Elasmobranchs, comprising sharks, skates, and rays, have a long evolutionary history extending back into the Palaeozoic. They are characterized by various unique traits including a predominantly cartilaginous skeleton, superficial prismatic phosphatic layer, and permanent tooth replacement. Moreover, they exhibit a more or less marked sexual dimorphism. Especially the morphology of the chondrocranium and the elements of the whole cranial region of extant and extinct chondrichthyans can provide valuable information about corresponding functions, e.g. the feeding apparatus might reflect the diet of the animals. However, studies on sexual dimorphisms are lacking in orectolobiform sharks, therefore, little is known about possible sexual dimorphic characters in the cranial region in this group. For this reason, we present in this study a comprehensive morphological description of the cranial region of the brownbanded bamboo shark Müller & Henle, 1838, with a special focus on its sexual dimorphic characters. Our results reveal clear morphological differences in both sexes of the examined specimens, particularly in the chondrocranium and the mandibular arch. The female specimen shows a comparatively more robust and compact morphology of the chondrocranium. This pattern is also evident in the mandibular arch, especially in the palatoquadrate. The present study is the first to describe the morphology of an orectolobiform shark species in detail using both manual dissection and micro-CT data. The resulting data furthermore provide a starting point for pending studies and are intended to be a first step in a series of comparative studies on the morphology of the cranial region of orectolobiform sharks, including the determination of possible sexual dimorphic characteristics.

In most modern bony vertebrates, a considerable portion of the chondrocranium remains cartilaginous only during a relatively small window of embryonic development, making it difficult to study this complex structure. Yet, the transient nature of some chondrocranial elements is precisely why it is so intriguing. Since the chondrocranium has never been lost in any vertebrate, its function is critical to craniofacial development, disease, and evolution. Experimental evidence for the various roles of the chondrocranium is limited, and though snapshots of chondrocranial development in various species at isolated time points are valuable and informative, these cannot provide the data needed to determine the functions of the chondrocranium, or its relationship to the dermatocranium in evolution, in development, or in disease. Observations of the spatiotemporal associations of chondrocranial cartilage, cartilage bone, and dermal bone over early developmental time are available for many vertebrate species and these observations represent the data from which we can build hypotheses. The testing of those hypotheses requires precise control of specific variables like developmental time and molecular signaling that can only be accomplished in a laboratory setting. Here, we employ recent advances in contrast-enhanced micro computed tomography to provide novel 3D reconstructions of the embryonic chondrocranium in relation to forming dermal and cartilage bones in laboratory mice across three embryonic days (E13.5, E14.5, and E15.5). Our observations provide support for the established hypothesis that the vertebrate dermal (exo-) skeleton and endoskeleton evolved as distinct structures and remain distinct. Additionally, we identify spatiotemporal patterning in the development of the lateral wall, roof, and braincase floor of the chondrocranium and the initial mineralization and growth of the bones associated with these cartilages that provides support for the hypothesis that the chondrocranium serves as a scaffold for developing dermatocranial bones. The experimental protocols described and data presented provide tools for further experimental work on chondrocranial development.