). (a) standard target
presented in the left hemifield; (b) standard target presented in the right hemifield. Error bars
show ±1 standard error of the mean.
4.0 Discussion
We conducted two studies to examine whether the JM affects the saccadic system
similarly to the vergence system, which would help us to elucidate the potential neural
mechanism involved in mediating the effect of the JM on the vergence system. We have
previously proposed that the JM acts through the activity of non-twitch motoneurons (Niechwiej-
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Szwedo et al., 2006) which receive monosynaptic input from premotor areas involved in the
programming of vergence eye movements but not from areas involved in the programming of
saccades (Wasicky et al., 2004). Thus, we hypothesized that if the JM acts through the non-
twitch motoneurons then the localization associated with saccades should not have been affected
by the manipulation. In contrast, if we had found that responses associated with saccades were
affected by the JM, then it would have been more likely that a different neural mechanism was
involved in mediating the effect. Overall, the results from both experiments showed that the JM
did not affect pointing or perceptual localization of targets presented in the frontal plane. Our
data support the first hypothesis and our earlier proposal that the JM affects the gain of the
proprioceptive feedback from EOM via the non-twitch motoneurons.
One of the limitations of our studies is the fact that our hypotheses are based on
neuroanatomical tracing studies which were conducted in sub-human primates. At the present
time it is unknown whether the human EOM fibers also receive dual innervation from ocular
motor nuclei (Buttner-Ennever et al., 2001). Nonetheless, human EOM do contain similar fiber
types to those found in primates and other mammals (Wasicky, Ziya-Ghazvini, Blumer, Lukas &
Mayr, 2000) and the PE are found in the global the multiply innervated fibers (MIF) in humans
(Richmond et al., 1984) and monkeys (Ruskell, 1978). Overall, the human and primate EOM are
remarkably similar in their organization, histochemical properties and repertoire of eye
movements, thus, we believe that it is likely that the dual innervation hypothesis can be extended
to humans as well.
A longstanding question in oculomotor physiology concerns the functional significance
of the MIF. It has been proposed that the MIF might participate in fine foveation eye movements
or might be part of a proprioceptive feedback loop (Spencer & Porter, 2005; Buttner-Ennever,
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Konakci & Blumer, 2005). These two possibilities are not mutually exclusive as it is certainly
possible that very fine eye adjustments rely on proprioceptive feedback. Moreover, the fact that
the global MIF are associated with the PE, the putative EOM proprioceptors, makes the
proprioceptive hypothesis viable. Two questions that remain are: 1) why is proprioceptive
feedback subject to gamma modulation when the localization response is associated with the
vergence but not with the saccadic system?, and more generally 2) what is the role of the gamma
system in oculomotor control?
The fact that the saccadic system was not affected by the JM perturbation in our study is
analogous to the findings of Guthrie and colleagues (1982) who reported that cutting the
monkeys’ ophthalmic branch of the trigeminal nerve (i.e., deafferentation) altered their vergence
responses but had no effect on their conjugate eye movements. Fusional vergence involves
disjunctive eye movements which are driven by disparity (i.e., the eyes move in opposite
direction when the stimulus falls on non-corresponding retinal points in order to avoid double
vision); thus, vergence eye movements require precise adjustment of both eyes to foveate the
target and maintain single vision. The CNS might monitor proprioceptive feedback from the
EOM for optimal performance in this task. In brief, our results reinforce the previous findings
and emphasize the importance of the EOM proprioceptive feedback loop for binocular function.
The modulation of proprioceptive feedback by the gamma system has been studied
extensively in the case of the skeletal system; in contrast, only one study, to our knowledge,
examined the gamma system in the EOM. Whitteridge (1959) demonstrated that proprioceptive
feedback from the EOM in the ungulate is modulated by the gamma system. Direct experimental
evidence of the gamma system in other species has been precluded by the lack of information
about the afferent pathway and location of the cell body. Nonetheless, we have used an indirect
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method to change the excitability of the gamma system by using the JM manipulation. Using this
proxy method we have provided evidence to support the notion that proprioceptive feedback
from the human EOM is also subject to gamma modulation.
It has been proposed that the gamma system is important for parametric adjustment of the
proprioceptive feedback loops to match the demands of different tasks (Prochazka, 1989). For
example, in the case of the skeletal system an increase in the sensorimotor gain is associated with
the performance of difficult or novel tasks in contexts that evoke generalized arousal and
vigilance. In other words, the gamma system allows state-dependent adjustment of
proprioceptive feedback which can be adjusted to address the specific sensorimotor requirements
predicted for the upcoming movement. An example of the parametric feedback adjustment for
the jaw muscles has been provided by Taylor and Gottlieb (1985). They suggested that the gain
of proprioceptive feedback might depend on the phase of the jaw movement. For instance, the
control of the velocity and displacement of the jaw are critical until the moment of tooth contact
whereupon the control of the force becomes critical. Moreover, they suggested that the CNS can
use proprioceptive feedback to determine the nature of the controlled variable (i.e., velocity or
force).
The requirement for gamma modulation of feedback from the EOM might be different
for saccades and vergence eye movements. Saccades are fast, ballistic eye movements ranging in
amplitude from 3 min arc to 90 and lasting between 15 to 100 ms. Programming of a saccade
involves a pulse and a step, which are related to the velocity and the amplitude of the eye
movement. In contrast, fusional vergence responses are slow (up to 1 sec) and generally small.
Vergence angle changes about 14 when gaze is moved from infinity to approximately 25 cm
(Howard, 2002). Even though horizontal saccades and vergence are both driven by the medial
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and lateral recti muscles, the differences in neural control for version and vergence eye
movements are reflected in the premotor input and the activity of the motoneurons. For example,
for conjugate adduction the premotor excitatory input comes from the abducens internuclear
neurons. In contrast, premotor input for convergence eye movements comes from supraocular
motor area (Mays, 1984). In addition, Mays and Porter (1984) reported that the relationship
between eye position and motoneuron firing rate is dependent on whether the eye movements are
conjugate or disconjugate. In their study, recordings were made from the abducens nucleus
during conjugate adduction and during convergence. Data showed that for a given eye position
the firing rate was greater for convergence compared to conjugate adduction suggesting that
there would be greater co-contraction in convergence.
Miller et al. (2002) tested this hypothesis by measuring the oculorotary forces in the
medial and lateral recti muscles during both types of eye movements. In contrast to the
hypothesis, they found decreased forces in both muscles. These results showed that the
innervation of the EOM is much more complex than previously acknowledged and that the motor
commands sent to the eye muscles differ during convergence and adduction. Given our results,
we propose that that the CNS can also set the gain of the proprioceptive feedback differently for
vergence and saccades via the gamma system.
In conclusion, we have examined whether registered eye position during saccadic eye
movements is affected by the JM manipulation which alters the excitability of the gamma
system. We have shown that the JM does not affect manual or perceptual localization of targets
presented in the frontal plane. Overall, data from the present study help to clarify findings from
our previous study which examined pointing in depth and strengthen our hypothesis that the JM
affects the activity of the non-twitch motoneurons. We propose that the non-twitch motoneurons
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might be involved in the parametric adjustment of the proprioceptive feedback loops to match
the demands of different types of eye movements.
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PAPER 3
MANIPULATION OF EXTRAOCULAR MUSCLE AFFERENCE
HAS NO EFFECT ON HIGHER ORDER PERCEPTUAL JUDGMENTS
1E. Niechwiej-Szwedo, E.G. González, B. Bahl, M.C. Verrier, A. M. Wong, M.J. Steinbach
Vision Research (2007); 47(26):3315-3323
1 See Appendix 1 for contributions of each author
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ABSTRACT
Observers perceive targets as farther while performing the Jendrassik Maneuver (JM)
suggesting that eye position is registered as more divergent. We examined the effects of the
JM perturbation in three studies of perceptual judgment that rely on accurate registration of
absolute distance: size constancy, stereoscopic depth, and the magnitude of the Pulfrich
illusion. The data showed no significant differences between the JM and control conditions.
The lack of an effect may be due to the fact that vergence is not a perfect cue to distance.
Furthermore, the relative contribution of extraocular muscle afference to registered eye
position may be less significant for higher order perceptual judgements.
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1.0 Introduction
Accurate estimation of egocenteric distance is not only critical for the performance of
reaching and grasping movements, but perceptual constancies, such as size and depth also
rely on accurate registration of absolute distance. The central nervous system (CNS) can
obtain depth information from static and dynamic monocular and binocular cues (Howard &
Rogers, 2002). Ocular vergence is an extraretinal binocular cue which has been shown to
provide crude but reliable distance information in a visually impoverished environment (for
reviews see Collewijn & Erkelens, 1990, Foley, 1980;).
