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Hahnloser, R.H.R. and Kozhevnikov, A. and Fee, M.S. (2002).
An ultrasparse code underlies the generation of neural sequences in songbirds.
Nature, 419: 65--70 (pdf).
Abstract
Sequences of motor activity are encoded in many vertebrate brains by complex
spatio-temporal patterns of neural activity; however, the neural circuit
mechanisms underlying the generation of these pre-motor patterns are poorly
understood. In songbirds, one prominent site of pre-motor activity is the
forebrain robust nucleus of the archistriatum (RA), which generates stereotyped
sequences of spike bursts during song and recapitulates these sequences during
sleep. We show that the stereotyped sequences in RA are driven from nucleus
HVC (high vocal
centre), the principal pre-motor input to RA. Recordings of identified HVC
neurons in sleeping and singing birds show that individual HVC neurons projecting
onto RA neurons produce bursts sparsely, at a single, precise time during
the RA sequence. These HVC neurons burst sequentially with respect to one
another. We suggest that at each time in the RA sequence, the ensemble of
active RA neurons is driven by a subpopulation of RA-projecting HVC neurons
that is active only at that time. As a population, these HVC neurons may
form an explicit represen-
tation of time in the sequence. Such a sparse representation, a temporal
analogue of the `grandmother cell' concept for object recognition, eliminates
the problem of temporal interference during sequence generation and learning
attributed to more distributed representations.
See also News and Views:
Fernando Nottebohm: Birdsong's clockwork.
Nature Neuroscience 5 (10), 925-926, 2002. (pdf).
Abstract:
Recordings from song premotor circuits in singing birds show how a population
of neurons may form an explicit representation of time in a motor sequence.