spatial interactions reveal inhibitory cortical networks in human
TRANSCRIPT
www.elsevier.com/locate/visres
Vision Research 45 (2005) 2810–2819
Spatial interactions reveal inhibitory cortical networksin human amblyopia
Erwin H. Wong a,*, Dennis M. Levi a,b, Paul V. McGraw c
a School of Optometry, University of California, Berkeley, CA 94720, USAb Helen Wills Neuroscience Institute, University of California, Berkeley, CA 94720, USA
c Department of Optometry, University of Bradford, Bradford BD7 1DP, UK
Received 24 August 2004; received in revised form 1 June 2005
Abstract
Humans with amblyopia have a well-documented loss of sensitivity for first-order, or luminance defined, visual information.
Recent studies show that they also display a specific loss of sensitivity for second-order, or contrast defined, visual information;
a type of image structure encoded by neurons found predominantly in visual area A18/V2. In the present study, we investigate
whether amblyopia disrupts the normal architecture of spatial interactions in V2 by determining the contrast detection threshold
of a second-order target in the presence of second-order flanking stimuli. Adjacent flanks facilitated second-order detectability in
normal observers. However, in marked contrast, they suppressed detection in each eye of the majority of amblyopic observers. Fur-
thermore, strabismic observers with no loss of visual acuity show a similar pattern of detection suppression. We speculate that
amblyopia results in predominantly inhibitory cortical interactions between second-order neurons.
� 2005 Elsevier Ltd. All rights reserved.
Keywords: Amblyopia; Second-order; Lateral interactions; Visual cortex
1. Introduction
Amblyopia is a disorder of spatial vision, usually
present in one eye, which results from discordant binoc-
ular input to the visual cortex during development.
Amblyopia is typically associated with strabismus (eye
misalignment) or anisometropia (unequal refractive er-
ror). A loss of contrast sensitivity for first-order (lumi-nance defined) spatial information is well documented
in amblyopic eyes, and is widely attributed to neural def-
icits at the level of striate cortex (V1) (Kiorpes &
McKee, 1999). Neurophysiological studies have shown
that the response of V1 neurons to a first-order, near
threshold stimulus placed within its receptive field can
be facilitated (response increased) (Bakin, Nakayama,
0042-6989/$ - see front matter � 2005 Elsevier Ltd. All rights reserved.
doi:10.1016/j.visres.2005.06.008
* Corresponding author. Tel.: +1 314 516 6516; fax: +1 314 516 5150.
E-mail addresses: [email protected] (E.H. Wong), dlevi@berkeley.
edu (D.M. Levi), [email protected] (P.V. McGraw).
& Gilbert, 2000; Kapadia, Ito, Gilbert, & Westheimer,
1995; Nelson & Frost, 1985; Polat, Mizobe, Pettet,
Kasamatsu, & Norcia, 1998) or suppressed (response re-
duced) (Knierman & Van Essen, 1992; Levitt & Lund,
1997; Walker, Ohzawa, & Freeman, 1999) by flanking
first-order stimuli. The type of interaction, i.e., facilita-
tory or suppressive, depends upon the spatial distance
between target and flanks, the relative orientation differ-ence between the elements that comprise the target and
flanks, and the magnitude of the flank contrast
(Kapadia, Westheimer, & Gilbert, 1999; Polat et al.,
1998). Such cortical interactions are thought to form
the cellular basis to psychophysical demonstrations of
enhanced visibility for first-order stimuli flanked by
facilitatory masks. Psychophysical studies have shown
that target and flank conditions which produce facilita-tion (lower the contrast detection threshold) in normal
eyes (Kapadia et al., 1995; Levi, Hariharan, & Klein,
2002; Polat & Sagi, 1993, 1994; Yu, Klein, & Levi,
E.H. Wong et al. / Vision Research 45 (2005) 2810–2819 2811
2002) can result in suppression (increase the contrast
detection threshold), or reduced facilitation, in amblyo-
pic eyes (Levi et al., 2002; Polat, Sagi, & Norcia, 1997).
However, Polat, Ma-Naim, Belkin, and Sagi (2004,
2005) has reported reduced facilitation in amblyopic
eyes only for high spatial frequency stimuli, and in stra-bismic amblyopes more than anisometropic amblyopes.
