Ionic medicine: Exploiting metallic ions to stimulate skeletal muscle tissue regeneration

IF 9.4 1区 医学 Q1 ENGINEERING, BIOMEDICAL
Hsuan-Heng Lu , Duygu Ege , Sahar Salehi , Aldo R. Boccaccini
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引用次数: 0

Abstract

The regeneration of healthy and functional skeletal muscle at sites of injuries and defects remains a challenge. Mimicking the natural environment surrounding skeletal muscle cells and the application of electrical and mechanical stimuli are approaches being investigated to promote muscle tissue regeneration. Likewise, chemical stimulation with therapeutic (biologically active) ions is an emerging attractive alternative in the tissue engineering and regenerative medicine fields, specifically to trigger myoblast proliferation, myogenic differentiation, myofiber formation, and ultimately to promote new muscle tissue growth. The present review covers the specialized literature focusing on the biochemical stimulation of muscle tissue repair by applying inorganic ions (bioinorganics). Extracting information from the literature, different ions and their potential influence as chemical cues on skeletal muscle regeneration are discussed. It is revealed that different ions and their varied doses have an individual effect at different stages of muscle cellular development. The dose-dependent effects of ions, as well as applications of ions alone and in combination with biomaterials, are also summarized. Some ions, such as boron, silicon, magnesium, selenium and zinc, are reported to exhibit a beneficial effect on skeletal muscle cells in carefully controlled doses, while the effects of other ions such as iron and copper appear to be contradictory. In addition, calcium is an essential regulatory ion for the differentiation of myoblasts. On the other hand, some ions such as phosphate have been shown to inhibit muscle cell behavior. This review thus provides a complete overview of the application of ionic stimulation for skeletal muscle tissue engineering applications, highlighting the importance of inorganic ions as an attractive alternative to the application of small molecules and growth factors to stimulate muscle tissue repair.

Statement of significance

Ionic medicine (IM) is emerging as a promising and attractive approach in the field of tissue engineering, including muscle tissue regeneration. IM is based on the delivery of biologically active ions to injury sites, acting as stimulants for the repair process. This method offers a potentially simpler and more affordable alternative to conventional biomolecule-based regulators such as growth factors. Different biologically active ions, depending on their specific doping concentrations, can have varying effects on cellular development, which could be either beneficial or inhibitory. This literature review covers the field of IM in muscle regeneration with focus on the impact of various ions on skeletal muscle regeneration. The paper is thus a critical summary for guiding future research in ionic-related regenerative medicine, highlighting the potential and challenges of this approach for muscle regeneration.

Abstract Image

离子医学:利用金属离子刺激骨骼肌组织再生。
在受伤和缺损部位再生健康和功能性骨骼肌仍然是一项挑战。模拟骨骼肌细胞周围的自然环境以及应用电刺激和机械刺激是目前正在研究的促进肌肉组织再生的方法。同样,在组织工程和再生医学领域,用治疗性(生物活性)离子进行化学刺激也是一种新兴的有吸引力的替代方法,特别是能引发成肌细胞增殖、成肌分化、肌纤维形成,并最终促进新的肌肉组织生长。本综述涵盖了有关应用无机离子(生物无机物)生化刺激肌肉组织修复的专业文献。通过从文献中提取信息,讨论了不同离子及其作为化学线索对骨骼肌再生的潜在影响。研究发现,不同的离子及其不同的剂量会在肌肉细胞发育的不同阶段产生不同的影响。此外,还总结了离子的剂量依赖效应以及离子单独或与生物材料结合的应用。据报道,一些离子,如硼、硅、镁和锌,在严格控制剂量的情况下对骨骼肌细胞产生有益影响,而其他离子,如铁和铜的影响似乎相互矛盾。此外,钙是肌母细胞分化过程中必不可少的调节离子。另一方面,一些离子(如磷酸盐)已被证明会抑制肌肉细胞的行为。预计本综述将全面概述离子刺激在骨骼肌组织工程中的应用,并将强调无机离子作为小分子和生长因子刺激肌肉组织修复应用的一种有吸引力的替代方法的重要性。意义说明:在组织工程(包括肌肉组织再生)领域,离子医学(IM)正在成为一种前景广阔、极具吸引力的方法。离子医学的基础是将具有生物活性的离子输送到受伤部位,作为修复过程的刺激剂。与传统的生物大分子调节剂(如生长因子)相比,这种方法可能更简单、更经济。不同的生物活性离子,根据其特定的掺杂浓度,可对细胞发育产生不同的影响,这些影响可能是有益的,也可能是抑制性的。这篇文献综述涉及肌肉再生中的 IM 领域,重点是各种离子对骨骼肌再生的影响。因此,本文是指导离子相关再生医学未来研究的重要总结,强调了这种方法在肌肉再生方面的潜力和挑战。
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来源期刊
Acta Biomaterialia
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.
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