TURNING TEENS INTO FOSSILPHILES: CITIZEN SCIENCE AND ADVANCED VISUALIZATION OF PALEONTOLOGY COLLECTIONS

In 2016, the North Carolina Museum of Natural Sciences (NCMNS) received funding from NSF’s Collections in Support of Biological Research Program to launch a new citizen science initiative—FossilPhiles—aimed at improving publically accessible natural history specimen data. The FossilPhiles project supported NCMNS’ ongoing efforts to digitize paleontology collections and provide STEM opportunities for historically underrepresented student populations by engaging middle and high school students in authentic data collection. Five students were chosen from area schools with underserved populations to digitize highly significant or visually impactful vertebrate, invertebrate, and paleobotanical fossil specimens (e.g., type specimens, rare collections, specimens of high public interest). Students were trained in specimen handling, collections data, and archiving. They collected standard measurement data, photographed specimens in 2D, and constructed 3D photorealistic models using photogrammetry. Over a period of six months, students took over 13,000 photos, documenting 176 specimens in 2D and 137 in 3D. Of these, 124 photos have already been uploaded to the NCMNS’ open-access collections database, accessible through the NCMNS’ website, GBIF, VertNet, and iDigBio. Future project plans include creation of a publicly accessible, interactive portal of the 3D specimen models. Throughout their internships, FossilPhiles students were provided training and opportunities to communicate their experiences with the broader community. The entirety of the FossilPhiles project took place within the glass-walled Paleontology Research Lab (PRL) in the Nature Research Center of the NCMNS, on view to NCMNS’ ~1 million annual visitors. Additionally, students were regularly engaged with communicating about the project in real-time via social media outlets (e.g., Twitter, blogs), sharing photos of fossils they worked on, facts and skills that they learned, and challenges they overcame. FossilPhiles students also partnered with peers engaged in non-STEM museum internships to promote cross-learning. They collaborated with the NCMNS’ Teen Newsroom program to produce a video interview about their evolving impressions on what it means to be a scientist

Incremental growth of therizinosaurian dental tissues: implications for dietary transitions in Theropoda

Previous investigations document functional and phylogenetic signals in the histology of dinosaur teeth. In particular, incremental lines in dentin have been used to determine tooth growth and replacement rates in several dinosaurian clades. However, to date, few studies have investigated the dental microstructure of theropods in the omnivory/herbivory spectrum. Here we examine dental histology of Therizinosauria, a clade of large-bodied theropods bearing significant morphological evidence for herbivory, by examining the teeth of the early-diverging therizinosaurian Falcarius utahensis, and an isolated tooth referred to Suzhousaurus megatherioides, a highly specialized large-bodied representative. Despite attaining some of the largest body masses among maniraptoran theropod dinosaurs, therizinosaurian teeth are diminutive, measuring no more than 0.90 cm in crown height (CH) and 0.38 cm in crown base length (CBL). Comparisons with other theropods and non-theropodan herbivorous dinosaurs reveals that when controlling for estimated body mass, crown volume in therizinosaurians plots most closely with dinosaurs of similar dietary strategy as opposed to phylogenetic heritage. Analysis of incremental growth lines in dentin, observed in thin sections of therizinosaurian teeth, demonstrates that tooth growth rates fall within the range of other archosaurs, conforming to hypothesized physiological limitations on the production of dental tissues. Despite dietary differences between therizinosaurians and hypercarnivorous theropods, the types of enamel crystallites present and their spatial distribution—i.e., the schmelzmuster of both taxa—is limited to parallel enamel crystallites, the simplest form of enamel and the plesiomorphic condition for Theropoda. This finding supports previous hypotheses that dental microstructure is strongly influenced by phylogeny, yet equally supports suggestions of reduced reliance on oral processing in omnivorous/herbivorous theropods rather than the microstructural specializations to diet exhibited by non-theropodan herbivorous dinosaurs. Finally, although our sample is limited, we document a significant reduction in the rate of enamel apposition contrasted with increased relative enamel thickness between early and later diverging therizinosaurians that coincides with anatomical evidence for increased specializations to herbivory in the clade