Information about vergence eye position can come from two sources: the efference
copy (outflow) and afferent feedback (inflow) from the eye muscles (Steinbach, 1987). There
are at least two receptors in the extraocular muscles (EOM) that could provide proprioceptive
information about eye position: muscle spindles and palisade endings (PE) (for a review see
Donaldson, 2000). Muscle spindles have been unequivocally shown to provide
proprioceptive information from skeletal muscles; however, their role in EOM is not as clear.
First, muscle spindles are only found in the orbital layer of the EOM and they are
morphologically different from the spindles found in skeletal muscle (for a review see
Ruskell, 1989). Second, several species, such as cat, rabbit, horse, and mouse do not have
muscles spindles in their EOM (Maier et al., 1974). In contrast, PE have been found in the
EOMs of all the species tested to date, such as cat, rhesus monkey, sheep, rat, and human
(Alvarado-Mallart & Pinçon-Raymond, 1979; Blumer et al., 1998; Buttner-Ennever et al.,
2001; Eberhorn, Horn, Eberhorn et al., 2005; Richmond et al., 1984). PE are also referred to
as innervated myotendious cylinders (Ruskell, 1978) and they are uniquely associated with
the multiply innervated non-twitch fibers (MIF) of the global layer of the eye muscles.
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Neuroanatomical tracing studies by Buttner-Ennever and colleagues (2001) have
shown that the MIF receive innervation from a distinct set of non-twitch motoneurons found
in the periphery of the twitch motoneurons that control eye movements. The authors
hypothesized that these non-twitch motoneurons could be involved in modulating the gain of
sensory feedback from the extraocular muscles, analogous to the gamma (fibers which
control the sensitivity of muscle spindles in the skeletal muscles.
Our previous study (Niechwiej-Szwedo et al., 2006) tested the above hypothesis using
a behavioural approach and a manipulation called the Jendrassik maneuver (JM). The JM
refers to a voluntary, forceful contraction of any muscle group. While the JM is performed,
the amplitude of skeletal reflexes is facilitated (Delwaide & Toulouse, 1981; Murthy, 1978).
One of the mechanisms proposed to explain the reflex reinforcement effect is that the muscle
contraction has a general effect that results in up-regulation of the motoneuron activity
which increases the baseline excitability of muscle spindles and, consequently, results in a
larger response when the muscle is stretched. We hypothesized that the JM would also alter
the gain of the afferent feedback from eye muscles which would result in misregistration of
eye position and localization errors.
Altering the feedback from the eye muscles during vergence eye movements via the
JM resulted in misregistration of eye position. In particular, when the JM was performed, eye
position was registered as more divergent while the actual eye position did not change
(Niechwiej-Szwedo et al., 2006). Based on these results we hypothesized that the JM would
also alter higher order perceptual judgements that rely on accurate registration of absolute
distance. This hypothesis was tested in three experiments.
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In the first experiment, size constancy was examined while feedback from extraocular
muscles was perturbed by the JM. Since the vergence angle of the eyes is an important
source of extraretinal information contributing to size constancy, we hypothesized that
participants would perceive the size of a constant retinal stimulus as larger when feedback
from the eye muscles was altered via the JM.
Stereoscopic depth constancy was examined in the second experiment. Horizontal
disparities must be scaled by viewing distance in order for depth constancy to be preserved
and the vergence angle of the eyes can be used to calibrate horizontal disparities for different
viewing distances. We hypothesized that for the same disparity, the perceived depth would
be greater when the JM is performed compared to the control condition without JM.
In the third experiment we examined whether perceived depth during the Pulfrich
illusion was affected by the JM. In the Pulfrich effect a pendulum objectively swinging in the
frontal plane appears to move in an elliptical orbit in depth. The effect results from the
cortical time delay, interpreted as a disparity induced when one eye views it through a neutral
density filter. It has been shown that the perceived depth (i.e., the short axis of the ellipse) is
dependent on the viewing distance, so we hypothesized that the perceived depth would be
greater while participants perform the JM.
All participants in the three studies had normal or corrected-to-normal visual acuity of
20/20 and stereopsis of at least 40 seconds of arc as measured with the Titmus test (Titmus
Optical Co., Inc., Petersburg, Virginia 23805). All experimental protocols were approved by
the Ethics Review Boards at the University of Toronto and the University Health Network
and participants gave their informed consent prior to participating.
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2.0 Experiment 1: The effect of JM on perceived size
Even though the size of the image projected on the retina changes substantially over a
range of viewing distances, observers perceive the size of an object as relatively constant.
This is referred to as size constancy. There are three laws which describe the relationship
between the object size, image size and distance: 1) for a constant object size, the image size
varies inversely with distance, 2) for a constant image size, object size is proportional to
distance, and 3) image size is proportional to object size for an object presented at a fixed
distance (Howard & Rogers, 2002).
Observers are remarkably good at judging object size accurately in natural
environments where the CNS can use multiple cues to distance. As depth cues are reduced so
is the degree of size constancy and observers tend to rely more on the retinal image size to
make judgements (Ono, 1966). Ocular vergence and accommodation are the only cues that
the CNS can use in an unstructured visual environment to judge the size of unfamiliar
objects; however, vergence is only reliable when the distance to the stimulus is less than 2 m
(Harvey & Leibowitz, 1967; Leibowitz & Moore, 1966; Wallach & Floor, 1971).
The contribution of oculomotor cues to size perception within near visual space was
shown by Wallach & Zuckerman (1963). Participants were asked to judge the size of a wire-
form pyramid while vergence and accommodation were altered using mirrors and lenses. The
size estimates obtained experimentally varied accordingly with the changes in oculomotor
cues, thus confirming that the perception of size relies on these cues.
More recently, Mon-Williams and colleagues (Mon-Williams, Tresilian, Plooy, Wann
& Broerse, 1997) examined the role of vergence in explaining the illusory size change of an
afterimage (i.e., Emmert’s law, which states that the perceived size of an afterimage is
96
dependent on the perceived distance to the surface). Participants judged the vertical size of an
afterimage in two conditions. In the control condition, the card on which the afterimage was
created was moved by the participant but fixation was maintained on a stationary light
emitting diode (LED). In the experimental condition participants made converging or
diverging eye movements when judging the size of the afterimage. The experimental results
clearly supported the hypothesis that vergence is necessary and sufficient to explain the
illusory change in the size of the afterimage. Specifically, converging eye movements were
associated with a smaller perceived size of the afterimage whereas diverging eye movements
led to reports of a larger afterimage.
Experiment 1 was designed to examine whether the perceptual phenomenon of size
constancy was affected by the JM which has been shown to affect the registered vergence
eye position. We employed a two-alternative forced choice paradigm (2 AFC) and the
method of constant stimuli. The perturbation (JM) occurred when either the standard or the
comparison stimuli were shown. We hypothesized that the order of the JM would affect the
size judgement. Two specific predictions were made for the case when both the standard and
comparison stimuli had the same retinal size: 1) if the JM were performed while participants
viewed the standard stimulus, the comparison would be perceived as smaller, and 2) if the
JM were performed while viewing the comparison stimulus, participants would report it as
larger. Eye movements were not recorded in this study because our previous work had shown
that the actual vergence eye position was not affected by the JM (Niechwiej-Szwedo et al.,
2006). In addition, a pilot study using the current methodology measured the eye movements
of three participants and found no differences between the JM and control conditions.
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2.1 Methodology
2.1.1 Participants
Twenty healthy adults (9 males) with no history of ocular disorders and a mean age of
28±13 years participated.
2.1.2 Stimuli
The initial fixation stimulus was a green LED controlled by a custom-made trigger
box. The LED was placed at a distance of 25 cm in front of the participant in the midline.
The height of the LED placement was adjusted for each participant individually to prevent
obstruction of the stimulus.
The standard stimulus for the psychophysical procedure was a grey square (4.7
visual angle) presented on a black background and displayed on a flat CRT monitor (refresh
rate 85 Hz). The viewing distance was 100 cm. There were five comparison stimuli: 4.5,
4.6, 4.7, 4.8 and 4.9. The display was programmed using VPixx (VPixx Technologies,
Inc., Montreal, QC), a graphics generation and psychophysics testing software, controlled by
an Macintosh iBook computer.
2.1.3 Apparatus
The JM consisted of an isometric voluntary contraction against resistance with the
abductor muscles of the legs. The device used for resistance was a Thigh Master™.
