School of Biochemistry and Immunology, Trinity College Dublin, Dublin, Ireland; Trinity Centre for Bioengineering, Trinity Biomedical Sciences Institute, Trinity College Dublin, Dublin, Ireland; Advanced Materials and Bioengineering Research (AMBER) Centre, Trinity College Dublin, Ireland.
Trinity Centre for Bioengineering, Trinity Biomedical Sciences Institute, Trinity College Dublin, Dublin, Ireland; Department of Mechanical and Manufacturing Engineering, School of Engineering, Trinity College Dublin, Dublin, Ireland; Advanced Materials and Bioengineering Research (AMBER) Centre, Trinity College Dublin, Ireland.
Acta Biomater. 2021 Oct 1;133:208-221. doi: 10.1016/j.actbio.2021.02.023. Epub 2021 Feb 28.
Tissue healing and regeneration is a complex, choreographed, spatiotemporal process involving a plethora of cell types, the activity of which is stringently regulated in order for effective tissue repair to ensue post injury. A number of globally prevalent conditions such as heart disease, organ failure, and severe musculoskeletal disorders require new therapeutic strategies to repair damaged or diseased tissue, particularly given an ageing population in which obesity, diabetes, and consequent tissue defects have reached epidemic proportions. This is further compounded by the lack of intrinsic healing and poor regenerative capacity of certain adult tissues. While vast progress has been made in the last decade regarding tissue regenerative strategies to direct self-healing, for example, through implantation of tissue engineered scaffolds, several challenges have hampered the clinical application of these technologies. Control of the immune response is growing as an attractive approach in regenerative medicine and it is becoming increasingly apparent that an in depth understanding of the interplay between cells of the immune system and tissue specific progenitor cells is of paramount importance. Furthermore, the integration of immunology and bioengineering promises to elevate the efficacy of biomaterial-based tissue repair and regeneration. In this review, we highlight the role played by individual immune cell subsets in tissue repair processes and describe new approaches that are being taken to direct appropriate healing outcomes via biomaterial mediated targeting of immune cell activity. STATEMENT OF SIGNIFICANCE: It is becoming increasingly apparent that controlling the immune response is as an attractive approach in regenerative medicine. Here, we propose that an in-depth understanding of immune system and tissue specific progenitor cell interactions may reveal mechanisms by which tissue healing and regeneration takes place, in addition to identifying novel therapeutic targets that could be used to enhance the tissue repair process. To date, most reviews have focused solely on macrophage subsets. This manuscript details the role of other innate and adaptive immune cells such as innate lymphoid cells (ILCs), natural killer (NK) cells and γδT cells (in addition to macrophages) in tissue healing. We also describe new approaches that are being taken to direct appropriate healing outcomes via biomaterial mediated cytokine and drug delivery.
组织修复和再生是一个复杂的、协调的、时空的过程,涉及到大量的细胞类型,其活动受到严格的调控,以便在受伤后进行有效的组织修复。许多全球性的常见疾病,如心脏病、器官衰竭和严重的肌肉骨骼疾病,都需要新的治疗策略来修复受损或患病的组织,尤其是在人口老龄化的情况下,肥胖、糖尿病和随之而来的组织缺陷已经达到了流行的程度。此外,某些成年组织缺乏内在的修复和再生能力,这进一步加剧了这种情况。尽管在过去十年中,组织再生策略在指导自我修复方面取得了巨大进展,例如通过植入组织工程支架,但这些技术的临床应用仍面临着许多挑战。控制免疫反应作为再生医学中的一种有吸引力的方法正在不断发展,越来越明显的是,深入了解免疫系统细胞和组织特异性祖细胞之间的相互作用至关重要。此外,免疫学和生物工程的结合有望提高基于生物材料的组织修复和再生的疗效。在这篇综述中,我们强调了单个免疫细胞亚群在组织修复过程中所起的作用,并描述了新的方法,通过生物材料介导的免疫细胞活性靶向来指导适当的愈合结果。
越来越明显的是,控制免疫反应是再生医学中的一种有吸引力的方法。在这里,我们提出,深入了解免疫系统和组织特异性祖细胞的相互作用,除了确定可以用来增强组织修复过程的新治疗靶点外,还可以揭示组织愈合和再生的机制。迄今为止,大多数综述仅集中于巨噬细胞亚群。本文详细介绍了其他先天和适应性免疫细胞,如先天淋巴细胞(ILC)、自然杀伤(NK)细胞和γδT 细胞(除巨噬细胞外)在组织修复中的作用。我们还描述了新的方法,通过生物材料介导的细胞因子和药物递送来指导适当的愈合结果。
