Georg von Békésy, in his book
Sensory Inhibition, explores a wide range of inhibitory phenomena in
sensory systems, and interprets them in terms of sharpening.
Visual inhibition Lateral inhibition increases the
contrast and sharpness in visual response. This phenomenon already occurs in the mammalian
retina. In the dark, a small light stimulus will enhance the different
photoreceptors (
rod cells). The rods in the center of the stimulus will
transduce the "light" signal to the brain, whereas different rods on the outside of the stimulus will send a "dark" signal to the brain due to lateral inhibition from
horizontal cells. This contrast between the light and dark creates a sharper image. (Compare
unsharp masking in digital processing). This mechanism also creates the
Mach band visual effect. Visual lateral inhibition is the process in which
photoreceptor cells aid the brain in perceiving contrast within an image. Electromagnetic light enters the eye by passing through the
cornea,
pupil, and the
lens (optics). It then bypasses the
ganglion cells,
amacrine cells,
bipolar cells, and
horizontal cells in order to reach the photoreceptors
rod cells which absorb light. The rods become stimulated by the energy from the light and release an excitatory neural signal to the horizontal cells. This excitatory signal, however, will only be transmitted by the
rod cells in the center of the ganglion cell receptive field to
ganglion cells because horizontal cells respond by sending an inhibitory signal to the neighboring rods to create a balance that allows mammals to perceive more vivid images. The central rod will send the light signals directly to
bipolar cells which in turn will relay the signal to the ganglion cells.
Amacrine cells also produce lateral inhibition to
bipolar cells and
ganglion cells to perform various visual computations including image sharpening. The final visual signals will be sent to the thalamus and
cerebral cortex, where additional lateral inhibition occurs.
Tactile inhibition Sensory information collected by the peripheral nervous system is transmitted to specific areas of the primary
somatosensory area in the
parietal cortex according to its origin on any given part of the body. For each neuron in the primary somatosensory area, there is a corresponding region of the skin that is stimulated or inhibited by that neuron. The regions that correspond to a location on the somatosensory cortex are mapped by a
homunculus. This corresponding region of the skin is referred to as the neuron's
receptive field. The most sensitive regions of the body have the greatest representation in any given cortical area, but they also have the smallest receptive fields. The lips, tongue, and fingers are examples of this phenomenon. When an area of the skin is touched, the central excitatory region activates and the peripheral region is inhibited, creating a contrast in sensation and allowing sensory precision. The person can then pinpoint exactly which part of the skin is being touched. In the face of inhibition, only the neurons that are most stimulated and least inhibited will fire, so the firing pattern tends to concentrate at stimulus peaks. This ability becomes less precise as stimulation moves from areas with small receptive fields to larger receptive fields, e.g. moving from the fingertips to the forearm to the upper arm. Lateral inhibition in
tonotopic channels can be found in the
inferior colliculus and at higher levels of auditory processing in the brain. However, the role that lateral inhibition plays in auditory sensation is unclear. Some scientists found that lateral inhibition could play a role in sharpening spatial input patterns and temporal changes in sensation, others propose it plays an important role in processing low or high tones. Lateral inhibition is also thought to play a role in suppressing
tinnitus. Tinnitus can occur when damage to the
cochlea creates a greater reduction of inhibition than excitation, allowing neurons to become aware of sound without sound actually reaching the ear. If certain sound frequencies that contribute to inhibition more than excitation are produced, tinnitus can be suppressed. The exact functions of these regions are unclear, but they do contribute to selective auditory processing responses. These processes could play a role in auditory functioning of other mammals, such as cats. ==Embryology==