Bone Marrow Mesenchymal Stem Cells Expanded Inside the Nichoid Micro-Scaffold: a Focus on Anti-Inflammatory Response.

IF 2.2 Q3 ENGINEERING, BIOMEDICAL Regenerative Engineering and Translational Medicine Pub Date : 2023-03-20 DOI:10.1007/s40883-023-00296-z
Bianca Barzaghini, Stephana Carelli, Letizia Messa, Federica Rey, Maria Antonietta Avanzini, Emanuela Jacchetti, Erika Maghraby, Clarissa Berardo, Gianvincenzo Zuccotti, Manuela Teresa Raimondi, Cristina Cereda, Valeria Calcaterra, Gloria Pelizzo
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引用次数: 1

Abstract

Purpose: Mesenchymal stem cells (MSCs) represent a promising source for stem cell therapies in numerous diseases, including pediatric respiratory system diseases. Characterized by low immunogenicity, high anti-inflammatory, and immunoregulatory features, MSCs demonstrated an excellent therapeutic profile in numerous in vitro and preclinical models. MSCs reside in a specialized physiologic microenvironment, characterized by a unique combination of biophysical, biochemical, and cellular properties. The exploitation of the 3D micro-scaffold Nichoid, which simulates the native niche, enhanced the anti-inflammatory potential of stem cells through mechanical stimulation only, overcoming the limitation of biochemical and xenogenic growth factors application.

Materials and methods: In this work, we expanded pediatric bone marrow MSCs (BM-MSCs) inside the Nichoid and performed a complete cellular characterization with different approaches including viability assays, immunofluorescence analyses, RNA sequencing, and gene expression analysis.

Results: We demonstrated that BM-MSCs inside the scaffold remain in a stem cell quiescent state mimicking the condition of the in vivo environment. Moreover, the gene expression profile of these cells shows a significant up-regulation of genes involved in immune response when compared with the flat control.

Conclusion: The significant changes in the expression profile of anti-inflammatory genes could potentiate the therapeutic effect of BM-MSCs, encouraging the possible clinical translation for the treatment of pediatric congenital and acquired pulmonary disorders, including post-COVID lung manifestations.

Lay summary: Regenerative medicine is the research field integrating medicine, biology, and biomedical engineering. In this context, stem cells, which are a fundamental cell source able to regenerate tissues and restore damage in the body, are the key component for a regenerative therapeutic approach. When expanded outside the body, stem cells tend to differentiate spontaneously and lose regenerative potential due to external stimuli. For this reason, we exploit the scaffold named Nichoid, which mimics the in vivo cell niche architecture. In this scaffold, mesenchymal stem cells "feel at home" due to the three-dimensional mechanical stimuli, and our findings could be considered as an innovative culture system for the in vitro expansion of stem cells for clinical translation.

Future perspective: The increasing demand of safe and effective cell therapies projects our findings toward the possibility of improving cell therapies based on the use of BM-MSCs, particularly for their clinical translation in lung diseases.

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骨髓间充质干细胞在软骨微支架内扩增:对抗炎反应的关注。
目的:间充质干细胞(MSCs)是多种疾病(包括儿童呼吸系统疾病)的干细胞治疗的一个有前途的来源。MSCs具有低免疫原性、高抗炎性和免疫调节特性,在许多体外和临床前模型中表现出优异的治疗效果。间充质干细胞位于一个特殊的生理微环境中,其特征是生物物理、生物化学和细胞特性的独特组合。模拟天然生态位的3D微支架Nichoid的开发,仅通过机械刺激就增强了干细胞的抗炎潜力,克服了生物化学和异种生长因子应用的限制。材料和方法:在这项工作中,我们在Nichoid内扩增了儿童骨髓间充质干细胞(BM-MSCs),并用不同的方法进行了完整的细胞表征,包括活力测定、免疫荧光分析、RNA测序和基因表达分析。结果:我们证明支架内的骨髓间充质干细胞保持在模拟体内环境条件的干细胞静止状态。此外,与平面对照相比,这些细胞的基因表达谱显示参与免疫反应的基因显著上调。结论:抗炎基因表达谱的显著变化可以增强骨髓间充质干细胞的治疗效果,为治疗儿童先天性和获得性肺部疾病(包括新冠肺炎后肺部表现)提供可能的临床转化。概述:再生医学是集医学、生物学和生物医学工程于一体的研究领域。在这种情况下,干细胞是能够再生组织和恢复体内损伤的基本细胞来源,是再生治疗方法的关键组成部分。当干细胞在体外扩增时,由于外部刺激,干细胞往往会自发分化并失去再生潜力。出于这个原因,我们开发了名为Nichoid的支架,它模仿了体内细胞的生态位结构。在这种支架中,由于三维机械刺激,间充质干细胞“感觉宾至如归”,我们的发现可以被认为是一种创新的培养系统,用于干细胞的体外扩增以进行临床翻译。未来展望:对安全有效的细胞疗法的需求不断增加,这使我们的发现有可能在使用骨髓间充质干细胞的基础上改进细胞疗法,特别是在肺部疾病中的临床转化。图形摘要:
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来源期刊
CiteScore
4.90
自引率
11.50%
发文量
41
期刊介绍: Regenerative Engineering is an international journal covering convergence of the disciplines of tissue engineering, advanced materials science, stem cell research, the physical sciences, and areas of developmental biology. This convergence brings exciting opportunities to translate bench-top research into bedside methods, allowing the possibility of moving beyond maintaining or repairing tissues to regenerating them. The journal encourages both top-down engineering approaches and bottom-up strategies integrating materials science with stem cell research and developmental biology. Convergence papers on instructive biomaterials, stimuli-responsive biomaterials, micro- and nano-patterning for regenerative engineering, elastomeric biomaterials, hydrogels for tissue engineering, and rapid prototyping and bioprinting approaches are particularly welcome. The journal provides a premier, single-blind peer-reviewed forum for the publication of original papers, authoritative reviews, rapid communications, news and views, and opinion papers addressing the most important issues and efforts toward successfully regenerating complex human tissues and organs. All research articles feature a lay abstract highlighting the relevance and future impact for patients, government and other health officials, and members of the general public. Bridging the gap between the lab and the clinic, the journal also serves as a dedicated platform for showcasing translational research that brings basic scientific research and discoveries into clinical methods and therapies, contributing to the improvement of human health care. Topics covered in Regenerative Engineering and Translational Medicine include: Advanced materials science for regenerative and biomedical applicationsStem cells for tissue regenerationDrug delivery for tissue regenerationNanomaterials and nanobiotechnology for tissue regenerationStudies combining tissue engineering/regeneration with developmental biologyConvergence research in pre-clinical and clinical phases
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