Ultrasound-activated piezoelectric biomaterials for cartilage regeneration

IF 8.7 1区化学 Q1 ACOUSTICS

Ultrasonics Sonochemistry Pub Date : 2025-04-14 DOI:10.1016/j.ultsonch.2025.107353

Yangchen Wei , Zhengyang Li , Tianjing Yu , Yan Chen , Qinglai Yang , Kaikai Wen , Junlin Liao , Linlin Li

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Abstract

Due to the low density of chondrocytes and limited ability to repair damaged extracellular matrix (ECM) in cartilage, many patients with congenital or acquired craniofacial trauma require filler graft materials to support facial structure, restore function, improve self-confidence, and regain socialization. Ultrasound has the capacity to stimulate piezoelectric materials, converting mechanical energy into electrical signals that can regulate the metabolism, proliferation, and differentiation of chondrocytes. This unique property has sparked growing interest in using piezoelectric biomaterials in regenerative medicine. In this review, we first explain the principle behind ultrasound-activated piezoelectric materials and how they generate piezopotential. We then review studies demonstrating how this bioelectricity promotes chondrocyte regeneration, stimulates the secretion of key extracellular components and supports cartilage regeneration by activating relevant signaling pathways. Next, we discuss the properties, synthesis, and modification strategies of various piezoelectric biomaterials. We further discuss recent progresses in the development of ultrasound-activated piezoelectric biomaterials specifically designed for cartilage regeneration. Lastly, we discuss future research challenges facing this technology, ultrasound-activated piezoelectric materials for cartilage regeneration engineering. While the technology holds great promise, certain obstacles remain, including issues related to material stability, precise control over ultrasound parameters, and the integration of these systems into clinical settings. The combination of ultrasound-activated piezoelectric technology with other emerging fields, such as Artificial Intelligence (AI) and cartilage organoid chips, may open new frontiers in regenerative medicine. We hope this review encourages further exploration of ultrasound-activated strategies for piezoelectric materials and their future applications in regenerative medicines.

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超声激活的软骨再生压电生物材料

由于软骨细胞密度低，修复软骨受损细胞外基质（ECM）的能力有限，许多先天性或获得性颅面外伤患者需要填充性移植物材料来支持面部结构，恢复功能，提高自信心，恢复社交。超声波能够刺激压电材料，将机械能转化为电信号，调节软骨细胞的代谢、增殖和分化。这种独特的特性引起了人们对在再生医学中使用压电生物材料的兴趣。在这篇综述中，我们首先解释了超声激活压电材料的原理以及它们如何产生压电。然后，我们回顾了证明这种生物电如何促进软骨细胞再生，刺激关键细胞外成分的分泌，并通过激活相关信号通路支持软骨再生的研究。接下来，我们讨论了各种压电生物材料的性质、合成和改性策略。我们进一步讨论了专门用于软骨再生的超声激活压电生物材料的最新进展。最后，讨论了超声活化压电材料在软骨再生工程中的应用前景。虽然这项技术前景广阔，但仍存在一些障碍，包括材料稳定性、超声参数的精确控制以及将这些系统整合到临床环境中。超声波压电技术与其他新兴领域的结合，如人工智能（AI）和软骨类器官芯片，可能会开辟再生医学的新领域。我们希望这篇综述能够鼓励进一步探索压电材料的超声激活策略及其在再生医学中的未来应用。

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来源期刊

Ultrasonics Sonochemistry 化学-化学综合

CiteScore

15.80

自引率

11.90%

发文量

361

审稿时长

59 days

期刊介绍： Ultrasonics Sonochemistry stands as a premier international journal dedicated to the publication of high-quality research articles primarily focusing on chemical reactions and reactors induced by ultrasonic waves, known as sonochemistry. Beyond chemical reactions, the journal also welcomes contributions related to cavitation-induced events and processing, including sonoluminescence, and the transformation of materials on chemical, physical, and biological levels. Since its inception in 1994, Ultrasonics Sonochemistry has consistently maintained a top ranking in the "Acoustics" category, reflecting its esteemed reputation in the field. The journal publishes exceptional papers covering various areas of ultrasonics and sonochemistry. Its contributions are highly regarded by both academia and industry stakeholders, demonstrating its relevance and impact in advancing research and innovation.