Pattern of interhemispheric synchronization in HVc during singing correlates with key transitions in the song pattern

doi:10.1152/jn.00003.2003

Pattern of interhemispheric synchronization in HVc during singing correlates with key transitions in the song pattern

Marc F. Schmidt¹^*

¹ Biology, University of Pennsylvania, Philadelphia, PA, USA

^* To whom correspondence should be addressed. E-mail: marcschm{at}sas.upenn.edu.

Many complex voluntary behaviors require that motor commandsbe tightly coordinated between cerebral hemispheres. The neuralmechanisms underlying such coordination, however, remain poorlyunderstood. Song production in birds is a highly stereotypedlearned motor behavior that requires finely tuned coordinationbetween hemispheres. In the present study, neural activity wasrecorded simultaneously from the song control nucleus HVc ineach hemisphere of singing adult male zebra finches (Taeniopygiaguttata). In all cases, the pattern of recorded multi-unit activityin each hemisphere was highly correlated during short segmentsof the song motor pattern. These correlated segments often consistedof multiple short bursts of activity. Because of the absenceof interhemispheric connections between song control nuclei,these observations suggest that HVc activity is synchronizedby common inputs to both hemispheres. Using sliding window cross-covarianceanalyses, periods of high interhemispheric synchronization werefound to be time-locked to the acoustic onset of syllables andnotes. In some cases, precisely synchronized bursts in bothhemispheres were also observed during periods associated withthe inter-syllable silent interval. In all cases, activity wascorrelated between hemispheres independently of the recordingsite, suggesting that all regions of HVc may be globally synchronizedduring these short segments of the song. Given the anatomicalorganization of the song system, inputs originating from eitherthalamus or midbrain are proposed to act as timing signals thatinitiate and synchronize intrinsic motor networks within eachHVc thus allowing for the precise coordination of motor commandsacross hemispheres.

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