Topographic Maps

Macaque Retinotopy

Source: Tootell et al., 1982

EXPANDINGRINGS

Retintopy: Flickering Checkerboard

•8 Hz flicker (checks reverse contrast 8X/sec)•good stimulus for driving visual areas•subjects must maintain fixation (on red dot)

ROTATINGWEDGES

Source: Jody Culham

Source: Jody Culham

time = 0

time = 20 sec

time = 60 sec

time = 40 sec

0 20 40 60

TIME

STIMULUSEXPECTED RESPONSE PROFILE OF AREA

RESPONDING TO STIMULUSTo analyze retinotopic data:

Analyze the data with a set of functions with the same profile but different phase offsets.

For any voxels that show a significant response to any of the functions, color code the activation by the phase offset that yielded maximum activation (e.g., maximum response to foveal stimulus = red, maximum response to peripheral stimulus = green)

Retintopy: Eccentricity

calcarinesulcus

left occipitallobe

right occipitallobe

•foveal area represented at occipital pole•peripheral regions represented more anteriorly

Source: Jody Culham

Retintopy on Flattened Occipital Lobe

2) cut along calcarinesulcus

left occipitallobe

Source: Jody Culham

3) unfold and flatten the cortical surface

uppe

r ca

lcar

ine

sulc

uslo

wer

cal

carin

e su

lcus

lateral surface (note: retinotopic areas do extend onto the lateral surface but are not shown here in this schematic)

1) virtually cut off the occipital lobe (remember, it’s a cup shape and the lateral surface is on the side we can’t see from this viewpoint)

occipitalpole

occipitalpole

Retintopy: Eccentricity Movie

occipital pole

calcarine sulcus

Movie: eccentricity.mpeghttp://cogsci.ucsd.edu/~sereno/phasemovie2.mpg

Source: Marty Sereno’s web page

Retintopy in V1: Polar Angle

calcarinesulcus

left occipitallobe

right occipitallobe

•left-right hemifields reverse (left field to right hemisphere)•upper-lower hemifields reverse (upper field to below calcarine)•horizontal meridian lies ~along calcarine (not always exactly)

HM

VM

VM

vertical meridian (VM)

horiz

onta

l mer

idia

n (H

M)

HM

VM

VM

Source: Jody Culham

Polar Angle and Eccentricity in V1

calcarinesulcus

left occipitallobe

right occipitallobe

•retinotopic areas are like polar coordinates: eccentricity and polar angle

Source: Jody Culham

Polar Angle in V1, V2 and beyond

left occipitallobe

•V2 is mirror image map of V1•V1-V2 border occurs at vertical meridian•V2-V3 border occurs at horizontal meridian•situation gets more complex in higher-tier areas (V4v, V3A) that have representations of whole hemifield

HM

VM

VM

vertical meridian (VM)

horiz

onta

l mer

idia

n (H

M)

} V1 lower

HM

} V2 lower

VM

} VP

} V1 upperHM

} V2 upperVM

} V3

calcarinesulcus

Source: Jody Culham

Retinotopy

Source: Sereno et al., 1995

Retinotopy: Polar Angle Movie

occipital pole

calcarine sulcus

Movie: phase.mpeghttp://zakros.ucsd.edu/~sereno/movies/phasemovie1b.mpg

Source: Marty Sereno’s web page

Getting Better Retinotopy

•use stimuli appropriate to the area (e.g., motion in MT, color in V4v)•use stimuli that are attentionally engaging•Marty Sereno: Buffy-o-topy

•UWO: chicken-o-topy

Other Sensory “-topies”

Touch: Somatotopy

Servos et al., 1998red = wrist; orange = shoulder

Audition: Tonotopy

cochlea

Sylvian fissure

temporal lobe

Movie: tonotopy.mpeghttp://cogsci.ucsd.edu/~sereno/downsweep2.mpg

Source: Marty Sereno’s web page

Face/Place-o-topy

Source: Levy et al., 2001

•faces activate foveal area (more for foveal than peripheral faces)

•places activate peripheral area (more for peripheral than foveal places)

Saccadotopy

Source: Sereno et al., 2001

•delayed saccades

•move saccadic target systematically around the clock

http://kamares.ucsd.edu/~sereno/LIP/both-closeup+stim.mpgMarty Sereno’s web page

Sulcal Formation

Source: Van Essen, 1997

Although sulci vary considerably from person to person (even in identical twins), there is considerable regularity in where the folds occur… Why?

David Van Essen proposes that as the brain develops, areas that are richly interconnected will be pulled together to form a gyrus (and those that are weakly interconnected form sulci).

Development of Sulci

Source: Ono, 1990

Sulci appear at predictable points in fetal development with the most prominent sulci (e.g., Sylvian fissure) appearing first.

Sulcal Formation: V1-V2

Source: Van Essen, 1997

The V1/V2 border provides one example of two richly interconnected areas that form a gyrus.

This arrangement also explains why maps in V1 and V2 are mirror images of each other!

calcarinesulcus

Comparative Neuroanatomy

Source: Comparative Mammalian Brain Collection

The complexity of sulci increased throughout evolution

Interspecies Comparisons

Figure H shows the macaque monkey visual areas morphed onto human cortex based on the placement of sulcal landmarks (Van Essen et al., 2001)

Can we assume humans are just morphed monkeys?

In some areas the human cortical surface area is slightly larger than in the macaque (e.g., visual cortex: 2X); in others it is considerably larger (e.g., parietal cortex: 20X)

Are individual areas larger? Are there more areas?