Neurophysiological studies have shown that the tran-
sition from facilitatory to suppressive interactions re-
flects the spatial distribution of target and flanks either
within the classic receptive field (CRF) or its inhibitory
surround. The excitatory CRF and larger (P2·) over-lapping inhibitory region form a center-surround mech-
anism (Angelucci et al., 2002; Cavanaugh, Bair, &Movshon, 2002a, 2002b) in which stimulation of the
annular surround suppresses the CRF response through
divisive modulation of the response gain but can not
drive the CRF directly (Cavanaugh et al., 2002a,
2002b). Anatomical evidence indicates that the excitato-
ry spatial limit of the CRF is formed by horizontal con-
nections within V1 (i.e., connections between cortical
columns) and the inhibitory surround is largely formedby feedback connections from V2 to V1 (Angelucci
et al., 2002; Cavanaugh et al., 2002a; but see Stettler,
Das, Bennett, & Gilbert, 2002). Therefore, the abnormal
pattern of spatial interactions for first-order visual stim-
uli reported in amblyopic observers could result from
either abnormal horizontal connections in V1, and/or
feedback connections from V2 to V1.
In comparison with the striate cortex, much less isknown about the effects of amblyopia on extra-striate
cortical structure and function. Visual processing in
the extra-striate cortex (V2) can be investigated using
second-order spatial stimuli, e.g., a visual stimulus de-
fined by contrast modulations. Contrast modulation fre-
quencies are not represented in the Fourier spectrum of
an image, and therefore demodulation is required for
stimulus detection—this has been extensively modeledas a filter-rectify-filter processing cascade (Chubb &
Sperling, 1988). Briefly, luminance modulations of high
spatial frequencies undergo linear filtering in V1, the
output is rectified (the demodulation step), and this en-
ables contrast modulations of low spatial frequencies to
be detected by a second-stage of linear filtering. There is
compelling psychophysical evidence that first-order and
second-order spatial information can be processed inde-pendently in the visual cortex (Schofield & Georgeson,
1999, 2003; Willis, Smallman, & Harris, 2000). Further-
more, physiological studies in cat (Mareschal & Baker,
1998; Zhou & Baker, 1994) and monkey (Leventhal,
Wang, Schmolesky, & Zhou, 1998; von der Heydt &
Peterhans, 1984, 1989) place the locus of the second fil-
tering stage predominantly in area 18/V2.
In a previous study, we demonstrated a specific loss ofsecond-order sensitivity in individuals with amblyopia
(Wong, Levi, & McGraw, 2001). However, it is presently
unknown whether the pattern of spatial interactions
which occur in the visual cortex of normal, or amblyopic
observers, are qualitatively or quantitatively similar for
first- and second-order stimuli. We examine this issue
by psychophysically determining contrast detection
threshold for a second-order target in the presence of col-linear or orthogonal second-order flanks (equated for
visibility) in normal observers (control), amblyopic
observers, and observers with strabismus but no loss of
visual acuity. We found the flanking effect to be facilita-
tive in normals but suppressive in each eye of most
amblyopic and strabismic observers (subsequently re-
ferred to as non-control observers). We speculate that
human amblyopia results in predominantly inhibitoryhorizontal interactions between second-order neurons.
2. Methods
2.1. Observers
Six amblyopic observers, two observers with strabis-mus but no loss of visual acuity, and five normal (con-
trol) observers participated in the experiment. All
observers were adults and the visual characteristics of
the non-control observers are presented Tables 1A and
B. Control observers had normal or corrected-to-normal
vision. All observers were highly practiced at making
psychophysical judgements, wore refractive correction
as required, and all but the author (EW) were naı̈ve tothe task. Informed consent following the guidelines of
either the University of Houston or the University of
California was obtained from all observers prior to data
collection.
2.2. Apparatus
Stimuli were generated using the macro capabilitiesof NIH Image 1.62f (available from http://rsb.
info.nih.gov/nih-image/). The host computer was an
Apple Power Macintosh 6500/225 and stimuli were pre-
sented on a Dell monitor (21-inch screen, resolution
1024 · 768 pixels, frame refresh rate 75 Hz, and mean
luminance 15 cd/m2). The monitor output was made lin-
ear over the entire range used in the experiment via cal-
ibration with a photometer (Minolta LS-110 digitalluminance meter). To obtain accurate control of lumi-
nance contrast we increased the number of intensity lev-
els from 8 to 12 bits by combining the outputs of the red,
green, and blue guns via a video summation device (Pelli
& Zhang, 1991).
