Brachiocephalic Muscular Arrangements in Cavioid Rodents 7 (Caviomorpha): a Functional, Anatomical, and Evolutionary Study

C. GARCÍA ESPONDA, R. CANALOCE, A. CANDELA

JOURNAL OF MAMMALIAN EVOLUTION

SPRINGER

Lugar: Berlin; Año: 2020

1064-7554

In cursorial mammals, reduction or loss of the clavicle is usually associated with the constitution of the m. brachiocephalicus, a14 continuous muscle that extends from head and neck regions to the forelimb, protracting it during locomotion. Among15 caviomorph rodents, the Cavioidea are characterized by many adaptations that improve running performance, such as the16 presence of a brachiocephalic configuration of the mm. cleidomastoideus, cleido-occipitalis, and deltoideus pars clavicularis, a17 feature that was interpreted as one of the main modifications for speed in running. However, a comprehensive analysis of this18 muscular configuration in the Cavioidea is not yet available. In this study, we analyze the morphological diversity, homologies,19 functions, and evolutionary changes of those shoulder muscles in cavioids that constitute the m. brachiocephalicus in cursorial20 mammals. We hypothesize that a brachiocephalic muscular arrangement of these muscles has evolved in this group in relation to21 a swift mode of locomotion. Muscular dissections on seven species of cavioids were performed while myological data on three22 other species were taken from the literature. Our results indicate that all cavioids have a brachiocephalic arrangement of the mm.23 cleidomastoideus, cleido-occipitalis, and deltoideus pars clavicularis, whereas a second brachiocephalic arrangement constituted24 by the mm. omotransversarius and trapezius pars cervicalis is present only in the larger cavioids. Both muscular configurations25 act in protracting the forelimb during the gait, but we also hypothesize that the particular disposition of the m. omotransversarius26 around the shoulder joint of larger cavioids could also assist in the stabilization of this joint during fast half-bounding locomotion