Technical note: Artificial Resynthesis Technology for the experimental formation of dental microwear textures
Autor: | Alexandria S. Peterson, Young Cheul Heo, Michael Weston, Kristin L. Krueger, Bonita van Heel, Evan Chwa, Ralph DeLong, Alex Fok, John C. Willman |
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Rok vydání: | 2021 |
Předmět: |
Technology
Fossil Record Enamel paint business.industry Dentistry Technical note Oral cavity Diet stomatognathic diseases stomatognathic system Tooth wear Food Anthropology Food texture visual_art visual_art.visual_art_medium Complex variables Animals Mastication Cattle Tooth Wear Anatomy business Geology |
Zdroj: | American journal of physical anthropologyREFERENCES. 176(4) |
ISSN: | 1096-8644 |
Popis: | Dental microwear formation on the posterior dentition is largely attributed to an organism's diet. However, some have suggested that dietary and environmental abrasives contribute more to the formation process than food, calling into question the applicability of dental microwear to the reconstruction of diet in the fossil record. Creating microwear under controlled conditions would benefit this debate, but requires accurately replicating the oral environment. This study tests the applicability of Artificial Resynthesis Technology (ART 5) to create microwear textures while mitigating the challenges of past research. ART 5 is a simulator that replicates the chewing cycle, responds to changes in food texture, and simulates the actions of the oral cavity. Surgically extracted, occluding pairs of third molars (n = 2 pairs) were used in two chewing experiments: one with dried beef and another with sand added to the dried beef. High-resolution molds were taken at 0, 50, 100, 2500, and 5000 simulated chewing cycles, which equates to approximately 1 week of chewing. Preliminary results show that ART 5 produces microwear textures. Meat alone may produce enamel prism rod exposure at 5000 cycles, although attrition cannot be ruled out. Meat with sand accelerates the wear formation process, with enamel prism rods quickly obliterated and "pit-and-scratch" microwear forming at approximately 2500 cycles. Future work with ART 5 will incorporate a more thorough experimental protocol with improved controls, pH of the simulated oral environment, and grit measurements; however, these results indicate the potential of ART 5 in untangling the complex variables of dental microwear formation. |
Databáze: | OpenAIRE |
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