PEER-REVIEWED PUBLICATION

2023

Automated Model Discovery for Skin: Discovering the Best Model, Data, and Experiment

Linka K, Tepole AB, et al.

Computer Methods in Applied Mechanics and Engineering

Stanford University, Purdue University, Graz University of Technology, Norwegian University of Science and Technology

RESEARCH SUMMARY

This work introduces a new class of Constitutive Artificial Neural Networks (CANNs) that autonomously discover the optimal constitutive model and material parameters from experimental data. The authors trained the network using biaxial extension datasets from rabbit and pig skin, acquired through mechanical tests performed on a CellScale BioTester 5000. The CANN framework embeds kinematic, thermodynamic, and polyconvexity constraints into its architecture, enabling the network to identify meaningful constitutive equations directly from data. The discovered models revealed that skin mechanics can be represented by a two-term exponential function based on the first and fourth strain invariants, corresponding to isotropic matrix and anisotropic collagen fiber contributions. The network also identified the optimal experimental protocols for maximizing model information, highlighting off-axis biaxial tests as the most informative for skin mechanics.

Biaxial extension experiments on rabbit and pig skin were performed using a CellScale BioTester 5000. Square skin specimens (~35 × 35 mm², 1.2 mm thick) were mounted with collagen fibers aligned along the principal axes, submerged in physiological solution, and subjected to controlled stretch protocols. The BioTester applied equibiaxial, off-axis, and uniaxial deformations while recording nominal stresses in both axes. These data were used to train neural networks that autonomously discovered the optimal constitutive representations of skin, quantifying anisotropy and collagen fiber alignment effects. Comparative training with rabbit and pig skin datasets revealed consistent two-term exponential behavior and demonstrated that the BioTester provided sufficiently rich data for robust model discovery.

AUTHORS

Kevin Linka, Adrian Buganza Tepole, Gerhard A. Holzapfel, Ellen Kuhl.

PUBLICATION DETAILS

JOURNAL

Computer Methods in Applied Mechanics and Engineering

YEAR

2023

INSTITUTIONS

Stanford University, Purdue University, Graz University of Technology, Norwegian University of Science and Technology

COUNTRIES

Austria, Norway, United States

INSTRUMENT USED

BioTester

TESTING METHODS

Biaxial TestingHydrated and Temperature Controlled TestingTensile Testing

RESEARCH APPLICATIONS

ECM & Decellularized Matrix MechanicsFibrosis & Tissue RemodelingMechanotransductionSkin and Wound Healing Biomechanics

Related Publications:

Instrument Used:

Year:

Testing Method:

Research Application:

Country:

Postpartum biomechanical adaptations of the anterior abdominal wall in a rat model: Implications for diastasis rectus abdominis

Lax M, Morgan M, et al.

Clinical Biomechanics

BioTester

Tensile Testing

Musculoskeletal Tissue Engineering & MechanicsPelvic Floor and Gynecological Biomechanics

2026

Comparison of Mechanical Properties of Patient-Specific Direct 3D-Printed Aortic Valve for Simulation Trainings: A Comparative Study

Cheheili Sobbi S, Pavlykova-Chertovska A, et al.

Innovations

BioTester

Digital Image Correlation (DIC)Tensile Testing

Cardiac Tissue Engineering & MechanicsHeart Valve Tissue Engineering & MechanicsPolymers and Elastomers Testing

2026

A deep neural network surrogate for fast mechanical parameter identification using the ring tensile test

Utrera A, Navarrete Á, et al.

Materials & Design

BioTester

Hydrated and Temperature Controlled TestingTensile Testing

MechanotransductionVascular Tissue Engineering & Mechanics

2026