Participants were asked to perform each contraction at a 75% level of their maximal
voluntary contraction, which was determined prior to the initiation of the experiment. To
ensure that the isometric contraction was performed at a consistent level throughout the
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experiment, a string was tied around the Thigh Master™ which pulled taut when the muscle
contraction was executed. Participants were instructed to hold the string taut while
performing the JM.
2.1.4 Procedure
Participants were seated in complete darkness. At the beginning of each trial they
fixated on the LED for 2.5 sec in order to standardize the initial vergence eye position. As
soon as the LED was switched off, the standard stimulus was presented for 2.5 sec and
participants were asked to fixate on it and to remember its size when it disappeared. The
comparison stimulus was shown at the same location 1.5 sec after the standard had
disappeared. Five sizes of the comparison stimulus were tested and their presentation order
was determined randomly by the computer. On each trial participants were asked to report
whether the comparison stimulus was ‘smaller’ or ‘larger’ than the standard. The comparison
stimulus disappeared after participants made the judgment. There were three experimental
conditions: Control: the judgment task was performed without the JM; Task 1: participants
performed the JM while viewing the LED and the standard stimulus and relaxed the
contraction before the comparison stimulus was presented (verbal judgment was made
without the JM); Task 2: participants fixated the LED and the standard stimulus without the
JM and started the JM when the standard stimulus disappeared (verbal judgement was made
with JM). The protocol is illustrated in Figure 12. The five comparison stimuli were tested 10
times in each experimental condition for a total of 150 trials. All experimental conditions
were completely randomized.
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Figure 12: Schematic illustration of the experimental protocol used in experiment 1.
2.1.5 Data Analysis
The proportion of ‘smaller’ responses was calculated and plotted for each participant
and condition for the five sizes of the comparison stimuli. Data was visually inspected for
trends and then fitted with a psychometric function using a logistic regression (SAS, Ver.
8.1). The goodness of fit of the model was tested using the Hosmer-Lemeshow statistic and a
non-significant result was used to verify that the logistic model was appropriate.
Subsequently, an overall psychometric function based on the means of all participants was
fitted for each task.
For each participant, the point of subjective equality (PSE) and the just noticeable
difference (JND) were calculated using the estimated parameters (slope and intercept) from
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the logistic model. The PSE is the point at which the logistic function yields a probability of
0.5 (i.e., the comparison stimulus is perceived as smaller than the standard stimulus 50% of
the time) and it reflects the accuracy of the judgment. The JND is the smallest possible
physical difference that can be detected reliably and it reflects the precision of the judgment.
The PSE, JND, intercept, and slope were submitted to a one-way repeated measures ANOVA
each with condition (control, task 1, task 2) as the independent variable.
The magnitude of the illusion (i.e., the proportion of ‘smaller’ responses) was
examined for the condition in which the comparison stimulus was the same size as the
standard. Data for each participant and condition were submitted to a one-way repeated
measures ANOVA with condition (control, task 1, task 2) as the independent variable.
2.2 Results
Preliminary inspection of the individual psychometric curves did not reveal consistent
differences between the conditions. The data were collapsed and the mean performance of all
participants in each condition is shown in Figure 13. The mean psychophysical curves clearly
show that participants were able to judge the size of the comparison square accurately in each
of the conditions.
The logistic model fitted the experimental data well for the majority of the psychometric
curves (59 out of 63), which was supported by the non-significant result from the Hosmer-
Lemeshow test. Although in four cases (one in Task 1 and three in Task 2) the test was
statistically significant, the logistic model was still used to fit the data. In contrast to the
hypothesis, no significant differences were found for any of the variables: PSE
(F(2,38)=2.61, n.s.), JND (F(2,38)=1.52, n.s.), slope (F(2,38)=1.53, n.s), y-intercept
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(F(2,38)=1.21, n.s). The magnitude of the illusion was not significantly different at the point
where both the standard and comparison stimuli were physically the same (F(2,38)=1.20,
n.s.).
Figure 13: Mean proportion responding ‘smaller’ for each of the five sizes of the comparison
square (at 0 both the standard and comparison squares were the same physical size, negative
values indicate that the comparison square was smaller). Error bars show 1 standard error.
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2.3 Discussion
It was expected that the order of JM would affect the size judgments; however,
neither the accuracy nor the precision of the perceptual judgment were affected by the
perturbation. A potential weakness of the experiment is that participants were aware that the
stimulus was always presented on a flat monitor screen at a fixed distance. Previous research
has shown that observers tend to make judgments of distal (object) or proximal (image) size
depending on the experimental conditions. For example, when no specific instructions were
given and with unrestricted viewing, observers tended to judge the distal size. In contrast,
when all visual cues were eliminated and viewing was monocular, observers judged the
proximal size (Ono, 1966). When only binocular cues were present, observers also tended to
judge the distal size and size constancy was preserved, at least up to 30 feet (Chalmers,
1952). Although the current experiment was conducted in the dark and no other visual cues
were available, participants could have relied on the oculomotor cues of vergence and
accommodation. Thus, it is likely that participants used distal size to make judgements in the
current study.
3.0 Experiment 2: The effect of JM on stereoscopic depth judgments
The perceptual phenomenon of depth constancy is conceptually similar to size
constancy and refers to the ability of the observer to judge the linear extent of a stimulus in
the saggital plane accurately despite changes in viewing distance (Ono & Comerford, 1977).
Depth constancy depends on the accurate registration of disparity and fixation distance.
When two images are separated in depth, they fall on non-corresponding or disparate retinal
points, which is the bases of stereopsis. By convention, points that are nearer to the observer
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than the fixation point have crossed disparity, conversely, points farther than the fixation
point have uncrossed disparity. Stereopsis is one of the cues contributing to depth perception
but it can only provide relative information. Specifically, a given disparity can be associated
with different depth intervals depending on the fixation distance. For example, a disparity of
50 min arc will be interpreted as a depth interval of 5 cm when viewed at 50 cm or a depth
interval of 20 cm if viewed at 100 cm. Likewise, a 5 cm depth interval viewed at 100 cm will
have disparity of 12 min of arc and the disparity will be 4 times larger when viewed from 50
cm away. To sum up, for a constant physical depth, retinal disparity decreases in proportion
to the square of the absolute distance (Ono & Comerford, 1977). Therefore, in order for
depth constancy to occur, the CNS must take into account the fixation distance or, in other
words, horizontal disparity must be calibrated for different fixation distances.
Wallach and Zuckerman (1963) were among the first to empirically examine whether
changes in vergence and accommodation contribute to depth constancy. In their experiments
the oculomotor cues were altered by optical means and the obtained depth estimates
approximated those that were predicted by the inverse square law. A detailed examination of
vergence contribution to depth constancy was reported by Ritter (1977). All distance cues
except for convergence and accommodation were removed and participants viewed a
stereoscopically presented image of a pyramid at different viewing distances. Results showed
that in the case of vergence-accommodation conflict, the depth interval was perceived based
on the convergence distance.
Experiment 2 was designed to examine whether the perceptual phenomenon of depth
constancy could be modified by the JM. Participants were asked to judge the separation in
depth between two lines when the registered vergence eye position was perturbed by the JM.
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Since during the JM eye position is registered as more divergent, we hypothesized that
participants would perceive the depth interval as larger while the JM was performed as
compared to the control condition. Vertical lines were used instead of random dot
stereograms to reduce the likelihood of participants using vertical disparities to judge depth.
3.1 Methodology
3.1.1 Participants
Five healthy adults with no history of ocular disorders, mean age 27.26.6 years,
participated.
3.1.2 Stimuli
The stimuli consisted of two vertical white lines subtending 1.5° by 0.1° of visual
angle, which were presented on a black background inside a white square outline subtending
5° x 5° of visual angle. The stimuli were viewed on a flat CRT monitor (Viewsonic, refresh
rate 60 Hz) at a viewing distance of 57 cm. The stereo images were displayed with 5 crossed
disparities: 1.17, 2.34, 3.51, 4.68, 5.85 min of arc. A rating scale consisting of 10 horizontal
lines ranging in length from 1 mm to 10 mm was displayed at the end of each trial and
numbers from 1 to 10 were displayed above the corresponding horizontal line.
3.1.3 Apparatus
The stimulus presentation was controlled by VPixx (VPixx Technologies, Montreal,
QC), a graphics generation and psychophysics testing software, controlled by Macintosh G4
computer. The stereo images were seen using liquid crystal glasses (CrystalEyes
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Workstation, Stereographics, San Rafael, CA). The JM procedure was the same as in
Experiment 1.
