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Early motor activity drives spindle bursts in the developing somatosensory cortex

Rustem Khazipov, Anton Sirota, Xavier Leinekugel, Gregory L. Holmes, Yehezkel Ben-Ari and György Buzsáki ()
Additional contact information
Rustem Khazipov: INMED, INSERM U29
Anton Sirota: CMBN, Rutgers University
Xavier Leinekugel: INMED, INSERM U29
Gregory L. Holmes: Dartmouth Medical School
Yehezkel Ben-Ari: INMED, INSERM U29
György Buzsáki: CMBN, Rutgers University

Nature, 2004, vol. 432, issue 7018, 758-761

Abstract: Abstract Sensorimotor coordination emerges early in development. The maturation period is characterized by the establishment of somatotopic cortical maps1,2, the emergence of long-range cortical connections3, heightened experience-dependent plasticity4,5,6,7 and spontaneous uncoordinated skeletal movement8,9. How these various processes cooperate to allow the somatosensory system to form a three-dimensional representation of the body is not known. In the visual system, interactions between spontaneous network patterns and afferent activity have been suggested to be vital for normal development10,11. Although several intrinsic cortical patterns of correlated neuronal activity have been described in developing somatosensory cortex in vitro12,13,14, the in vivo patterns in the critical developmental period and the influence of physiological sensory inputs on these patterns remain unknown. We report here that in the intact somatosensory cortex of the newborn rat in vivo, spatially confined spindle bursts represent the first and only organized network pattern. The localized spindles are selectively triggered in a somatotopic manner by spontaneous muscle twitches8,9, motor patterns analogous to human fetal movements15,16. We suggest that the interaction between movement-triggered sensory feedback signals and self-organized spindle oscillations shapes the formation of cortical connections required for sensorimotor coordination.

Date: 2004
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DOI: 10.1038/nature03132

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