309.4 - Intra- and interspecific structural variation in the archosaur lung: insights from 3D imaging and segmentation

Emma Schachner (Louisiana State University Health Sciences Center), Adam Lawson (Tulane University), Aracely Martinez (Louisiana State University Health Sciences Center), M Echols (Medical Center for Birds), Raul Diaz Jr (California State University Los Angeles), Clinton Grand Pre (Louisiana State University Health Sciences Center), Brandon Hedrick (Louisiana State University Health Sciences Center)

Innovations in three-dimensional (3D) imaging and segmentation have facilitated unprecedented levels of anatomical investigation into the detailed structures of the respiratory system that are often difficult to study in situ. Recent hypotheses of homology between crocodilians and birds have facilitated quantitative comparative analyses of bronchial trees and in situ models reveal new complexities in the relationship between the respiratory and skeletal systems. Here we quantitatively compare the bronchial trees of two crocodilians, the American alligator (Alligator mississippiensis) and Cuvier’s dwarf caiman (Paleosuchus palpebrosus) with select birds, including the ostrich (Struthio camelus), the African gray parrot (Psittacus erithacus), and the red-tailed hawk (Buteo jamaicensis). Notably, the relative distances from the carina to the secondary bronchi measured are conserved, indicating a possible ancestral or constrained trait. With respect to interspecific avian comparisons, we found grossly observable variation within a single taxon in air sac morphology (e.g., P. erithacus), as well as substantial differences between the individual taxa via segmented surface models – particularly in the expansions of the interclavicular sacs, the extent of the diverticula, and the size of the abdominal sacs. Furthermore, we found that specific sac contribution to postcranial pneumatization varies substantially across our dataset. Individual specimens imaged for this study also revealed multiple pathologies, including scoliosis, foreign objects inside the animals, and broken bones, which have been incorporated into the anatomical models for clinical surgical atlases that are under development. While these data are preliminary, they provide a framework for larger scale comparisons and hypotheses of the ancestral archosaurian pulmonary system.

LSUHSC Research Enhancement Program Grant