3.1.4 Procedure
Participants saw the display with the room lights turned off. At the beginning of each
trial, they fixated on a standard vertical line presented for 1 sec. A second, or comparison,
vertical line appeared to the left of the first one with a variable crossed disparity and for a 2
second duration. Participants were instructed to remember the separation in depth between
the two vertical lines. After the comparison stimulus disappeared, participants were shown 10
horizontal lines and were asked to estimate the distance in depth between the two vertical
lines by choosing one of the horizontal lines. Participants made a verbal response indicating
the number (1-10) corresponding to the depth interval that they saw between the two vertical
lines. They were not informed that only five disparity stimuli were used. Participants
completed 10 trials for each stimulus disparity with and without the JM for a total of 100
stereoscopic depth judgments. For the JM trials participants started the isometric contraction
prior to seeing the stimulus with the disparity and held it while viewing it. Prior to data
collection, all participants completed 20 practice trials to become acquainted with the task.
3.1.5 Data Analysis
For each disparity value the mean perceived depth was calculated and plotted for all
participants. Data were fitted using a linear regression model. The slope and y-intercept
parameters obtained from the model were submitted to a paired Student’s t-test with
condition (control, JM) as the dependent variable.
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3.2 Results
The mean responses of all participants ranged in values from 2 to 7; thus, participants
used the middle range of the scale and responses at the limits were not frequent. The
individual curves showed that participants could judge the depth difference reliably, which is
evident in the slope values and the measure of goodness of fit of the model (Table 2). A
paired samples t-test showed no significant differences between the control condition and the
JM condition for the slope or y-intercept values. The lack of difference is illustrated in Figure
14 which shows the mean data of all participants.
Table 2: Parameters obtained from the linear regression model for individual participants
Participant Model fit (R2) Slope Y- intercept
value
Con
trol
JM Con
trol
JM Con
trol
JM
1 0.92 0.90 1.11 0.99 0.59 1.47
2 0.87 0.75 0.78 0.58 2.46 3.36
3 0.97 0.97 0.67 1.04 2.21 0.94
4 0.85 0.71 1.02 0.94 1.30 1.76
5 0.88 0.55 1.36 0.86 0.60 0.76
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Figure 14: Mean perceived depth for stereoscopically presented stimuli in experiment 2.
Error bars show 1 standard error.
3.3 Discussion
The experimental results did not confirm our hypothesis and showed that JM did not
affect judgments of stereoscopic depth. The CNS must use oculomotor cues or vertical
disparities in order for stereoscopic depth constancy to be preserved. The disparity stimulus
in the current study consisted of vertical lines presented at the midline so no vertical
disparities were present in the field of view and the CNS must have relied on the only
available cues, which were the vergence and accommodative state of the eyes.
We chose to examine the effect of JM on depth constancy by presenting the stimulus
using stereoscopic goggles, which allowed us to precisely control the disparity. However,
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stereoscopic presentation has a disadvantage: the oculomotor cues of vergence and
accommodation are in conflict (Ono & Comerford, 1977). The disparity stimulus which
drives the vergence system creates an illusion of depth, but there is no retinal blur and the cue
of accommodation informs the system that both stimuli are at the same distance. Ritter
(1977), however, showed that in a case of vergence-accommodation conflict the judgments
of perceived distance are based on the cue of convergence, so it is unlikely that the mismatch
between these cues contributed to the present findings. The next study was designed to
further examine the effect of JM on depth constancy using the Pulfrich phenomenon for
which there was no conflict between oculomotor cues.
4.0 Experiment 3: The effect of JM on perceived depth during the Pulfrich illusion
In the Pulfrich illusion, a pendulum moving sinusoidally in the frontoparallel plane
appears to move along an elliptical path plane when viewed through a neutral density filter
placed over one eye. Placing the filter in front of one eye creates a luminance difference
between the two eyes which leads to a temporal delay in transmitting visual information to
the cortex. The cortical time delay is interpreted by the CNS as binocular disparity of the
moving object between the images seen by the two eyes (Howard & Rogers, 2002).
The effect of fixation distance on the magnitude of perceived depth during the
Pulfrich illusion was studied by Lit and Hyman (1951). They systematically investigated
whether variables such as differences in illumination, distance to target, and velocity of the
target influenced the magnitude of the stereoscopic depth effect. Their results clearly showed
that for any given illumination difference value, the pendulum’s motion depended on the
fixation distance with the largest depth interval observed for the largest fixation distance and
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greater illumination difference between the two eyes. These results were later replicated by
Wallach and colleagues (Wallach, Gillam & Cardillo, 1979).
More recently, Nakamizo and Lei (2000) examined the magnitude of the illusion at
larger viewing distances raging from 1 m to 4 m for stimulus velocities of 0.2, 0.4, and 0.6
Hz. Two procedures for measuring depth were used: participants had to match the perceived
depth interval using a probe or to reproduce the depth interval using a tape measure.
Although there were no significant differences between the two response methods (matching
and reproduction), the matching response produced depth estimates that were closer to those
that would be expected if the Pulfrich effect increased in direct proportion to viewing
distance.
In summary, previous studies have shown that the perceived depth of the Pulfrich
effect depends on the viewing distance and vergence angle of the eyes; therefore, experiment
3 was designed to examine whether the perceived depth during the Pulfrich illusion is also
affected by the JM. Participants viewed the moving stimulus through a pair of different filters
placed in front of the two eyes: one of the filters was constant while the other was adjusted
by the participant. Participants were asked to null the apparent depth by adjusting one of the
filters. We hypothesized that during the JM the depth interval would be perceived as larger
and that in order to null the illusion participants would compensate by over-adjusting the
variable filter.
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4.1 Methodology
4.1.1 Participants
Five healthy adults with no history of any ocular disorders, mean age 47.213.5
years, participated in experiment 3.
4.1.2 Stimuli
The fixation stimulus was a 0.25 black dot and the target stimulus was a black
vertical 1.5 bar both displayed on a white background on a flat CRT monitor (Viewsonic,
refresh rate 85 Hz). The target stimulus moved sinusoidally in the frontoparallel plane at a
peak velocity of 15/sec. The display was programmed using VPixx (VPixx Technologies,
Inc., Montreal, QC) and controlled by a Macintosh G4 computer.
4.1.3 Apparatus
Participants viewed the vertical bar through a custom-made apparatus that contained
two round apertures. Participants were seated behind the apparatus and the height of the chair
was adjusted individually. A variable neutral density (ND) filter (luminance values ranging
from 2.5 cd/m2 to 102.5 cd/m
2) mounted on a movable wheel, was placed over the right
aperture. The density of the variable filter could be adjusted by turning a knob. A 360
protractor was attached to the movable wheel so that the responses could be read out with an
accuracy of 1/10 of a degree. Three constant, non-adjustable ND filters (0.2, 0.7, and 1.0 log
units) were used during the experiment and placed over the left aperture.
The JM procedure was the same as in Experiments 1 and 2.
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4.1.4 Procedure
At the beginning of each trial participants closed their eyes. The experimenter spun
the wheel with the variable ND filters to vary the initial value of the filter between trials. One
of the three ND filters, randomly determined prior to the experiment, was placed to cover the
left aperture. Participants opened their eyes when cued by the experimenter and viewed the
moving bar while fixating the dot. The moving target was viewed through different filters
over each eye which produced an illusion of elliptical movement (Pulfrich effect).
Participants were asked to null the illusion by adjusting the variable ND filter with the
movable knob. They were allowed as much time to make the adjustment as they needed to
make sure that the elliptical movement of the target stimulus disappeared. Once the
participant indicated that the illusion had disappeared, the experimenter recorded the
response which was the number indicated by the protractor. The task was performed while
participants performed the JM and without the JM and these two conditions were randomized
prior to the experiment. Participants completed five trials in each experimental condition for
a total of 30 trials.
4.1.5 Analysis
Data for individual participants were plotted for the three values of ND filters for the
two JM conditions and inspected visually for trends. Subsequently, data were submitted to 2-
way repeated measures ANOVA with two factors: condition (control, JM) and filter value
(0.2, 0.5, 1.0 log units).
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4.2 Results
Preliminary inspection of the individual response curves did not reveal consistent
differences between the experimental and control conditions. The data were collapsed and
the mean performance of all participants in each condition is shown in Figure 15. As
expected, analysis of variance (ANOVA) yielded a significant main effect of filter
(F(2,140)=541.68, p<0.0001) showing that the perceived depth interval varied across the
Figure 15: Mean values obtained when participants were asked to null the Pulfrich illusion by
adjusting the value of the variable filter. Error bars show 1 standard error.
