Glia in tissue engineering: From biomaterial tools to transplantation

IF 9.4 1区 医学 Q1 ENGINEERING, BIOMEDICAL Acta Biomaterialia Pub Date : 2024-12-01 DOI:10.1016/j.actbio.2024.10.017
AS Dill-Macky , EN Lee , JA Wertheim , KM Koss
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Abstract

Glia are imperative in nearly every function of the nervous system, including neurotransmission, neuronal repair, development, immunity, and myelination. Recently, the reparative roles of glia in the central and peripheral nervous systems have been elucidated, suggesting a tremendous potential for these cells as novel treatments to central nervous system disorders. Glial cells often behave as ‘double-edged swords’ in neuroinflammation, ultimately deciding the life or death of resident cells. Compared to glia, neuronal cells have limited mobility, lack the ability to divide and self-renew, and are generally more delicate. Glia have been candidates for therapeutic use in many successful grafting studies, which have been largely focused on restoring myelin with Schwann cells, olfactory ensheathing glia, and oligodendrocytes with support from astrocytes. However, few therapeutics of this class have succeeded past clinical trials. Several tools and materials are being developed to understand and re-engineer these grafting concepts for greater success, such as extra cellular matrix-based scaffolds, bioactive peptides, biomolecular delivery systems, biomolecular discovery for neuroinflammatory mediation, composite microstructures such as artificial channels for cell trafficking, and graft enhanced electrical stimulation. Furthermore, advances in stem cell-derived cortical/cerebral organoid differentiation protocols have allowed for the generation of patient-derived glia comparable to those acquired from tissues requiring highly invasive procedures or are otherwise inaccessible. However, research on bioengineered tools that manipulate glial cells is nowhere near as comprehensive as that for systems of neurons and neural stem cells. This article explores the therapeutic potential of glia in transplantation with an emphasis on novel bioengineered tools for enhancement of their reparative properties.

Statement of significance

Neural glia are responsible for a host of developmental, homeostatic, and reparative roles in the central nervous system but are often a major cause of tissue damage and cellular loss in insults and degenerative pathologies. Most glial grafts have employed Schwann cells for remyelination, but other glial with novel biomaterials have been employed, emphasizing their diverse functionality. Promising strategies have emerged, including neuroimmune mediation of glial scar tissues and facilitated migration and differentiation of stem cells for neural replacement. Herein, a comprehensive review of biomaterial tools for glia in transplantation is presented, highlighting Schwann cells, astrocytes, olfactory ensheating glia, oligodendrocytes, microglia, and ependymal cells.

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组织工程中的胶质细胞:从生物材料工具到移植。
神经胶质细胞对神经系统的几乎所有功能都至关重要,包括神经传递、神经元修复、发育、免疫和髓鞘化。最近,神经胶质细胞在中枢神经系统和周围神经系统中的修复作用得到了阐明,这表明这些细胞在治疗中枢神经系统疾病方面具有巨大的潜力。神经胶质细胞在神经炎症中往往是一把 "双刃剑",最终决定着驻留细胞的生死。与胶质细胞相比,神经元细胞的活动能力有限,缺乏分裂和自我更新能力,而且通常更为脆弱。在许多成功的移植研究中,胶质细胞一直是候选治疗药物,这些研究主要集中在利用许旺细胞、嗅觉鞘胶质细胞和少突胶质细胞在星形胶质细胞的支持下恢复髓鞘。然而,此类疗法在临床试验中鲜有成功案例。目前正在开发几种工具和材料,以了解和重新设计这些移植概念,取得更大的成功,如基于细胞外基质的支架、生物活性肽、生物分子输送系统、用于神经炎症调解的生物分子发现、复合微结构(如用于细胞贩运的人工通道)和移植增强电刺激。此外,干细胞衍生皮质/大脑类器官分化方案的进步,使病人衍生胶质细胞的生成与需要高创手术或无法获得的组织中的胶质细胞相媲美。然而,对操纵胶质细胞的生物工程工具的研究远不如对神经元和神经干细胞系统的研究全面。本文探讨了神经胶质细胞在移植中的治疗潜力,重点是增强其修复特性的新型生物工程工具。意义说明:神经胶质细胞在中枢神经系统中起着一系列发育、平衡和修复作用,但在损伤和退行性病变中往往是组织损伤和细胞丢失的主要原因。大多数神经胶质移植物都采用许旺细胞进行髓鞘再形成,但也采用了其他神经胶质和新型生物材料,强调它们的不同功能。已经出现了一些很有前景的策略,包括神经免疫调解胶质瘢痕组织和促进干细胞迁移和分化以替代神经。本文全面综述了神经胶质细胞移植的生物材料工具,重点介绍了许旺细胞、星形胶质细胞、嗅鞘胶质细胞、少突胶质细胞、小胶质细胞和上皮细胞。
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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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