2.3. Stimuli
We used stationary, contrast modulations of random
static noise as second-order stimuli (Fig. 1). Stimuli were
Table 1
Visual characteristics of non-control observers
Subject Type Refractive error Acuitya Fixation Strabismus Stereoacuityb Treatment/age
(A) Visual characteristics of amblyopic observers
JF Aniso R �0.50–0.25 · 177 20/20 R/L central None None No surgery or patch;
25, M L +3.50 DS 20/50 glasses at 11
AH Strab R +0.50–1.00 · 93 20/50 R/L central R esotrope 12D None No surgery; patch at 7;
19, F L plano-0.75 · 100 20/25 glasses at 16
RH Strab R �1.00–0.50 · 170 20/15 R/L central, L esotrope 2D None No surgery or patch;
35, M L �1.50–1.50 · 010 20/40 L unsteady glasses at 12
AM Aniso R +2.50–1.00 · 010 20/50 R/L central None 320 s arc No surgery or patch;
22, F L �0.25 DS 20/20 contact lens at 7
DM Strab & R �0.50–0.25 · 92 20/20 R central, L exotrope 3D None No surgery or patch;
40, F Aniso L +2.50–1.00 · 160 20/80 L 0.5� nasal glasses at 12
DS Strab & R +2.25 DS 20/40 R 2� nasal L esotrope 8D None No surgery;
26, M Aniso L +0.50 DS 20/20 L central patch and glasses at 5
(B) Visual characteristics of observers with strabismus and no loss of visual acuity
RC Strab R plano-0.25 · 167 20/15 R/L central alt exotrope 8D, None No surgery, patch, or
33, M L +0.25–0.50 · 170 20/15 L hypertrope 6D glasses
WS Strab & R +2.75 DS 20/15 R/L central R exotrope 10D, None Surgery at 0.5, 3, 7;
50, F Aniso L +0.50 DS 20/20 R hypertrope 5D patch and glasses at 2
a Snellen chart.b Borish card.
2812 E.H. Wong et al. / Vision Research 45 (2005) 2810–2819
constructed by multiplying a random static noise back-
ground by a 2-D Gabor, and are mathematically de-
scribed by:
Lðx; yÞ ¼ ðLmean þ ðrand� 0.5ÞÞ� ðLmean þ Lmean � C sinð2pðFxþ /ÞÞ� expð�ðx2 þ y2Þ=r2ÞÞ; ð1Þ
where Lmean is the mean luminance of the background,
rand is a uniformly distributed random variable between
0 and 1, C is the contrast of the modulation, F is the spa-
A
B
Fig. 1. Examples of our stimuli: horizontal target with (A) collinear
flanks and (B) orthogonal flanks, separated (center-to-center) by 4k(where k (wavelength) = r, the standard deviation of the Gaussian
window). Target and flanks are sinusoidal modulations (1.0 or
2.0 c/deg) of the background contrast (static, random noise).
tial frequency of the modulation, / is the spatial phase,
r is the standard deviation of the Gaussian envelope,
and x and y are the respective horizontal and vertical
distances from the peak of the Gaussian envelope.
Eachpixel subtended 0.93 min of arc at amean viewing
distance of 1.4 m and noise patches were 4 · 4 square pix-els. The luminance increment or decrement of each noise
patch was taken randomly from a uniform distribution.
The mean contrast of the noise background was 50%.
The contrast of each noise patch depended on the value
of the convolving sinusoid at that position. The stimulus
area (768 · 256 pixels) was centered within the screen
and contained a horizontal target and flanks (collinear or
orthogonal pair) of equal spatial frequency (1.0 or2.0 c/deg). The standard deviation (r) of the 2-D Gabor
for all stimuli was 1k (where k = 1 carrier cycle). This pro-
duced targets and flanks of equal bandwidth, spatial
isolation at the smallest separation (4k), and decreasing
center-to-center separationas spatial frequency increased.
Flankswere equidistant from the target andwe tested sep-
arations (center-to-center) of 4, 5, 6, and 8k. Separationsfrom1k to 3kwerenot tested to avoidoverlapbetween tar-get and flanks. Three sets of stimuli were created and used
randomly during the experiment to offset any luminance
artifacts produced from the clumping of random static
noise.