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three filter values. Specifically, the largest depth interval was perceived with ND filter 1.0
which created the largest luminance difference between the two eyes. In contrast to our
hypothesis, there were no significant differences between the control and the JM condition
(F(1,140)=3.43, n.s.) and the interaction effect was also not significant (F(2,140)=0.36, n.s.).
4.3 Discussion
Although the Pulfrich effect has been shown to depend on viewing distance, the
current study showed that it was not affected by the JM perturbation. Overall, the results
from experiments 2 and 3 showed that the JM had no effect on the perceptual phenomenon of
depth constancy.
5.0 General Discussion
The purpose of our studies was to examine whether higher order
perceptual judgments which require accurate registration of absolute distance are
affected by a manipulation which we have shown alters the gain of the
proprioceptive feedback from the EOM. Contrary to our hypotheses, we found
that the JM manipulation did not significantly affect judgments of size, depth or
the Pulfrich illusion. These are important findings as they help to establish that
proprioceptive feedback plays a negligible role in maintaining the perceptual
phenomena of size and depth constancy.
Previous studies have shown that proprioceptive signals from the eye
muscles play a significant role in the programming of eye movements (see section
1.1.2.2, Knox et al., 2000; Weir & Knox, 2001), during egocentric localization
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tasks (Bridgeman & Stark, 1991; Gauthier et al., 1990a,b; Lewis & Zee, 1993;
Roll et al., 1991; Steinbach, 1987; Velay et al., 1994) and adaptation of smooth
pursuit (vanDonkelaar al., 1997).
Two methods have been used to manipulate EOM afference in binocularly intact
observers: a vibration stimulus applied over the muscle and passive deviation of the eye
using a suction lens. Vibration provides a good stimulus for activating the Ia afferents which
in skeletal muscles activate the tonic vibration reflex (i.e., contraction of the vibrated
muscle). Roll and colleagues (1991) applied vibration over the inferior rectus muscle while
subjectes were fixating a single light in the dark. During the vibration trials subjects reported
that the target moved up and they also pointed above the target. Similar results were obtained
by Velay et al. (1994) where vibration of the right lateral rectus muscle resulted in an illusory
movement of the target to the left. Overall, results from these studies suggest that vibration of
an EOM muscle leads to the perception that the muscle is lengthening, and participants report
that the target is moving in a direction opposite to that of the vibrated muscle.
The afferent signals from eye muscles can be also altered by passively moving the
eye using a suction lens. This method, introduced by Gauthier and colleagues (1990a), offers
a way of distinguishing the contributions of inflow and outflow to registered eye position.
The paradigm involves subjects fixating a target with one eye while the other eye is
occluded. In the first experimental condition the fixating eye is deviated, thus, the amount of
innervation sent to the muscles must be increased in order to maintain fixation. Since both
eyes receive the same amount of innervation during conjugate eye movements (Hering’s
law), the occluded eye should deviate by an amount corresponding to the efferent signal sent
to the fixating eye. In this condition, the efferent signal to the eye muscles must be increased
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to compensate for the perturbation, but the afferent feedback from the fixating eye is not
changing because the eye is not changing position. Therefore, this task allows one to examine
the effect of efference on registered eye position. The second experimental condition
involves passive deviation of the occluded eye. In this case, the amount of innervation does
not change, but the afferent feedback from the deviatated eye does change. Therefore, the
second condition allows one to examine the contribution of afference to regitstered eye
position.
The current study is the first examination of the role of afference in higher order
perceptual phenomena using the JM manipulation to alter the feedback from the eye muscles.
The JM has been used extensively to alter the excitability of spinal reflexes (Dowman &
Wolpaw, 1988; Gregory et al., 2001; Murthy, 1978; Zehr & Stein, 1999) and limb position
information (Yasuda et al., 2006). Our previous studies (Niechwiej-Szwedo & Steinbach,
2007) were the first to show that the JM can also be used to alter proprioceptive feedback
from the EOM. Specifically, we showed that participants made consistent perceptual errors
when localizing targets in depth during the JM while the actual eye position was not affected.
Thus, we expected that perceptual judgments that require accurate registration of depth
would be also affected by the JM. This was not confirmed by the results from the three
experiments.
The perceptual phenomena of size and depth constency depend on the preceived
distance, which is an internally generated estimate of the viewing distance. In the real world,
the neural estimate of viewing distance is based on multiple visual and oculomotor cues. In
the present experiments most visual cues were removed and oculomotor cues provided the
only input for distance estimation; nontheless, the perturbed vergence signal was not taken
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into account by the CNS. This result could be explained by considering the relative
contribution of efference and afference to registered eye position examined by Gauthier and
colleagues (1990a) and Bridgman and Stark (1991). Both studies used the passive eye
deflection paradigm (described above) and found significant localization errors with open-
loop pointing responses, which were always correlated with the direction of the deviated eye.
However, the localization errors were only found when the occluded eye was deviated by a
large amount (>10º). Based on the localization errors and using a regression analysis, these
authors calculated that the contribution of proprioception from the eye muscles to the
registered eye position was approximately 30%, under their experimental conditions. It is
possible that the afferent contribution from the EOM to judgments involving size and depth
constancy or the Pulfrich illusion is even less significant and is not actually used for higher
order perceptual judgments by the CNS. Alternatively, it is also possible that the perturbation
that we are using, i.e., the JM, is not large enough to disrupt perceptual constancies2. In short,
the lack of significant effect was most likely due to a combination of factors, such as the fact
that vergence is not a perfect cue to distance and the JM manipulation is not a strong
petrubation of the feedback from the extraocular muscles. In addition, perceptual constancies
rely on multiple cues and are not easily perturbed, therefore, a strong manipulation might be
necessary to definitively determine whether the afferent feedback from the eye muscles plays
a role in maintaining perceptual constancies.
In summary, results from the present study showed that altering feedback from the
EOM via the JM did not affect perceptual judgments of size or depth. The lack of a
significant effect might not be surprising given that the JM manipulation affects the
registered vergence eye postions, but vergence itself is not a perfect cue to distance. Overall,
2 We thank an anonymous reviewer for this suggestion.
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the role of afference in oculomotor control and visuomotor behavior is not well understood
yet; however, the current study is the first to report that perturbations of afferent input from
the extraocular muscles do not affect higher order perceptual judgements.
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PAPER 4
LOCALIZATION IN DEPTH IS NOT AFFECTED BY THE JENDRSSIK
MANEUVER IN PATIENTS OPERATED FOR STRABISMUS: CASE STUDIES
119
ABSTRACT
Strabismus is a disorder involving misalignment of the eye(s). Previous studies have reported
that surgery, which is a common treatment to correct the misalignment of the eyes, can
damage proprioceptive receptors in the eye muscles and patients might be left deafferented.
The present study tested whether surgically treated patients would be affected by the
Jendrassik Maneuver (JM) which was shown to alter registered eye position when
binocularly healthy observers localize targets in depth. It was hypothesized that the patients’
responses would not be affected by the JM perturbation because the surgeries most likely
compromised the extraocular muscle feedback loops. Data from patients with congenital
strabismus confirmed our hypothesis. A larger study should be conducted to determine
whether the lack of gain modulation was due to damage sustained from the surgical
intervention or whether patients had an abnormal proprioceptive apparatus prior to surgery.
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Introduction
Strabismus is an ocular disorder which involves misalignment of the eye(s). It is a
heterogeneous disorder which can be divided into several subtypes based on the deviation of
the eyes. For example, esotropia occurs when the eyes deviate medially, and exotropia refers
to laterally deviated eyes. Strabismus may be constant (the amount of deviation is constant
over time), intermittent (the eye deviates under some conditions, such as stress or anxiety). It
may be comitant (amount of deviation does not vary with gaze direction) or incomitant
(amount of deviation varies with gaze direction) as in paralytic strabismus (i.e., due to EOM
paralysis) (Von Noorden & Campos, 2002). The prevalence of strabismus in the general
population has been estimated to be between 3 and 6% (Stidwill, 1997; Graham, 1974).
