Shape change throughout the body of the tongue during drinking in the striped skunk (Mephitis mephitis)

Abstract

In mammals, the tongue plays a central role in many oral behaviors, but it is particularly essential for feeding and drinking. During feeding, the tongue is used for ingestion, manipulation and positioning of food within the oral cavity, and swallowing. When mammals drink, they do so by lapping, licking, or sucking, and the tongue is vital to uptake and transport of fluid into and through the oral cavity and oropharynx. All of these behaviors are performed with only a partial reliance on a bony support system; instead the tongue engages in complex movements as a muscular hydrostat – where selective contraction of intrinsic and extrinsic muscle fibers produce movements and deformations of the tongue. The tongue's anatomical complexity and its location inside the oral cavity make it particularly difficult to visualize and study the movements that contribute to these and other oral behaviors. The objective of this study is to test the ability of marker‐based XROMM (X‐ray reconstruction of moving morphology) to track shape changes throughout the body of the tongue. The striped skunk (Mephitis mephitis), a mammalian omnivore belonging to the order Carnivora, was used as a model for rhythmic lapping while drinking a barium liquid. Data was collected using XROMM with markers implanted in the bones of the skull as well as in the body of the tongue. Tongue markers were used to calculate length changes throughout the body of the tongue. Timing and movement parameters are also registered to the gape cycle derived from the rigid body motions derived from skeletal markers. Based on an analysis of 150 cycles, during rhythmic drinking, the middle and posterior tongue underwent the most variation in length change, while the anterior tongue underwent the least amount of variation in length. In contrast, the posterior tongue underwent the least amount of variation in tongue width, as compared to the anterior and middle tongue. Maximum overall tongue length occurred 2.74±29.3 msec before maximum gape, whereas minimal overall tongue length occurred 20.24±7.38 msec before minimum gape. Based on these preliminary results, this method shows promise for producing quantitative data for studying tongue deformations within the oral cavity. Future studies incorporating spatial parameters of the tongue to the rest of the feeding apparatus across mammals will further our understanding of how the tongue functions during feeding and drinking behaviors.Support or Funding InformationNational Science Foundation Grant DBI‐0922988, National Science Foundation Grant IOS‐1456810This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.