2.4. Experiment
We used a lateral masking design (Polat & Sagi, 1993)and incorporated normalization of flank contrast
A
B
C
E.H. Wong et al. / Vision Research 45 (2005) 2810–2819 2813
between all observers. We measured second-order con-
trast detection for (a) flanks, (b) horizontal target, and
(c) horizontal target in the presence of collinear (hori-
zontal) or orthogonal (vertical) flanks (at 2· and in some
cases 4· the contrast detection threshold measured in
(a)). For all measurements, the observer sat in a dark-ened room, head positioned on a chin rest, non-tested
eye occluded with a black patch, and fixating the center
of the screen. We tested each eye of the non-control
observers, and the dominant eye of the control
observers.
For measurement (a) we used a method of limits par-
adigm consisting of a self-paced, 7-step staircase (con-
trast changes in .075 log steps). Stimulus duration was500 ms and the inter-stimulus interval (500 ms) con-
tained an un-modulated random noise field of the same
size and average Michaelson contrast (50%) as that con-
tained in the stimulus intervals. Each run contained 25
trials, and threshold was calculated from pooling at least
10 consecutive runs taken over 2 or more days.
For measurement (b) and (c) we used a self-paced,
temporal two-alternative forced-choice paradigm withthe method of constant stimuli. Flanks were presented
in each of two 500-ms stimulus intervals, separated by
a 500-ms interval as in measurement (a), and, respective-
ly, signaled by simultaneous single or dual tones. The
subject�s task was to detect the target presented random-
ly in one of the stimulus intervals. A keyboard press sig-
naled the response and no feedback was given. Each
trial contained the target at one of seven contrast levels(in .075 log steps), chosen to span the psychometric
function, and presented in random order. Each run con-
sisted of 145 trials, with the first 5 being discarded to al-
low for task adaptation, and tested one combination of
spatial frequency and flank to target separation. We col-
lected at least 5 consecutive runs over 3 or more days
and calculated contrast detection threshold (75% correct
response) by Weibull function fit to the data.We note that in pilot studies amblyopic observers
were unable to perform the experimental task adequate-
ly when stimuli were presented for 200 ms. We therefore
used 500 ms stimulus presentations in all experimental
measures.
Fig. 2. Normal observers show facilitation of contrast detection by
flanks. Contrast of the collinear flanks (column 1) and orthogonal
flanks (column 2) is in multiples of their respective contrast detection
threshold: (A) 2· threshold and (B) 4· threshold. Spatial frequency is
1 c/deg. Lines connect the weighted average at each separation and
error bars represent ± SEM. The weighted averages of (A) and (B) are
shown in (C).
3. Results
All observers viewed second-order stimuli consisting
of 1 c/deg (modulation frequency), non-overlapping tar-
get and flanks (center-to-center separations of 4, 5, 6,
and 8k) (where k (wavelength) = r, the standard devia-
tion of the Gaussian window) (Fig. 1). We calculated a
threshold modulation ratio: (contrast detection thresh-
old with flanks)/(contrast detection threshold withoutflanks), for the dominant eye of normal observers,
amblyopic eye (AE) and fellow non-amblyopic eye
(NAE) of amblyopic observers, and the right eye (RE)
and left eye (LE) of non-amblyopic observers with stra-
bismus. Threshold modulation ratios greater than 1
indicate suppressive interactions, whilst ratios less than
1 indicate facilitative interactions. We plot threshold
modulation ratio as a function of target to flankseparation.
We found that normal eyes showed facilitation in the
presence of both collinear and orthogonal flanks at 4, 5,
and 6k separation with a reduced effect at 8k (Fig. 2).
Note that the target–flank separation is specified in both
degrees and wavelengths (k)—which are identical at a
stimulus spatial frequency of 1 c/deg. The amount of
facilitation was essentially equal for flanks of 2· or 4·their flank contrast detection threshold (flank detection
data not shown). Therefore, facilitative interactions in
normal observers appear to be independent of flank ori-
entation and contrast for second-order stimuli. At 2·flank contrast detection threshold, the mean facilitation
at 4k (the separation producing the greatest effect) was
13% ± 4% for collinear flanks and 11% ± 4% for orthog-
onal flanks. We subsequently tested all non-controlobservers at 4k separation, and most observers at 5, 6,
2814 E.H. Wong et al. / Vision Research 45 (2005) 2810–2819
and 8k separations, with flanks set at twice the flank
contrast detection threshold.