The major consequences of a strabismus that has an early onset are deficits in
binocular function and amblyopia. Binocular function requires sensory and motor fusion:
sensory fusion involves the ability to fuse the retinal images from both eyes into a single
percept, and motor fusion refers to the ability to align the eyes using vergence eye
movements to maintain sensory fusion (Von Noorden & Campos, 2002). In healthy
individuals, when both eyes fixate an object, the lines of sight from both eyes intersect on it
and the images fall on corresponding retinal points thereby giving rise to a single percept. In
strabismus, the eyes are misaligned and the two images of the object fall on non-
corresponding retinal points. In young children and over time, the brain suppresses the visual
input from one eye, which can result in reduced acuity for that eye (amblyopia), and lack of
binocular function (stereopsis and vergence). Deficits in binocular function in patients with
strabismus can lead to difficulties in the performance of tasks that involve eye-hand
coordination (Fronius & Sireteanu, 1994; Grant, Melmoth, Morgan & Finlay, 2007), spatial
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localization (Weir, Cleary, Parks & Dutton, 2000) and saccadic conjugacy (Bucci, Kapoula,
Yang, Roussat & Bremond-Gignac, 2002; Kapoula, Bucci, Eggert, & Garraud, 1997).
Surgical intervention is often employed to correct strabismus. For example, for
esotropia, the surgical procedures are aimed at weakening the MR and/or strengthening the
LR (von Noorden & Campos, 2002). Recession of the MR muscle is performed to weaken
the muscle by changing the tangential force, thereby decreasing its rotational force on the
globe. It involves cutting the muscle tendon close to insertion and reinserting it on the sclera
posterior to the original insertion. Another procedure that is very effective in decreasing the
strength of the muscle is marginal myotomy, which is sometimes considered in cases of a
large deviation that cannot be corrected with maximal recession. Myotomy involves reducing
the number of contractile elements and it is rarely performed due to its irreversibility.
Resection of the LR muscle is performed to strengthen the muscle. It involves shortening the
length of the muscle by excising a portion of the tendon and reinserting it to the original
insertion.
A major goal of corrective surgery for strabismus is to obtain good alignment of the
eyes. The predominant view being that the potential for binocular function is greatest when
both eyes are aligned properly. The standard for the functional outcome of surgery is
stereopsis and fusional vergence eye movements, as well as symmetrical pursuit and OKN.
Unfortunately, these functional outcomes are frequently not obtained and as many as 50% of
children have to undergo multiple surgeries (Helveston, Neely, Stidham, Wallace et al.,
1999). It is possible that one of the factors contributing to the suboptimal outcome is the fact
that EOM afferent feedback loops are compromised during the surgery (Steinbach, 1987) .
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The development of optimal surgical techniques is partly hindered by the lack of
understanding of how the CNS processes and uses proprioceptive information from the
EOM. There is ample experimental evidence which shows that feedback from EOM
contributes to registered eye position during visuomotor tasks (for a review see Donaldson,
2000). In addition, we demonstrated that healthy observers are susceptible to a manipulation
of afferent feedback via the Jendrassik Maneuver (JM) while localizing targets in depth
(Niechwiej-Szwedo et al., 2006). The JM changes the excitability of spinal and brainstem
reflexes, presumably via the activity of the gamma system. Thus, we proposed that the CNS
might modulate the gain of the afferent signal from EOM possibly via the activity of the non-
twitch motoneurons identified by Buttner-Ennever and colleagues (2001). It has been
hypothesized that the non-twitch motoneurons could be involved in modulating the gain of
sensory feedback from EOM, analogous to the gamma-efferent fibers which control the
sensitivity of muscle spindles in the skeletal muscles (Buttner-Ennever et al., 2002; Porter et
al., 1995; Robinson, 1991).
The present study examined the effect of JM on target localization in patients with
strabismus who have had surgeries that potentially compromised the EOM feedback loops.
We have previously reported that the JM altered registered vergence eye position in
binocularly healthy observers (Niechwiej-Szwedo et al., 2006), thus, we used the same
protocol to examine whether patients’ responses were also affected by the perturbation. It
was hypothesized that patients’ responses would not be affected by the JM perturbation
because the gain of sensory signal could not be altered via the non-twitch motoneurons due
to compromised EOM proprioceptive receptors and/or afferent pathway.
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Methodology
Patients
Five patients (aged 16-55 years) who underwent surgical treatment for strabismus
were tested in the experiment. Due to the heterogeneity of the disorder, each patient is
described in detail in Table 1. All patients had a self reported binocular corrected visual
acuity of 20/20 or better. Patients were included in the study if they had binocular
stereoacuity of at least 140 sec arc, as determined by the Titmus test. The fact that patients
were required to have residual stereoactuity to participate in the experiment restricted the
number of eligible patients who were able to complete the study. The experimental protocol
was approved by the Ethics Review Boards at the University of Toronto and the University
Health Network and participants gave their informed consent prior to participating.
Experimental Procedure
The experimental procedure used in this study was exactly the same as that of
Experiment 2, in Paper 1 (described on pages 51 to 53 of this thesis). Briefly, patients were
tested using a two-alternative forced choice procedure while seated in the dark. Two targets
(visual angle 0.25) were presented sequentially in depth and patients had to report whether
the second target was nearer or farther than the first one. The standard target was presented at
a viewing distance of 69.7 cm throughout the experiment. The comparison target was shown
randomly at one of 5 locations and the viewing distance ranged between 67.6 cm to 71.7 cm.
The vergence angle required to converge the 5 targets ranged between 5 to 5.5 degrees.
124
Table 3: Patients’ clinical characteristics and surgical procedures
Patient Gender Age Age at
surgery
Stereoacuity
(arc sec-1
)
Deficit prior to surgery Surgical procedure
1 M 16 First: 2
Second: 7
140 Congenital left esotropia,
bilateral IO overactivation
Left exotropia developed two
years after first surgery
First: left MR recession (4.5 mm),
bilateral IO myotomy
Second: left LR recession (7 mm)
2 F 45 <2 40 Congenital left esotropia Could not be obtained
3 F 17 16 40 Congenital right 4th
nerve
palsy
Left IR recession (2.5 mm)
Right IO myectomy (5 mm)
4 F 55 54 60 Left 6th
nerve palsy due to
previous surgery to remove a
tumour
Transposition of left SR and IR to
strengthen the LR
5 M 43 43 40 Acquired right 4th
nerve palsy
due to head injury
Right IO recession (10 mm)
*MR = medial rectus; LR = lateral rectus; IR = inferior rectus; SR= superior rectus; IO = inferior oblique.
125
One of the comparison targets was shown at the same location as the standard target and the
other four were shown closer or farther than the standard. There were four experimental
conditions: (a) Control: standard and comparison targets were shown with no JM; (b) Task 1:
standard target appeared during the JM, and comparison target appeared after the JM was
released; (c) Task 2: standard target appeared when the JM was not performed, and the
comparison target appeared during the JM; (d) Task 3: standard and comparison targets
appeared while the JM was performed (see Figure 4 for an illustration of the protocol). The
experimental conditions were completely randomized. In each experimental condition the
comparison target was shown 10 times at each of the 5 locations for a total of 200 trials per
participant.
Results
Data for each patient were plotted individually and are presented in Figure 16. Visual
inspection of the data from three of the patients (patients 1 to 3) clearly show that the JM did
not affect the perceptual localization judgement. In contrast, patient 4 showed a similar
pattern of responses as the binocularly healthy observers (described in Paper 1, experiment
2), which is apparent in Figure 16. This patient reported that the location of the comparison
target was ‘farther’ while performing the JM in comparison to the condition when the JM
was performed during the presentation of the standard target. The psychometric functions of
patient 5 are more variable. There is a difference between the conditions when the JM was
performed during the presentation of the standard and comparison targets. Similarly to
patient 4 and the binocularly healthy observers, patient 5 reported that the comparison target
126
-2 -1 0 +1 +2
1.0
.8
.6
.4
.2
0
Location of comparison target (cm)
patient 1 patient 2
patient 3 patient 4
patient 5
control condition (no JM)
JM during standardJM during comparison
JM during standardno JM during comparison
no JM during standardJM during comparison
Location of comparison target (cm)
-2 -1 0 +1 +2
1.0
.8
.6
.4
.2
0
-2 -1 0 +1 +2
1.0
.8
.6
.4
.2
0-2 -1 0 +1 +2
1.0
.8
.6
.4
.2
0
-2 -1 0 +1 +2
1.0
.8
.6
.4
.2
0
Figure 16: Psychometric functions of the patients tested. The location of the comparison
target with respect to the standard is shown in cm with positive values indicating nearer and
negative farther positions from the observer. Proportion of ‘near’ responses for each
comparison target location (at 0 both targets were presented at the same location).
127
was ‘farther’ when the JM was performed during the presentation of the standard target for 3
(out of 5) possible locations of the comparison. However, this was not the case when the
comparison target was presented nearer than the standard target (Figure 16, patient 5).
