Because neuronal tunings are diverse, and because neighboring neurons have more similar tuning than distant neurons, one might expect each stimulus to evoke a distinct spatial activity pattern, with more
similar stimuli evoking more similar patterns. In this picture, no pair of stimuli would produce an exactly identical population response, so the firing pattern of even a relatively small set of neurons Transmembrane Transproters modulator could in principle identify which of many stimuli was presented, limited only by the noise in neuronal responses. This is intuitively appealing, because it suggests the information coding capacity of the population is being used efficiently to represent a large number of potential stimuli. Bathellier et al.’s experiments suggest a different picture (Figure 1B). Using two-photon calcium imaging, they recorded the activity of up to 100 neurons in the superficial layers of auditory
cortex, while presenting a set of ∼60 brief acoustic stimuli including tones and segments of complex sounds. In contrast to the picture suggested in Figure 1A, selleck chemical the number of patterns the population actually produced was very limited. Many stimuli produced no reliable response at all; but when a response was evoked, it typically consisted of the same subset of cells, forming a stereotyped spatial pattern termed a “response mode.” In most recordings, only one response mode was seen whatever the stimulus; in a smaller number of recordings two or three modes were seen, with each mode evoked by a distinct set of stimuli. When more than one mode was seen they were spatially segregated, with centers- of mass typically more than 50 μm apart (the true separation is probably larger since the modes could extend beyond the imaging window), although
one neuron could participate in more than one response mode. The modes therefore appear to consist of partially overlapping assemblies of probably several hundred neurons, arranged in local clusters of size the order a hundred microns. The activation of a response mode was a discrete event. In recordings where multiple modes were observed, Bathellier et al. (2012) presented weighted superimpositions Acyl CoA dehydrogenase of two sounds, each driving one mode. The resulting firing pattern did not smoothly interpolate between the two response modes, but suddenly switched from one mode to the other, for a particular value of the weighting. This suggests a “winner-take-all” form of competition between response modes. Although this picture is different to what many scientists may have assumed about population codes, it is not inconsistent with previous studies. When the same data was analyzed with single-neuron methods, standard results such as V-shape tuning curves were seen. The fact that these tuning curves show a continuous variation of firing rate with tone frequency might seem to contradict the all-or-none activation of response modes.