Secrétariat médical Offres d'emploi - Ozoir-la-Ferrière (77)

Topic description

Context. The skin serves as the body’s outermost protective layer and must retain its elasticity, firmness, and tensile strength. Assessing its biomechanical properties is essential for accurate diagnosis, monitoring treatment responses, and improving theragnostic strategies. Since the mechanical behaviour of biological soft tissues is highly dependent to their physiopathological state, clinicians often rely on palpation, a subjective experience-dependent method with limited sensitivity, to detect abnormalities in superficial tissues. To address these limitations, various non-invasive techniques, such as elastography, have been developed to quantitatively evaluate tissue elasticity. However, despite their precision, these imaging techniques remain costly and complex to operate.

A practical, low-cost, and real-time method for non-invasive skin characterization has been proposed by the MSME lab. The approach involves an instrumented small hammer equipped with a piezoelectric force sensor on its impacting surface. By measuring the time-dependent force applied between the hammer and a metallic cylindrical rod in contact with the skin, the system enables the assessment of soft tissue mechanical properties. In this context, we need a detailed understanding of the dynamic behaviour occurring during the measurement procedure of the skin biomechanical properties, which will eventually lead to the development of an effective medical device for the estimation of the skin properties.

Objective. The objective of this work is to develop biomechanical models and associated numerical methods capable of predicting the dynamic behaviour of the skin-rod coupled system under impact loading, as defined by the experimental protocol. The biomechanical model must accurately describe the high strain-rate deformation behaviour of the skin during impact. Two primary challenges must be addressed: The tissue’s model must account for its anisotropic, multilayered, and micro-structured nature, as well as its rate-dependent dissipative behaviour; Contact modelling: The contact model must incorporate detailed surface geometries and deformations to capture the complexity of friction and adhesion phenomena at the skin-metal interface under dynamic loading.

The project will proceed through the following steps:

1. The derived physical models—both for the skin and the skin–rod contact interface—will be implemented in numerical solvers to address the forward problem.

2. A contact detection algorithm will be developed to effectively handle the irregular interface between the metallic rod and the stratum corneum (the outermost layer of the epidermis).

3. Direct time integration schemes will be employed to efficiently solve the resulting nonlinear coupled system.

4. Model order reduction techniques for finite element simulations of impact problems in the considered multiphysics and strongly heterogeneous medium will be developed.

5. Finally, model-based machine learning approaches will be introduced to enable real-time simulation of this large-scale system.

Starting date

-10-01

Funding category

Public/private mixed funding

Funding further details

ANR