Inmarked contrast to normal observers, we found that
flanks suppressed target detection thresholds in each eye
of the majority of non-control observers. Fig. 3 presents
data from each eye of all non-control observers, testedat 4k separation. Collinear flanks produced suppression
in both eyes of five amblyopic observers, and in 3 of 4 eyes
of strabismic, non-amblyopic observers WS and RC
(non-dominant eye shown as AE and dominant eye as
NAE) (Fig. 3A). Amongst amblyopes, observer DS
showed the largest amount of suppression (38% ± 12%).
All amblyopic observers generally showed very similar
amounts of suppression in each eye.Orthogonal flanks at a separation of 4k produced
suppression in all amblyopic and non-dominant eyes
(Fig. 3B). For each of these eyes the amount of suppres-
sion was very similar to that produced by collinear
flanks (Fig. 3A). In contrast, orthogonal flanks pro-
duced suppression in only 3 of 6 non-amblyopic eyes
(DS, JF, and AM) and 1 of 2 dominant eyes (RC)
(Fig. 3B). Interestingly, the non-amblyopic eye ofobserver RH showed the largest amount of suppression
for orthogonal flanks (39% ± 10%), which was very sim-
ilar to the largest amount produced by collinear flanks
(36% ± 12%, amblyopic eye of observer DS).
Fig. 3. Collinear (A) and orthogonal (B) flanks produce suppression of
contrast detection in each eye of most non-control observers. Data are
for 1 c/deg stimuli at 4k separation (i.e., the condition of maximum
flank effect) and error bars represent ± SEM. Suppression is shown by
most amblyopic eyes (filled symbols) and fellow preferred eyes (open
symbols). The facilitation by normal observers (weighted average) is
shown by the solid line. For observers RC and WS (both strabismic
without loss of visual acuity), their non-dominant eye is represented as
AE and the dominant eye as NAE.
Overall, our findings indicate that target detection
thresholds are clearly influenced by neural activity asso-
ciated with both collinear and orthogonal flanks. In
visually normal observers, the presence of these flanking
stimuli enhance detection, whilst in non-control observ-
ers they impair detection, in most cases regardless ofthe eye investigated. This strongly suggests that the
mechanism that mediates facilitation, or suppression in
the case of non-control observers, has a cortical locus
at or beyond the site of binocular combination. In sup-
port, the amblyopic observers who showed the least
amount of suppression (Fig. 3—JF and AM) were not
strabismic and amblyope AM had demonstrated some
residual binocular function in the form of gross stereop-sis (32000).
The amount of suppression shown by non-control
observers decreased as the separation between target
and flank increased, and dissipated almost entirely at a
separation of 8k (Fig. 4). This is demonstrated by data
from four amblyopic observers who showed suppression
by both collinear and orthogonal flanks. Taken together
with the results from normal observers (Fig. 2), it islikely that a separation of 8k reflects the spatial limits
of the inhibitory surround on the CRF (see Section 4).
The non-control observers had higher contrast detec-
tion threshold for flanks (data not shown) which limited
the contrast level at which flanks could be presented at
twice their respective detection threshold—the exception
being amblyope DS. Whilst the normal observers
showed similar interactions for different levels of flankcontrast, when tested with flanks at 4· detection thresh-
old the amblyopic eye of DS showed reduced suppres-
sion for both collinear (0% ± 9% vs 38% ± 12%) and
orthogonal flank conditions (10% ± 10% vs 36% ±
12%) (Fig. 4). The reduction in target suppression may
reflect the unmasking of excitatory connections by high-
er levels of flank contrast (see Section 4).