Discussion
The purpose of this study was to determine whether patients who had undergone
strabismus surgery were susceptible to a manipulation that has been shown to alter registered
vergence eye position in binocularly healthy observers. It was hypothesized that patients who
had surgeries on their eye muscles would not be affected by the JM because the afferent
feedback loops would have been compromised by the surgeries. Specifically, since the
experimental task requires vergence eye movements, it was expected that patients who have
had surgeries on their horizontal eye muscles would have been least affected by the JM
manipulation. Although patients tested in the study had different deficits prior to surgery and
a variety of surgeries, data from three patients who had congenital strabismus supported the
hypothesis. Two of these patients had infantile esotropia and the surgery was performed on
the horizontal muscles in one of the patients (patient 1). The medical record for patient 2
could not be obtained, but the surgery was most likely performed on the horizontal muscles.
In contrast, patient 3 who was also not affected by the JM manipulation had surgery on the
inferior rectus and inferior oblique muscles. Data from the two patients who had acquired
strabismus do not support the hypothesis. One of these patients (patient 4) had a transposition
surgery which consisted of a partial transposition of the muscle fibers from the superior and
inferior recti to strengthen the lateral rectus. Since this surgery did not involve a complete
tenotomy, it is possible that the proprioceptive feedback loop was not affected to the same
128
extent compared to the other surgeries; thus the patient was able to perform the task similarly
to observers who did not have surgeries. Data from patient 5 is more variable which might be
partly explained by the etiology. The patient acquired superior oblique palsy due to a head
injury. The fact that a diffuse head injury might have affected his ability to concentrate and
perform the task consistently on all trials could not be ruled out. Alternatively, it is also
possible that the surgery disrupted the proprioceptive feedback loops to some extent which
resulted in increased variability of the responses.
The fact that surgical intervention can compromise the EOM afferent signals has been
previously reported by Steinbach and Smith (1981). Specifically, open-loop pointing
responses were examined in two groups of patients: one group that had had a single surgery
and a second group that had more than one surgery on the same eye muscles. The data
showed that patients in the first group were able to point accurately to targets immediately
after the surgery when the eye was uncovered and before visual experience was allowed.
Furthermore, the shift in the pointing responses corresponded to approximately one-quarter
of the amount that the eye was rotated during the surgery. These data suggest that patients
were able to use proprioceptive signals from the EOM to inform the CNS about the
surgically altered eye position. In contrast, the localization responses of patients in the
second group who had had multiple surgeries did not show a significant difference after the
surgery, which means that the altered eye position was not taken into account by the CNS.
The difference in performance between the patients that had one surgery in comparison to
patients who had multiple surgeries was most likely due to the progressive damage to the
EOM proprioceptors sustained during successive surgeries. Even a single surgery can
compromise the EOM afferent signal if there is significant damage to the myotendinous
129
junction. For example, Steinbach, Kirshner and Arstikaitis (1987) compared the effects of
recession and marginal myotomy and found that following myotomy, patients did not use the
proprioceptive signal to compensate for the changed eye position.
In the present study we tested patients who had different types of surgeries and only
one patient had two surgical interventions. Despite this, data from three patients clearly
showed that the gain of EOM feedback was not altered by the JM perturbation. There could
be several reasons to explain the lack of effect. First, it is possible that the surgery
compromised the receptors at the myotendinous junction, particularly in the patient who
experienced more than one surgery. Second, the gain of the signal could have also been
compromised if the afferent or the efferent nerves which supply the PE were affected by the
surgery. At present, the course of the afferent fibers has not been fully traced, but several
studies have shown that the afferent nerve travels with the ocular motor nerves and then
transfers to the ophthalmic branch of the trigeminal nerve near the apex of the orbit or in the
region of the cavernous sinus (for review, see Donaldson, 2000). It is also possible that the
surgery affected the axon that runs along the muscle fiber to the tendon and then loops back
to enter the capsule as it bifurcates to supply the PE.
One of the limitations of this study is the fact that patients were only tested after
surgery. Thus, it can not be determined whether the lack of gain modulation was due to
damage sustained due to the surgical intervention or whether these patients had an abnormal
proprioceptive apparatus prior to surgery. The three patients who were not affected by the JM
manipulation all had congenital deficits. Two studies that previously examined the EOM
myotendinous junction of patients who had congenital strabismus reported structural
alterations in the receptors and their innervation (Corsi, Sodi, Salvi & Faussone-Pellegrini,
130
1990; Domenici-Lombardo, Corsi, Mencucci, Scrivanti, Faussone-Pellegrini & Salvi, 1992);
thus, it is possible that gain modulation was impaired in these three patients prior to surgery.
The current study cannot distinguish between the two possibilities. Future studies should
examine a larger sample of patients both before and after the surgery.
In conclusion, the results from this study provide critical support for the hypothesis
that the effect of the JM on the localization responses in depth found in binocularly healthy
observers is specific to the eye muscles. The fact that the responses of patients with
congenital strabismus were not susceptible to the manipulation suggests that the effect most
likely depends on an intact EOM proprioceptive apparatus.
131
CHAPTER IV: GENERAL DISCUSSION
4.1 Summary of findings
The overall objective of this thesis was to test the hypothesis that the non-twitch
motoneurons associated with multiply innervated fibers (MIF) of the global layer of eye
muscles control the gain of proprioceptive feedback from the palisade endings (PE) in a way
analogous to the gamma-spindle system found in skeletal muscles, as proposed by Buttner-
Ennever and her colleagues (2002). The hypothesis was tested in a series of behavioural and
psychophysical studies which examined whether the afferent signals from the extra-ocular
muscles (EOM), and consequently registered eye position, was altered by a manipulation
which is known to affect the afferent feedback in skeletal muscles, presumably via the
gamma system.
Our behavioral studies with healthy human observers showed that the Jendrassik
maneuver (JM) affects registered vergence eye position. Specifically, participants reported
that targets were farther away during this perturbation which suggests that eye position was
registered as more divergent. The misregistration was evident with both manual and
perceptual responses. In contrast, neither the manual nor the perceptual localization of targets
in the frontal plane were affected by the JM. Since the non-twitch motoneurons receive direct
premotor input from areas involved in the programming of vergence but not saccadic eye
movements, our data support the hypothesis that the JM alters proprioceptive feedback from
EOM possibly via the activity of non-twitch motoneurons.
A critical finding from our studies was the fact that the kinematics of neither vergence
nor saccadic eye movements were affected by the JM. Since the non-twitch motoneurons do
not add to the force that is used to move the eyes (Fuchs & Luschei, 1971), the eye
132
movement data from our study yield further support for our hypothesis that the JM affects the
activity of the non-twitch motoneurons and not the twitch motoneurons.
In contrast to our hypotheses, higher order perceptual judgments that require accurate
registration of absolute depth were not affected by the perturbation. The lack of significant
effect might not be surprising given that the JM manipulation affects registered vergence eye
postion, but vergence itself is not a perfect cue to distance. Consequently, the perturbed
vergence signal was not taken into account by the central nervous system.
The last paper examined whether JM affects registered vergence eye position in
patients with strabismus who have had surgeries that most likely compromised the EOM
afferent feedback loops. As hypothesized, data showed that responses of patients with
congenital strabismus were not affected by the JM perturbation which might be due to the
fact that proprioceptive feedback could not be altered via the non-twitch motoneurons. These
results provide critical support for the fact that the effect of the JM depends critically on the
intact proprioceptive EOM feedback loop.
In summary, using a proxy method that alters the EOM afferent signal, possibly via
the activity of the non-twitch motoneurons, we provided behavioural evidence to support the
hypothesis proposed by Buttner-Ennever and colleagues (2002), and Robinson‟s original
claim that the PE and MIF might be part of an „inverted muscle spindle‟ (Robinson, 1991).
4.2 Significance
This project provides a novel insight into the mechanism involved in the use of
sensory feedback from the extraocular muscles. Data showed that the gain of proprioceptive
feedback was altered by the JM during vergence but not during saccadic eye movements. The
133
fact that the saccadic system was not affected is analogous to the findings of Guthrie and
colleagues (1982) who reported that cutting the monkeys‟ ophthalmic branch of the
trigeminal nerve (i.e., deafferentation) altered their vergence responses but had no effect on
their conjugate eye movements. Our results reinforce the importance of the EOM
proprioceptive feedback loop for binocular function.
An important question that remains is: What is the role of the gamma () system and
proprioception in general in oculomotor control and visuomotor behaviour? The unique
structure of the EOM and the fact that the cell body and the afferent pathway of the putative
proprioceptors, the PE, have not been definitively identified, makes it difficult to study the
question. The role of EOM proprioception in the control and execution of different types of
eye movements has been reviewed extensively by Donaldson (2000), but the possibility that
the system might modulate the gain of sensory feedback was only briefly mentioned.
