Approximation of extracted features enabling 3D design tuning for reproducing the mechanical behaviour of biological soft tissues

This article describes a new method, inspired by machine learning, to mimic the mechanical behaviour of target biological soft tissues with 3D printed materials. The principle is to optimise the structure of a 3D printed composite consisting of a geometrically tunable fibre embedded in a soft matrix...

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Published in:Soft matter 2024-03, Vol.2 (12), p.273-2738
Main Authors: Serantoni, Vincent, Rouby, Corinne, Heller, Ugo, Boisson, Jean
Format: Article
Language:English
Subjects:
Machine learning
Mechanical properties
Periosteum
Soft tissues
Strain
Stress-strain curves
Tensile tests
Three dimensional composites
Three dimensional printing
Tissues
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creator Serantoni, Vincent
Rouby, Corinne
Heller, Ugo
Boisson, Jean
description This article describes a new method, inspired by machine learning, to mimic the mechanical behaviour of target biological soft tissues with 3D printed materials. The principle is to optimise the structure of a 3D printed composite consisting of a geometrically tunable fibre embedded in a soft matrix. Physiological features are extracted from experimental stress-strain curves of several biological soft tissues. Then, using a cubic Bézier curve as the composite inner fibre, we optimised its geometric parameters, amplitude and height, to generate a specimen that exhibits a stress-strain curve in accordance with the extracted features of tensile tests. From this first phase, we created a database of specimen geometries that can be used to reproduce a wide variety of biological soft tissues. We applied this process to two soft tissues with very different behaviours: the mandibular periosteum and the calvarial periosteum. The results show that our method can successfully reproduce the mechanical behaviour of these tissues. This highlights the versatility of this approach and demonstrates that it can be extended to mimic various biological soft tissues. A machine learning inspired method to mimic the mechanical behaviour of biological soft tissues is described. The tuned composite, based on Bézier curves, gives good results in the experimental reproduction of mandibular and calvarial periosteum.
doi_str_mv 10.1039/d3sm01159c
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source Royal Society of Chemistry:Jisc Collections:Royal Society of Chemistry Read and Publish 2022-2024 (reading list)
subjects Machine learning
Mechanical properties
Periosteum
Soft tissues
Strain
Stress-strain curves
Tensile tests
Three dimensional composites
Three dimensional printing
Tissues
title Approximation of extracted features enabling 3D design tuning for reproducing the mechanical behaviour of biological soft tissues
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