4
THE PRIMARY VISUAL
CORTEX
After Kuffler's first paper on center-surround retinal ganglion cells
was pub-
lished in 1952, the next steps were clear. To account for the properties
of the
cells, more work was needed at the retinal level. But we also needed
to record
from the next stages in the visual pathway, to find out how the brain
inter-
preted the information from the eyes. Both projects faced formidable
difficul-
ties. In the case of the brain, some years were required to develop
the tech-
niques necessary to record from a single cell and observe its activity
for many
hours. It was even harder to learn how to influence that activity by
visual
stimulation.
TOPOGRAPHIC
REPRESENTATION
Even before further research became possible, we were not com-
pletely ignorant about the parts of the brain involved in vision: the
geography
of the preliminary stages was already well mapped out (see the illustration
on
the next page). We knew that the optic-nerve fibers make synapses with
cells
in the lateral geniculate body and that the axons of lateral geniculate
cells
terminate in the primary visual cortex. It was also clear that these
connections,
from the eyes to the lateral geniculates and from the geniculates to
the cortex,
are topographically organized. By topographic representation, we mean
that the mapping of each structure to the next is systematic: as you
move along the
retina from one point to another, the corresponding points in the lateral
genic-
ulate body or cortex trace a continuous path. For example, the optic
nerve
fibers from a given small part of the retina all go to a particular
small part of
the lateral geniculate, and fibers from a given region of the gcniculate
all go to
a particular region of the primary visual cortex. Such an organization
is not
surprising if we recall the caricature of the nervous system shown in
the figure
on page 6, in which cells are grouped in platelike
arrays, with the plates
stacked so that a cell at any particular stage gets its input from an
aggregate of
cells in the immediately preceding stage.
In the retina, the successive stages are in apposition, like playing
cards
stacked one on top of the other, so that the fibers can take a very
direct route
from one stage to the next. In the lateral geniculate body, the cells
are obvi-
ously separated from the retina, just as, equally obviously, the cortex
is in a
different place from the geniculate. The style of connectivity nevertheless
re-
mains the same, with one region projecting to the next as though the
succes-
sive plates were still superimposed.
The optic-nerve fibers simply gather into a bundle as they leave the
eye, and
when they reach the geniculate, they fan out and end in a topographically
orderly way. (Oddly, between the retina and geniculate, in the optic
nerve,
they become almost completely scrambled, but they sort out again as
they
reach the geniculate.) Fibers leaving the geniculate similarly fan out
into a
broad band that extends back through the interior of the brain and ends
in an
equally orderly way in the primary visual cortex. After several synapses,
when
fibers leave the primary visual cortex and project to several other
cortical re-
gions, the topographic order is again preserved. Because convergence
occurs
at every stage, receptive fields tend to become larger: the farther
along the path
we go, the more fuzzy this representation-by-mapping of the outside
world
becomes.
An important, long-recognized piece of evidence that the pathway is
topo-
graphically organized comes from clinical observation. If you damage
a certain
part of your primary visual cortex, you develop a local blindness, as
though
you had destroyed the corresponding part of your retina.
The visual world is thus systematically mapped onto the geniculate and
cortex. What was not at all clear in the 1950s was what the mapping
might
mean. In those days it was not obvious that the brain operates on the
informa-
tion it receives, transforming it in such a way as to make it more useful.
People
had the feeling that the visual scene had made it to the brain; now
the problem
for the brain was to make sense of it—or perhaps it was not the
brain's prob-
lem, but the mind's. The message of the next chapters will be that a
structure
such as the primary visual cortex does exert profound transformations
on the
information it receives. We still know very little about what goes on
beyond
this stage, and in that sense you might argue that we are not much better
off.
But knowing that one part of the cortex works in a rational, easily
understood
way gives grounds for optimism that other areas will too. Some day we
may
not need the word mind at all.
the Golgi method, shows a few pyramidal
cells—a tiny fraction of the total number in
such a section. The entire height of the
photograph represents about 1 millimeter.
A tungsten microelectrode, typical of what
is used for extracellular recordings, has
been superimposed, to the same scale.
eyes to primary visual cortex, of a human
brain, as seen from below. Information
comes to the two purple-colored halves of
the retinas (the right halves, because the
brain is seen upside down) from the oppo-
site half of the environment (the left visual
field) and ends up in the right (purple) half
of the brain. This happens because about
half the optic-nerve fibers cross at the
chiasm, and the rest stay uncrossed. Hence
the rules: each hemisphere gets input from
both eyes; a given hemisphere gets infor-
mation from the opposite half of the visual
world.