Enhancement of Bone Regeneration Through the Converse Piezoelectric Effect, A Novel Approach for Applying Mechanical Stimulation.

IF 1.6 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY
Bioelectricity Pub Date : 2021-12-01 Epub Date: 2021-12-16 DOI:10.1089/bioe.2021.0019
Amber Carter, Kristen Popowski, Ke Cheng, Alon Greenbaum, Frances S Ligler, Adele Moatti
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引用次数: 0

Abstract

Serious bone injuries have devastating effects on the lives of patients including limiting working ability and high cost. Orthopedic implants can aid in healing injuries to an extent that exceeds the natural regenerative capabilities of bone to repair fractures or large bone defects. Autografts and allografts are the standard implants used, but disadvantages such as donor site complications, a limited quantity of transplantable bone, and high costs have led to an increased demand for synthetic bone graft substitutes. However, replicating the complex physiological properties of biological bone, much less recapitulating its complex tissue functions, is challenging. Extensive efforts to design biocompatible implants that mimic the natural healing processes in bone have led to the investigation of piezoelectric smart materials because the bone has natural piezoelectric properties. Piezoelectric materials facilitate bone regeneration either by accumulating electric charge in response to mechanical stress, which mimics bioelectric signals through the direct piezoelectric effect or by providing mechanical stimulation in response to electrical stimulation through the converse piezoelectric effect. Although both effects are beneficial, the converse piezoelectric effect can address bone atrophy from stress shielding and immobility by improving the mechanical response of a healing defect. Mechanical stimulation has a positive impact on bone regeneration by activating cellular pathways that increase bone formation and decrease bone resorption. This review will highlight the potential of the converse piezoelectric effect to enhance bone regeneration by discussing the activation of beneficial cellular pathways, the properties of piezoelectric biomaterials, and the potential for the more effective administration of the converse piezoelectric effect using wireless control.

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通过匡威压电效应促进骨再生--应用机械刺激的新方法
严重的骨伤会对患者的生活造成破坏性影响,包括限制工作能力和高昂的费用。骨科植入物在修复骨折或大面积骨缺损方面可以帮助愈合损伤,其程度超过了骨骼的自然再生能力。自体移植物和同种异体移植物是目前使用的标准植入物,但由于存在供体部位并发症、可移植骨数量有限和成本高昂等缺点,对合成骨移植替代物的需求日益增加。然而,复制生物骨的复杂生理特性,更不用说再现其复杂的组织功能,是一项具有挑战性的工作。由于骨骼具有天然的压电特性,因此人们对压电智能材料进行了研究。压电材料可通过以下两种方式促进骨骼再生:一种是在机械应力作用下积累电荷,通过直接压电效应模拟生物电信号;另一种是通过反向压电效应在电刺激作用下提供机械刺激。虽然这两种效应都有益处,但反向压电效应可以通过改善愈合缺损的机械反应,解决应力屏蔽和不活动造成的骨萎缩问题。机械刺激可激活细胞通路,增加骨形成,减少骨吸收,从而对骨再生产生积极影响。本综述将通过讨论有益细胞通路的激活、压电生物材料的特性以及利用无线控制更有效地管理反向压电效应的潜力,突出反向压电效应在促进骨再生方面的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Bioelectricity
Bioelectricity Multiple-
CiteScore
3.40
自引率
4.30%
发文量
33
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