Complex pitch perception mechanisms are shared by humans and a New World monkey

Significance Complex pitch perception serves a pivotal role in human audition, especially in speech and music perception. It has been suggested that pitch perception mechanisms demonstrated in humans are not shared by nonhuman species. Here we provide evidence that a New World monkey, the common marmoset, shares all primary features of complex pitch perception mechanisms with humans. Combined with previous findings of a specialized pitch processing region in both marmoset and human auditory cortex, this evidence suggests that pitch perception mechanisms likely originated early in primate evolution. The perception of the pitch of harmonic complex sounds is a crucial function of human audition, especially in music and speech processing. Whether the underlying mechanisms of pitch perception are unique to humans, however, is unknown. Based on estimates of frequency resolution at the level of the auditory periphery, psychoacoustic studies in humans have revealed several primary features of central pitch mechanisms. It has been shown that (i) pitch strength of a harmonic tone is dominated by resolved harmonics; (ii) pitch of resolved harmonics is sensitive to the quality of spectral harmonicity; and (iii) pitch of unresolved harmonics is sensitive to the salience of temporal envelope cues. Here we show, for a standard musical tuning fundamental frequency of 440 Hz, that the common marmoset (Callithrix jacchus), a New World monkey with a hearing range similar to that of humans, exhibits all of the primary features of central pitch mechanisms demonstrated in humans. Thus, marmosets and humans may share similar pitch perception mechanisms, suggesting that these mechanisms may have emerged early in primate evolution.

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