For our sample of non-control observers, we foundno association between flank-induced suppression and
absolute second-order sensitivity (isolated target detec-
tion threshold in the absence of flanks, relative to nor-
mal observers). This was the case for amblyopic (or
non-dominant) eyes (Fig. 5A) and fellow non-amblyopic
(or dominant) eyes (Fig. 5B). These results also demon-
strate that flank-induced suppression is not associated
with visual acuity (Tables 1A and B).In control experiments we found that flank-induced
suppression in non-control observers was relatively im-
mune to changes in scale and size (Fig. 6). Amblyopic
observers showed flank-induced suppression for 2 c/deg
stimuli at similar target to flank separations (4k and
5k) as the 1 c/deg stimuli. The overlap of the 2 c/deg data
(representing 2 and 2.5� separations) and 1 c/deg data
(representing 4 and 5� separations) suggests that the sup-pressive effects are invariant to spatial frequency (scale)
and size. Physiologically, this suggests the presence of
A
B
Fig. 4. Suppression by collinear and orthogonal flanks occurs at 4k–6k separations. Amblyopic eye (A) and preferred eye (B) data from four
amblyopic observers. Data are for 1 c/deg stimuli at 4k–8k separations and error bars represent ± SEM. Only amblyopic observer DS could be tested
with flank contrast at 4· flank contrast detection threshold. The gray line represents the facilitation shown by control eyes (weighted average).
E.H. Wong et al. / Vision Research 45 (2005) 2810–2819 2815
different size CRF-surround mechanisms in V2, operat-
ing over a large range of cortical distances.
4. Discussion
We report novel visual deficits in amblyopic observ-ers, and strabismic observers with no loss of visual acu-
ity, which result from anomalous interactions between
spatially isolated, second-order visual stimuli. Specifical-
ly, under conditions where normal (control) observers
show enhanced visual performance, non-control observ-
ers show a very different pattern of spatial interaction: in
virtually every case, visual sensitivity is compromised by
the presence of nearby stimuli. Taken together, the
results of this study, when considered in light of known
physiology of second-order processing, represent an
amblyopic deficit at an early stage of extra-striate visual
processing (V2).
Almost all amblyopic observers showed suppressionin each eye, both amblyopic and preferred, often of al-
most equal magnitude. Furthermore, strabismic observ-
ers RC and WS showed suppression in both eyes (Fig.
3), without any loss of visual acuity or second-order sen-
sitivity in either eye (Fig. 5 and Table 1B). Our finding
of bilateral second-order deficits should perhaps have
A
B
Fig. 5. Flank effect is not associated with absolute second-order
contrast sensitivity. Data are from (A) amblyopic eyes (AE) and (B)
fellow non-amblyopic eyes (NAE). For each eye, threshold modulation
ratio for collinear flanks (filled symbols) and orthogonal flanks (open
symbols) is plotted against relative sensitivity for the isolated target.
Relative sensitivity = (contrast detection threshold)/(average contrast
detection threshold for five normal observers). For observers RC and
WS (both strabismic without loss of visual acuity), their non-dominant
eye is represented as AE and the dominant eye as NAE.
Fig. 6. Suppressive flank effect is size and scale invariant. Data are
from two amblyopic observers. Stimuli are 1 c/deg (filled symbols) and
2 c/deg (open symbols) and error bars represent ± SEM.
2816 E.H. Wong et al. / Vision Research 45 (2005) 2810–2819
been expected, given the predominantly binocular nat-
ure of V2 neurons (Hubel & Livingstone, 1987).In normal observers, collinear and orthogonal flanks
facilitated second-order contrast detection thresholds by
approximately 12% (Fig. 2). This value is somewhat
lower than that found for first-order stimuli (up to
50%) (Levi et al., 2002; Polat & Sagi, 1993; Yu et al.,
2002). A similar relationship has been shown for con-
trast discrimination: the reduction of apparent (supra-
threshold) contrast by flanking stimuli is significantlyless for second-order cues than for first-order cues
(Ellemberg, Allen, & Hess, 2004). Previous studies
examining the degree and nature of flank-induced facil-
itation for first-order visual stimuli present a somewhat
contradictory picture. Some studies suggest that facilita-
tion is orientation dependent (and is greatest for collin-
ear flanks and targets) (Polat & Sagi, 1993), whilst
others posit orientation independent mechanisms (Leviet al., 2002; Yu et al., 2002). The results of the present
study show qualitative agreement with the latter class
of first-order studies where the magnitude of facilitation
is unrelated to the internal image structure of isolated
patches. Therefore, facilitation of contrast detection
thresholds, by both first-order and second-order flank-
ing stimuli, appears to involve a process that pools
information across a broad range of oriented filters.Physiologically, this suggests that horizontal connec-
tions exist between neurons with a range of different ori-
entation preferences, rather than being restricted to
connecting common orientations. Our results suggest
orientation independence: both collinear and orthogo-
nal flanks produced nearly equal facilitation in control
eyes (Fig. 2), and nearly equal suppression in the major-
E.H. Wong et al. / Vision Research 45 (2005) 2810–2819 2817
ity of amblyopic eyes as well as the fellow preferred eyes
(Fig. 3). Furthermore, Ellemberg et al. (2004) reported
that in normal observers, flank orientation effects on
contrast discrimination were more broadly tuned for
second-order stimuli than for first-order stimuli. For
the large flank to target separations used in this study,we hypothesize that our results indicate a CRF-sur-
round mechanism in which the surround input to the
CRF is broadly tuned to orientation.
