使用维甲酸释放间充质干细胞支架诱导巨噬细胞M1到M2。

IF 1 4区 医学 Q4 ENGINEERING, BIOMEDICAL
Kaivon D Assani, Nasim Nosoudi, Jaime E Ramirez-Vick, Surinder P Singh
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引用次数: 3

摘要

背景:巨噬细胞极化的调节是有效的组织修复和再生治疗所必需的。治疗性调节巨噬细胞从炎性M1表型到纤维化M2表型可能有助于治疗疾病,如慢性伤口,这些疾病在伤口愈合过程中停滞在延长和加剧的炎症阶段。目的:本研究评估负载维甲酸(RA)和脂肪源性间充质干细胞(ASCs)的普鲁兰/明胶纳米纤维支架调节M1到M2抗炎转化的效率。方法:采用静电纺丝法制备支架,并用乙二醇二缩水甘油醚(EGDE)交联。将RA和/或ASCs暴露于培养的巨噬细胞中可以促进M1向M2的转变。普鲁兰之所以被选为支架材料,是因为它具有猝灭活性氧的能力,活性氧是在炎症进展中起重要作用的关键信号分子,而且它具有优异的机械性能。由于存在细胞结合基序及其生物相容性,明胶被选为额外的支架成分。支架组成为75:25和50:50,普鲁兰:明胶。以1:70和1:50 EGDE:EtOH交联支架。通过FTIR测定支架的组成。在本研究中,我们选择75:25的蒲鲁兰:明胶与1:70的EGDE:EtOH交联,形成直径328±47.9 nm(平均±SD)的纳米纤维作为支架组合物,因为它的降解和释放速度较低,可以持续递送RA。结果:支架成分在14天后降解至约80%,7天后约有38%的药物释放。通过脂多糖(LPS)和γ干扰素(IFN-γ)刺激,THP-1单核细胞被诱导成M1巨噬细胞表型。将这些M1巨噬细胞暴露于装载RA和ASCs的支架中,诱导其分化为M2表型。结论:qPCR基因表达定量显示,暴露2天后,M1生物标志物、肿瘤坏死因子α (TNFα)和白细胞介素1β (il - 1β)降低,M2生物标志物CCL22升高,M1向M2成功转化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
M1 to M2 induction in macrophages using a retinoic acid-releasing mesenchymal stem cell scaffold.

Background: Modulation of macrophage polarization is required for effective tissue repair and regenerative therapies. Therapeutic modulation of macrophages from an inflammatory M1 to a fibrotic M2 phenotype could help in diseases, such as chronic wounds, which are stalled in a prolonged and heightened inflammatory stage within the wound healing process.

Objective: This study evaluates the efficiency of a pullulan/gelatin nanofiber scaffold loaded with retinoic acid (RA) and adipose-derived mesenchymal stem cells (ASCs) to modulate M1 to M2 anti-inflammatory transition.

Methods: Scaffolds were fabricated by electrospinning, and crosslinked using ethylene glycol diglycidyl ether (EGDE). Exposure of RA and/or ASCs to cultured macrophages have been shown to promote M1 to M2 transition. Pullulan was chosen as a scaffold material due to its ability to quench reactive oxygen species, key signaling molecules that play an important role in the progression of inflammation, as well as for its excellent mechanical properties. Gelatin was chosen as an additional scaffold component due to the presence of cell-binding motifs and its biocompatibility. Scaffold compositions examined were 75:25 and 50:50, pullulan:gelatin. The scaffolds were crosslinked in 1:70 and 1:50 EGDE:EtOH. The scaffold composition was determined via FTIR. For the present study, the 75:25 pullulan:gelatin crosslinked with 1:70 EGDE:EtOH, forming nanofibers 328 ± 47.9 nm (mean ± SD) in diameter, was chosen as the scaffold composition due to its lower degradation and release rate, which allows a sustained delivery of RA.

Results: The scaffold composition degraded to approximately 80% after 14 days, with approximately 38% of the drug released after 7 days. THP-1 monocytic cells were induced into a M1 macrophage phenotype through stimulation with lipopolysaccharide (LPS) and gamma interferon (IFN-γ). These M1 macrophages were the exposed to scaffolds loaded with RA and ASCs, to induce differentiation to an M2 phenotype.

Conclusion: Gene expression quantitation by qPCR showed a reduction of M1 biomarkers, tumor necrosis factor alpha (TNFα) and interleukin 1β (IL1β), and an increase of M2 biomarker CCL22 after 2 days of exposure, suggesting successful M1 to M2 transition.

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来源期刊
Bio-medical materials and engineering
Bio-medical materials and engineering 工程技术-材料科学:生物材料
CiteScore
1.80
自引率
0.00%
发文量
73
审稿时长
6 months
期刊介绍: The aim of Bio-Medical Materials and Engineering is to promote the welfare of humans and to help them keep healthy. This international journal is an interdisciplinary journal that publishes original research papers, review articles and brief notes on materials and engineering for biological and medical systems. Articles in this peer-reviewed journal cover a wide range of topics, including, but not limited to: Engineering as applied to improving diagnosis, therapy, and prevention of disease and injury, and better substitutes for damaged or disabled human organs; Studies of biomaterial interactions with the human body, bio-compatibility, interfacial and interaction problems; Biomechanical behavior under biological and/or medical conditions; Mechanical and biological properties of membrane biomaterials; Cellular and tissue engineering, physiological, biophysical, biochemical bioengineering aspects; Implant failure fields and degradation of implants. Biomimetics engineering and materials including system analysis as supporter for aged people and as rehabilitation; Bioengineering and materials technology as applied to the decontamination against environmental problems; Biosensors, bioreactors, bioprocess instrumentation and control system; Application to food engineering; Standardization problems on biomaterials and related products; Assessment of reliability and safety of biomedical materials and man-machine systems; and Product liability of biomaterials and related products.
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