| Abstract: | The masticatory apparatus of the vespertilionid bat Myotis lucifugus appears generalized. Principal modifications for more efficient trituration have involved accessory tooth cusps. Chewing strokes pass through orbits (up to 7/sec) involving translations along and rotation about three axes. Direction of chewing typically reverses by at least the fifth or sixth consecutive orbit. Reversal involves modification of the downstroke at varying positions along its course. Compared to certain other bats, which do not utilize oral phonation for echolocation, Myotis chews much more rapidly, with many more degrees of freedom in orbital configuration. The overall envelope of motion is remarkably similar in all these species. The jaw muscles of Myotis act asymetrically, and in more than one direction as the orbit progresses. They overlap in their periods of activity forming a continually-modified muscular sling. Unilateral force couples facilitate orthal rotation at the condyles and movements of them. Bilateral couples, pitting protrusors of one side against retrusors of the other, facilitate lateral translation. The pterygoids are instrumental in continuing motion across the top and bottom of the orbit. Countercontractions are particularly important in stabilizing and protecting the temporomandibular joints. The mandibular symphyseal joint appears to act passively, providing additional flexibility for the system. Higher nervous control beyond the simple jaw-opening reflex appears necessary to explain the firing order of the digastrics and the phase relationship of orbital reversal to overall muscular firing intensity. Control mechanisms, ancillary phenomena and comparative aspects are discussed. |
