Modelling marsupial mastication: The biomechanical bite model of the Linnaeus's mouse opossum Marmosa murina (Marsupialia, Didelphidae).

IF 1.9 3区医学 Q2 ANATOMY & MORPHOLOGY

Journal of Anatomy Pub Date : 2025-06-27 DOI:10.1111/joa.70003

Vincent Decuypere, Anthony Herrel, Quentin Grimal, Damien Germain, Anne-Claire Fabre, Sandrine Ladevèze

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引用次数: 0

Abstract

Marsupials have evolved alongside other mammals on many continents, mainly in the southern hemisphere, developing their own traits and adaptations. Although the relationships between morphology, bite force, and diet have been well studied in many vertebrate groups, this has rarely been the case for marsupials until recently. Present-day American marsupials' diet and their feeding capacities, considered generalists, remain poorly understood. A better understanding of current American marsupials will lead to more accurate inference models for extinct metatherians. Here, we study and describe for the first time the masticatory apparatus of the Linnaeus' mouse opossum Marmosa murina, along with its performance. Bite forces data were collected for different marsupial species during a field mission in French Guiana in 2017. A 3D bite reconstruction model has been established through dissections and using the lever arm method, based on the static equilibrium of the muscular vectors in the jaw. The optimal gape angle and the contribution of each masticatory muscle to the closing of the mouth were determined. We identify and individualized the different fascicles of the masseter, zygomaticomandibular, temporal, and pterygoid muscles, together with their respective origin and insertion areas. The optimal gape is around 6°, supporting the use of the last molar to get the strongest bite forces. The M. masseter superficialis, the M. temporalis superficialis, and the M. temporalis profundus medialis are the muscles having the greatest impact on the maximum bite force. Our biomechanical model allows a correct approximation of the biting force. However, the muscle stress value has to be increased from 30 N.cm^-2 to 44.360 N.cm^-2 and 54.209 N.cm^-2 to match the in vivo bite forces on the last molar (m4) for Marmosa murina. These high values are rather surprising, suggesting that our model, with the use of standardized constants for all mammals, underestimates true bite forces.

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模拟有袋动物咀嚼：林奈鼠负鼠Marmosa murina（有袋动物，双翅目）的生物力学咬伤模型。

有袋动物与其他哺乳动物一起在许多大洲进化，主要是在南半球，发展出自己的特征和适应能力。尽管形态、咬合力和饮食之间的关系已经在许多脊椎动物群体中得到了很好的研究，但直到最近才在有袋类动物中得到研究。现代美国有袋动物的饮食和摄食能力，被认为是多面手，仍然知之甚少。更好地了解现在的美国有袋动物，将为已经灭绝的元兽类动物带来更准确的推理模型。本文首次对林奈鼠负鼠（Marmosa murina）的咀嚼器官及其功能进行了研究和描述。2017年，在法属圭亚那的一次实地考察中，科学家收集了不同有袋动物物种的咬合力数据。基于颌骨肌肉矢量的静态平衡，通过解剖和杠杆臂方法建立了三维咬合重建模型。确定了最佳的张口角度和各咀嚼肌对闭口的贡献。我们识别和个性化咬肌、颧下颌肌、颞肌和翼状肌的不同肌束，以及它们各自的起源和插入区域。最佳咬合间隙约为6°，支持使用最后一颗磨牙，以获得最强的咬合力。咬肌浅肌、颞浅肌和颞深肌内侧肌是对最大咬合力影响最大的肌肉。我们的生物力学模型允许对咬合力进行正确的近似。然而，肌肉应力值必须从30牛开始增加。cm-2至44.360北纬cm-2和54.209 N。cm-2来匹配鼠狨猴最后一颗臼齿（m4）的体内咬合力。这些高数值相当令人惊讶，这表明我们的模型使用了所有哺乳动物的标准化常数，低估了真实的咬合力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Anatomy 医学-解剖学与形态学

CiteScore

4.80

自引率

8.30%

发文量

183

审稿时长

4-8 weeks

期刊介绍： Journal of Anatomy is an international peer-reviewed journal sponsored by the Anatomical Society. The journal publishes original papers, invited review articles and book reviews. Its main focus is to understand anatomy through an analysis of structure, function, development and evolution. Priority will be given to studies of that clearly articulate their relevance to the anatomical community. Focal areas include: experimental studies, contributions based on molecular and cell biology and on the application of modern imaging techniques and papers with novel methods or synthetic perspective on an anatomical system. Studies that are essentially descriptive anatomy are appropriate only if they communicate clearly a broader functional or evolutionary significance. You must clearly state the broader implications of your work in the abstract. We particularly welcome submissions in the following areas: Cell biology and tissue architecture Comparative functional morphology Developmental biology Evolutionary developmental biology Evolutionary morphology Functional human anatomy Integrative vertebrate paleontology Methodological innovations in anatomical research Musculoskeletal system Neuroanatomy and neurodegeneration Significant advances in anatomical education.