Emerging Piezoelectric Metamaterials for Biomedical Applications

Jingwei, Xie

doi:10.53941/mi.2024.100004

Open Access

Review

Emerging Piezoelectric Metamaterials for Biomedical Applications

Zishuo Yan¹

,

Huy Tran¹

,

Dezun Ma¹

,

Jingwei Xie^{1, 2, *}

Author Information

Submitted: 30 Sept 2024 | Revised: 18 Nov 2024 | Accepted: 20 Nov 2024 | Published: 21 Nov 2024

Abstract

Emerging piezoelectric metamaterials hold immense promise for biomedical applications by merging the intrinsic electrical properties of piezoelectricity with the precise architecture of metamaterials. This review provides a comprehensive overview of various piezoelectric materials- such as molecular crystals, ceramics, and polymers—known for their exceptional piezoelectric performance and biocompatibility. We explore the advanced engineering approaches, including molecular design, supramolecular packing, and 3D assembly, which enable the customization of piezoelectric properties for targeted biomedical applications. Particular attention is given to the pivotal role of metamaterial structuring in the development of 0D spheres, 1D fibers and tubes, 2D films, and 3D scaffolds. Key biomedical applications, including tissue engineering, drug delivery, wound healing, and biosensing, are discussed through illustrative examples. Finally, the article addresses critical challenges and future directions, aiming to drive further innovations in piezoelectric biomaterials for next-generation healthcare technologies.

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Keywords

piezoelectric metamaterials | molecular design | supramolecular packing | 3D assembly | biomedical applications

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DOI

10.53941/mi.2024.100004

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Volume 1, Issue 1

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Yan, Z., Tran, H., Ma, D., & Xie, J. (2024). Emerging Piezoelectric Metamaterials for Biomedical Applications. Materials and Interfaces, 1(1), 13–34. https://doi.org/10.53941/mi.2024.100004

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