Modulating biomechanical and integrating biochemical cues to foster adaptive remodeling of tissue engineered matrices for cardiovascular implants

IF 9.4 1区医学 Q1 ENGINEERING, BIOMEDICAL

Acta Biomaterialia Pub Date : 2025-03-19 DOI:10.1016/j.actbio.2025.03.036

Pascal Breitenstein , Valery L. Visser , Sarah E. Motta , Marcy Martin , Melanie Generali , Frank P.T. Baaijens , Sandra Loerakker , Christopher K. Breuer , Simon P. Hoerstrup , Maximilian Y. Emmert

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Abstract

Cardiovascular disease remains one of the leading causes of mortality in the Western world. Congenital heart disease affects nearly 1 % of newborns, with approximately one-fourth requiring reconstructive surgery during their lifetime. Current cardiovascular replacement options have significant limitations. Their inability to grow poses particular challenges for pediatric patients. Tissue Engineered Matrix (TEM)-based in situ constructs, with their self-repair and growth potential, offer a promising solution to overcome the limitations of current clinically used replacement options. Various functionalization strategies, involving the integration of biomechanical or biochemical components to enhance biocompatibility, have been developed for Tissue Engineered Vascular Grafts (TEVG) and Tissue Engineered Heart Valves (TEHV) to foster their capacity for in vivo remodeling. In this review, we present the current state of clinical translation for TEVG and TEHV, and provide a comprehensive overview of biomechanical and biochemical functionalization strategies for TEVG and TEHV. We discuss the rationale for functionalization, the implementation of functionalization cues in TEM-based TEVG and TEHV, and the interrelatedness of biomechanical and biochemical cues in the in vivo response. Finally, we address the challenges associated with functionalization and discuss how interdisciplinary research, especially when combined with in silico models, could enhance the translation of these strategies into clinical applications.

Statement of significance

Cardiovascular disease remains one of the leading causes of mortality, with current replacements being unable to grow and regenerate. In this review, we present the current state of clinical translation for tissue engineered vascular grafts (TEVG) and heart valves (TEHV). Particularly, we discuss the rationale and implementation for functionalization cues in tissue engineered matrix-based TEVGs and TEHVs, and for the first time we introduce the interrelatedness of biomechanical and biochemical cues in the in-vivo response. These insights pave the way for next-generation cardiovascular implants that promise better durability, biocompatibility, and growth potential. Finally, we address the challenges associated with functionalization and discuss how interdisciplinary research, especially when combined with in silico models, could enhance the translation of these strategies into clinical applications .

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调节生物力学并整合生物化学线索，促进心血管植入物组织工程基质的适应性重塑。

心血管疾病仍然是西方世界死亡的主要原因之一。先天性心脏病影响了近1%的新生儿，其中约四分之一的人一生中需要进行重建手术。目前的心血管替代方案有明显的局限性。它们无法生长对儿科患者构成了特别的挑战。基于组织工程基质（TEM）的原位结构具有自我修复和生长潜力，为克服目前临床使用的替代方案的局限性提供了一个有希望的解决方案。组织工程血管移植物（TEVG）和组织工程心脏瓣膜（TEHV）的各种功能化策略，包括整合生物力学或生化成分来增强生物相容性，已经被开发出来，以培养它们在体内重塑的能力。在这篇综述中，我们介绍了TEVG和TEHV的临床翻译现状，并提供了TEVG和TEHV的生物力学和生化功能化策略的全面概述。我们讨论了功能化的基本原理，功能化线索在TEM-based TEVG和tev中的实现，以及生物力学和生化线索在体内反应中的相互关系。最后，我们讨论了与功能化相关的挑战，并讨论了跨学科研究，特别是与计算机模型相结合时，如何加强这些策略在临床应用中的转化。意义说明：心血管疾病仍然是导致死亡的主要原因之一，目前的替代品无法生长和再生。在这篇综述中，我们介绍了组织工程血管移植物（TEVG）和心脏瓣膜（TEHV）的临床翻译的现状。特别地，我们讨论了组织工程基质TEVGs和tevv中功能化线索的原理和实现，并首次介绍了生物力学和生化线索在体内反应中的相互关系。这些见解为下一代心血管植入物铺平了道路，这些植入物承诺更好的耐用性、生物相容性和生长潜力。最后，我们讨论了与功能化相关的挑战，并讨论了跨学科研究，特别是与计算机模型相结合时，如何加强这些策略在临床应用中的转化。

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

Acta Biomaterialia 工程技术-材料科学：生物材料

CiteScore

16.80

自引率

3.10%

发文量

776

审稿时长

30 days

期刊介绍： Acta Biomaterialia is a monthly peer-reviewed scientific journal published by Elsevier. The journal was established in January 2005. The editor-in-chief is W.R. Wagner (University of Pittsburgh). The journal covers research in biomaterials science, including the interrelationship of biomaterial structure and function from macroscale to nanoscale. Topical coverage includes biomedical and biocompatible materials.