Neuronal control of bird song production

Bird song represents a powerful model system for many of the important problems in behavioral neurobiology, offering both easily measured sensory and motor patterns and a discrete neural effector system. Methods were developed to record the discharge of neurons in singing birds to examine the functions of nuclei in the song control pathway previously implicated anatomically. In several cases, lesions and other techniques were employed to test predictions derived from electrode recordings. Four major findings emerge from these studies. Single-unit recordings from telencephalic nucleus hyperstriatum ventrale, pars caudale (HVc) show several classes of neurons with apparently specialized roles in song production and/or sensorimotor interaction. The nucleus interfacialis (Nlf; Nottebohm, 1980), which provides an input to HVc and is anatomically the “highest” nucleus in the descending motor pathway, is uniquely placed among vocal control nuclei to be a generator of timing cues for song. Consistent with the unidirectional connections between nuclei of the descending pathway, Nlf, HVc, and nucleus robustus archistriatalis (RA) are activated sequentially prior to sound onset. Three other nuclei with connections to or from the descending tract do not show song-related activity in the adult. Bilateral HVc recordings and peripheral disruptions of the vocal apparatus suggest that both hemispheres and syringeal halves normally make similar contributions to most if not all song syllables. The latter finding casts doubt on the analogy between neural lateralization in bird song and in human speech.

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