We used spatially isolated stimuli and thus did not
measure the previously reported suppression effects pro-
duced at small target–flank separations (1k–2k) when
using first-order stimuli (Polat & Sagi, 1994). Suppression
results from the overlap of supra-threshold flanks thateffectively transform the task from one of contrast detec-
tion, to contrast discrimination. The latter task produces
contrast increment thresholds that are greater (poorer)
than the corresponding contrast detection thresholdmea-
sured at wider flank–target separations. Our finding that
spatially isolated stimuli up to 4�–6� produced suppres-
sion in non-control observers and facilitation in normal
observers possibly suggests unequal CRF sizes betweenthe two groups. However, we have recently conducted a
spatial summation experiment using identical stimuli
(Wong & Levi, in press) and found that amblyopic and
normal observers show similar performance, i.e., a simi-
lar improvement in contrast detection threshold as target
size increases (up to 8� at 4r). This suggests that the spa-tial extent of the CRF is similar in non-control and nor-
mal observers. In total, it is more probable that thefindings in the present study reflect the influence of the
flanking stimuli on the balance between the CRF-sur-
round gains, rather than an elaborate recruitment of hor-
izontal connections over large cortical distances (but see
Stettler et al., 2002). Furthermore, the inhibitory sur-
round in non-control observers appears to exert a greater
influence than that seen in normal observers.
Through psychophysical measures we can only infer,based on contemporary neurophysiology (see Section 1)
that the amblyopic deficits found in this study reflect
neural deficits in V2. An alternative or contributory
mechanism could be deficient reentrant connections to
V2 from higher-order visual areas; connections analo-
gous to those found to V1 (for a review see, Angelucci
& Bullier, 2003). A feedback mechanism is especially rel-
evant to this study in light of evidence that second-ordercues stimulate neurons in primate MT (O�Keefe &
Movshon, 1998) and multiple extra-striate areas in hu-
mans via fMRI (Mendola, Dale, Fischl, Liu, & Tootell,
1999; Smith, Greenlee, Singh, Kraemer, & Hennig,
1998; but see Nishida, Sasaki, Murakami, Watanabe,
& Tootell, 2003). Furthermore, greater influence from
feedback mechanisms may have occurred due to our
use of 500 ms stimulus presentations.Another possible explanation for our results is that
the imbalance between excitation and inhibition reflects
an imbalance in the excitatory and inhibitory inputs to
second-order neurons from first-order (V1) neurons
(Morgan & Baldassi, 1997). However, we note that
our amblyopic observers show these abnormalities at
low spatial frequencies (1 and 2 c/deg) where amblyopic
observers show normal facilitation with first-order stim-uli of similar spatial frequency (Polat et al., 2004, 2005).
Moreover, our use of static, random noise as the carrier
in the second-order stimuli greatly reduced the likeli-
hood that side-band spatial frequencies (first-order
structures produced by the modulation of the carrier)
contributed to the interactions between the second-order
stimuli. That is, prominent side-bands could elicit first-
order spatial interactions (abnormal in amblyopicobservers) that could then be passed forward to the sec-
ond-order mechanism (i.e., filter-rectify-filter model).