It has been suggested that in the skeletal system “the fusimotor system allows state
dependent parametric adjustment of proprioceptive feedback” (Prochazka, 1989). The
implication of this hypothesis is that the loop is important for parametric adjustment of the
feedback loops to match the demands of different tasks, which might also be relevant for the
oculomotor system. For example, many studies have shown that the relationship between eye
position and the firing frequency of the ocular motoneurons is highly correlated (Carpenter,
1988). However, a study by Mays and Porter (1984) reported that the relationship between
eye position and firing rate is also dependent on the type of eye movement. In their study,
recordings were made from the abducens nucleus during conjugate adduction and during
convergence. Data showed that for a given eye position there was an increase in the firing
rate during convergence compared to conjugate adduction. Extending on these results, Miller
134
and colleagues (2002) measured the oculorotary forces in the horizontal recti muscles to test
whether the force developed in the lateral rectus is in fact higher in the converged state.
Paradoxically and in contrast to the hypothesis, they found decreased forces in both the
lateral and medial recti muscles during convergence. These results clearly showed that the
innervation of the EOM is much more complex than previously acknowledged, and it is
possible that the motor commands to the eye muscles differ during convergence and
conjugate adduction. In light of our results, it should also be acknowledged that the gain of
the proprioceptive system might be set differently for different types of eye movements.
The results of this project may have important clinical implications for the treatment
of strabismus. Surgical intervention is a common treatment for strabismus, but often does not
result in regaining of stereoscopic vision and vergence eye movements. In fact, as many as
50% of children have to undergo multiple surgeries (Helveston, Neely, Stidham, Wallace et
al., 1999). It is possible that the lack of success is partly due to the damage sustained at the
myotendinous region which contains the putative proprioceptors of the eye muscles.
However, it has also been suggested that sparing of the receptors which send abnormal
signals might contribute to sensory and motor deficits in binocular vision in patients with
strabismus (Steinbach, 1986). On the other hand, it is also possible that congenital
abnormalities of the sensory receptors and pathway contribute to the development of
strabismus and whether the surgery affects the receptors has no bearing on the outcome of
the surgery.
135
4.3 Limitations
Although our research provides a novel insight into the mechanism of EOM
feedback, it also has limitations. Our manipulation, the JM, has been used extensively to alter
the excitability of spinal reflexes and limb position information. There is no dispute that JM
alters the afferent signals and has a general effect that affects all spinal and brainstem
reflexes but no studies to our knowledge have been able to unequivocally explain the
neurophysiological mechanism involved. Despite the debate, we assumed that one of the
mechanisms through which the JM operates is the gamma system and we used it to perturb
the afferent signals from EOM. Since it has been shown that the gamma system might be
predominately involved in modulating the reflex response during the steady phase of the
isometric contraction (Phase 3) (Delwaide & Toulouse, 1980), we ensured that the
localization responses that participants were asked to make in all the experiments also
occurred in that phase. Although we used an indirect method, our data clearly show that JM
affected localization responses, but not the actual eye position, associated with vergence but
not versional eye movements. Overall, these results provided support for the proposal that the
JM altered the afferent signals from EOM via the activity of non-twitch motoneurons.
Results from our studies highlight the importance of reporting negative findings. The
significance of publishing negative results in oculomotor research was emphasized by the
study by Keller and Robinson (1971), which reported the absence of stretch reflexes in EOM.
In the present thesis, we reported negative results that supported our hypotheses in Paper 2
and in Paper 3 our predictions were not supported by the data. Findings from both papers are
valuable and it is important to disseminate these results as they help to understand the
mechanisms involved in EOM proprioceptive feedback control.
136
The use of a proxy method in a behavioural study to infer neurophysiological
mechanisms is a major limitation; however, it is currently the only method of investigating
the question whether the gain of afferent feedback from EOM can be altered via the gamma
system in humans. The only method that would provide unequivocal evidence for a gain
control regulation of proprioceptive feedback from the eye muscles would be recording from
the cell body of the EOM sensory neuron while stimulating the non-twitch motoneurons.
This type of experiment may never be possible in the humans and a proxy method offers the
only way of investigating the question. Even in sub-human primates no one has yet recorded
from the somata of the palisade endings.
Another limitation of the present study is the fact that our hypotheses are based on
neuroanatomical tracing studies conducted in sub-human primates. At present, it is unknown
whether the human EOM fibers also receive dual innervation from ocular motor nuclei.
Nonetheless, human EOM do contain similar fiber types that are found in the primates and
other mammals (Wasicky et al., 2000) and the PE are also associated with the global multiply
innervated fibers (Richmond et al., 1984). Overall, the human and primate EOM are
remarkably similar in their organization, histochemical properties and repertoire of eye
movements so it is likely that the dual innervation hypothesis can be extended to humans as
well.
4.4 Future direction
The studies presented in this thesis were the first to examine whether sensory
feedback from EOM can be altered by a manipulation that presumably changes the
excitability of the gamma system. Data provide strong, but preliminary, support for the
137
hypothesis that the gain of EOM proprioceptive feedback loops might be set differently to
match the demands of different types of eye movements. Due to the limited scope of the
thesis, only two types of eye movements were examined: vergence and saccades. Future
studies should examine whether the JM also affects other oculomotor systems. For instance,
since the non-twitch motoneurons receive direct premotor input from the area involved in
gaze-holding mechanisms and pursuit (Wasicky et al., 2004; Ugolini et al., 2006), these
should be examined next. In particular, a recent retrograde tracing study by Billig and Strick
(2007) showed that the cortical inputs to the MIF come from the frontal eye field area that is
predominately involved in smooth pursuit. Our pilot studies have shown that pursuit of
targets in the frontal plane was not affected by the JM; however, this does not negate the fact
that pursuit of targets moving in depth might be affected, which should be examined next.
The proxy method we used to alter the activity of the gamma system is not the only
means by which the gamma system can be activated indirectly. Several studies have shown
that attentionally demanding tasks, such as mental calculation can also increase spindle
activity without concomitant activation of the alpha motoneurons (Ribot, Roll & Vedel,
1986; Ribot-Ciscar et al., 2000; Rossi-Durand, 2002). These studies used microneurography
and inferred gamma activity from the recordings from Ia afferents. One of the only studies
that directly recorded from gamma motoneurons confirmed that their activity was selectively
enhanced by mental computation, pinna twisting, startling the subject by hand clapping
behind their back or changes in the environmental conditions. Overall, these studies suggest
that gamma activity can be enhanced indirectly by any task that increases arousal, thus, any
of these tasks could be used instead of the JM to confirm the results of the current studies.
138
Results of this project may have important clinical implications for the treatment of
strabismus but only a few patients were tested and future studies should replicate the
experiment with a larger population. Additionally, patients who participated in the our study
(paper 4) had different deficits and surgeries which could affect the proprioceptive feedback
loops differently. We were unable to ascertain whether their performance characteristics were
due to damage sustained by the myotendinous junction involving the palisade endings or to a
disruption of the pathway that modulates the gain of proprioceptive feedback from extra-
ocular muscles. To shed more light on this issue, future studies should examine patients pre
and post surgical intervention.
In conclusion, after years of neglect, extra-ocular muscle proprioception has received its
due attention in the past few years. It is now indisputable that both afferent and efferent
signals play a role in oculomotor control and visuomotor behaviour and must be taken into
account when developing models of oculomotor control. Furthermore, the efferent signals
that have to be considered must include the alpha and gamma systems.
139
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Appendix 1
Contribution of each author:
1. Ewa Niechwiej-Szwedo: design of the experiments, generation of hypotheses,
programming and generation of the stimulus, data collection, data analysis (including
statistical analysis), writing of the manuscripts.
2. Esther Gonzalez (advisory committee member): psychophysics and design of
experiments, generation of hypotheses, programming and generation of the stimulus,
comments on the manuscripts.
3. Agnes Wong (advisory committee member): discussion of experimental approach,
comments on the manuscripts.
4. Molly Verrier (supervisor): discussion of experimental approach, comments on the
manuscripts.
5. Martin J. Steinbach (supervisor): experimental approach to use the JM to manipulate
the gamma system, design of experiments, generation of hypotheses, comments on
the manuscripts.
6. Sivan Bega (summer student): data collection and analysis for experiment 3 in paper
1.
7. Bharat Bahl (summer student): data collection and analysis for experiment 1 in paper
3.
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