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

**Authors:** Vincent Decuypere, Anthony Herrel, Quentin Grimal, Damien Germain, Anne‐Claire Fabre, Sandrine Ladevèze

PMC · DOI: 10.1111/joa.70003 · Journal of Anatomy · 2025-06-27

## TL;DR

This paper studies the jaw mechanics of the Linnaeus's mouse opossum to understand its bite force and mastication, offering new insights into marsupial evolution.

## Contribution

The first biomechanical bite model of Marmosa murina, combining in vivo data and 3D reconstruction to estimate bite forces.

## Key findings

- The optimal gape angle for maximum bite force in Marmosa murina is around 6°.
- The M. masseter superficialis, M. temporalis superficialis, and M. temporalis profundus medialis contribute most to bite force.
- Muscle stress values in the model need to be increased to match in vivo measurements, suggesting underestimation by current methods.

## 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.

The marsupial masticatory apparatus has rarely been studied until recently, mainly in Australasian species. We therefore reconstructed the maximum bite forces of the South American Linnaeus's mouse opossum Marmosa murina using in vivo bites, specimen dissections, and 3D static equilibrium of the jaw muscles. Our research provides relevant anatomical data and raises new evolutionary hypotheses and questions about the inner muscular or physiological parameters of the marsupial jaw.

## Linked entities

- **Species:** Marmosa murina (taxon 126295)

## Full-text entities

- **Species:** Marmosa murina (murine mouse opossum, species) [taxon 126295], Mus musculus (house mouse, species) [taxon 10090]

## Full text

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## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12588181/full.md

## References

82 references — full list in the complete paper: https://tomesphere.com/paper/PMC12588181/full.md

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Source: https://tomesphere.com/paper/PMC12588181