Auxetic Metamaterials for Biomedical Devices: Current Situation, Main Challenges, and Research Trends

Auxetic Metamaterials for Biomedical Devices: Current Situation, Main Challenges, and Research Trends

Auxetic metamaterials are characterized by a negative Poisson ratio (NPR) and display an unexpected property of lateral expansion when stretched and densification when compressed. Auxetic properties can be achieved by designing special microstructures, hence their classification as metamaterials, an...

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Bibliographic Details
Published in:Materials Vol. 15; no. 4; p. 1439
Main Authors: Lvov, Vladislav A, Senatov, Fedor S, Veveris, Alnis A, Skrybykina, Vitalina A, Díaz Lantada, Andrés
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 15-02-2022
MDPI
Subjects:
additive manufacturing
Artificial intelligence
auxetics
Back surgery
Biomechanics
biomedical devices
Biomedical materials
Densification
Design
Design engineering
Finite element analysis
Geometry
Manufacturing
Medical device industry
Medical electronics
Medical equipment
Medical research
Metamaterials
microfabrication
Morphing
Optimization techniques
Poisson's ratio
Prostheses
Prototyping
Raw materials
Review
Stents
Tissue engineering
Transplants & implants
auxetics
additive manufacturing
tissue engineering
biomedical devices
computational modelling
metamaterials
microfabrication
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Summary:Auxetic metamaterials are characterized by a negative Poisson ratio (NPR) and display an unexpected property of lateral expansion when stretched and densification when compressed. Auxetic properties can be achieved by designing special microstructures, hence their classification as metamaterials, and can be manufactured with varied raw materials and methods. Since work in this field began, auxetics have been considered for different biomedical applications, as some biological tissues have auxetic-like behaviour due to their lightweight structure and morphing properties, which makes auxetics ideal for interacting with the human body. This research study is developed with the aim of presenting an updated overview of auxetic metamaterials for biomedical devices. It stands out for providing a comprehensive view of medical applications for auxetics, including a focus on prosthetics, orthotics, ergonomic appliances, performance enhancement devices, in vitro medical devices for interacting with cells, and advanced medicinal clinical products, especially tissue engineering scaffolds with living cells. Innovative design and simulation approaches for the engineering of auxetic-based products are covered, and the relevant manufacturing technologies for prototyping and producing auxetics are analysed, taking into consideration those capable of processing biomaterials and enabling multi-scale and multi-material auxetics. An engineering design rational for auxetics-based medical devices is presented with integrative purposes. Finally, key research, development and expected technological breakthroughs are discussed.
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ISSN:1996-1944
1996-1944
DOI:10.3390/ma15041439