However, past studies show that side-bands, and their
adjacent spatial frequencies, are more likely to be signif-
icant in second-order stimuli that contain a grating car-
rier of high contrast rather than a noise carrier (of any
contrast) (Dakin & Mareschal, 2000; Jamar, Campagne,
& Koenderink, 1982).Our hypothesis, of altered CRF-surround gain mech-
anisms in second-order neurons, predicts that in normal
observers, flanks disinhibit the (tonic) surround suppres-
sion. Disinhibition is plausible because the flanks were
present in each trial (500 ms each) of the two-alternative
design, thereby acting as an almost constant mask. In
this situation, the contrast detection threshold reflects
the state of contrast adaptation of the inhibitory sur-round. A reduction in inhibition produces an increase
in the CRF gain and a net facilitation of visual sensitiv-
ity. Psychophysically, the increase in CRF gain is dem-
onstrated by an improvement in contrast detection
threshold. In the first-order domain, improved contrast
sensitivity following adaptation to flanks has been
shown by Ejima and Takahashi (1985). We speculate
that an analogous mechanism could occur for second-order stimuli.
Our hypothesis also predicts that for non-control
observers that showed suppression, the flanks did not
completely disinhibit the (dominant) surround. The net
effect of surround stimulation on the CRF would be
inhibition, or less excitation, relative to normal observ-
ers. Psychophysically, the inhibition of the CRF is dem-
onstrated by an increase (deterioration) in contrastdetection threshold. This finding appears to be specific
to second-order stimuli in light of evidence that first-
order stimuli of low spatial frequency, like that used in
our study, produce nearly equal amounts of flank-in-
duced facilitation in amblyopic and normal observers
(Polat et al., 2004, 2005). A stronger inhibitory surround
could represent a shift in the balance of horizontal excit-
atory and inhibitory connection strength betweensecond-order neurons, i.e., a functional increase in inhi-
bition between second-order neurons.
2818 E.H. Wong et al. / Vision Research 45 (2005) 2810–2819
Exactly this type of inhibition-dominated network is
supported by the results of amblyope DS who showed
substantially less suppression in both eyes when flank
contrast was doubled (the other amblyopic observers
could not be tested at four times flank detection con-
trast). The visual performance of normal observers, onthe other hand, remained unchanged under identical
conditions (Figs. 2 and 4). The reduced suppression ef-
fect shown by amblyope DS could be explained by the
mechanism of short-term plasticity—in this case further
disinhibition resulting in an unmasking of subthreshold
excitatory connections to supra-threshold activity. The
limited contrast range for second-order flanks prevented
other amblyopic observers from being tested at 4· detec-tion contrast. The presentation of stimuli for greater
than 500 ms may have also produced further disinhibi-
tion, i.e., greater contrast adaptation of the inhibitory
surround; however, we did not test this condition.
Although the horizontal connections and CRF-sur-
round mechanism in V2 are largely unexplored, an inhi-
bition-dominated network in amblyopia appears likely
based on evidence from V1. Synaptic weighting has itsbasis in the reciprocal connections between columns of
similar orientation in striate cortex (Weliky, Kandler,
Fitzpatrick, & Katz, 1995) and the balance of neural in-
put (push-pull arrangement) is modeled to determine the
contrast gain of single neurons (Carandini, Heeger, &
Movshon, 1997). In strabismus, anomalous horizontal
connections are found following abnormal visual experi-
ence during development in cat (Lowell & Singer, 1992)and monkey (Tyschen & Burkhalter, 1995), and may ex-
plain the less robust synchronization between neurons
responsive to the amblyopic eye in cat (Roelfsema,
Konig, Engel, Sireteanu, & Singer, 1994). Moreover,
inhibition dominated horizontal connections between
both ocular dominance columns and orientation col-
umns are thought to underlie the interocular suppres-
sion seen in strabismus (Sengpiel & Blakemore, 1996).These evidences lead us to speculate the existence of
analogous mechanisms in V2.
In summary, we found that spatially isolated, second-
order stimuli produced facilitatory interactions in nor-
mal observers but suppressive interactions in each eye
of amblyopic observers and strabismic observers with
no loss of visual acuity. Based on contemporary neuro-
physiology, our results suggest an early, higher-orderprocessing deficit in amblyopia. We further speculate
that early abnormal visual experience may result in pre-
dominantly inhibitory cortical networks.
Acknowledgments
Portions of the results of this study were presented inabstract form at the 2001 Association for Research in Vi-
sion and Ophthalmology Meeting. This study was sup-
ported by NIH NEI grants K23EY14261 (E.H.W.) and
RO1EY01728 (D.M.L.), and a Wellcome Trust (UK)
Research Career Development Fellowship to P.V.M.
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