A biorobotic model of the suction feeding system in largemouth bass: the roles of motor program speed and hyoid kinematics

Abstract

The vast majority of ray-finned fishes capture prey through suction feeding. The basis of this behavior is generation of subambient pressure through rapid expansion of a highly kinetic skull. Over the last four decades, results from in-vivo experiments have elucidated the general relationships between morphological parameters and subambient pressure generation. Until now, however, researchers have been unable to tease apart the discrete contributions of, and complex relationships among, the musculoskeletal elements that support buccal expansion. Fortunately, over the last decade, biorobotic models have gained a foothold in comparative research and show great promise in addressing long-standing questions in vertebrate biomechanics. In this paper, we present BassBot, a biorobotic model of the head of the largemouth bass (Micropterus salmoides). BassBot incorporates a three-dimensional acrylic plastic armature of the neurocranium, maxillary apparatus, lower jaw, hyoid, suspensorium, and opercular apparatus. Programming of linear motors permits precise reproduction of live kinematic behaviors including hyoid depression and rotation, premaxillary protrusion, and lateral expansion of the suspensoria. BassBot reproduced faithful kinematic and pressure dynamics relative to live bass. We show that motor program speed has a direct relationship on subambient pressure generation. Like vertebrate muscle, the linear motors that powered kinematics were able to produce larger magnitudes of force at slower velocities and, thus, were able to accelerate linkages more quickly and generate larger magnitudes of subambient pressure. In addition, we demonstrate that disrupting the kinematic behavior of the hyoid interferes with the anterior-to-posterior expansion gradient. This resulted in a significant reduction in subambient pressure generation and pressure impulse of 51% and 64% respectively. These results reveal the promise biorobotic models have in isolating individual parameters and assessing their role in suction feeding.