The effect of Klotho protein complexed with nanomaterials on bone mesenchymal stem cell performance in the treatment of diabetic ischaemic ulcer

IF 3.8 4区 工程技术 Q1 BIOCHEMICAL RESEARCH METHODS IET nanobiotechnology Pub Date : 2022-09-26 DOI:10.1049/nbt2.12099
Rui Tang, Gang Zhao, Yuqiao Wang, Ruixue Zhang
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引用次数: 1

Abstract

A lack of angiogenesis is the key problem in the healing of diabetic foot ulcers. Stem cells have already been proven to have a high potential for angiogenesis. The most important aspects of stem cell therapy are improving the microenvironment, cell homing and continuous factor stimulation. We investigated the effect of Klotho protein to heal wounds by promoting the proliferation and migration of bone mesenchymal stem cells and endothelial cells in vitro. Based on the above study, we produced a compound material by using poly(lactic-co-glycolic acid) (PLGA), chitosan microspheres and gelatin through electro spining technology. The structure of the compound material, just like a sandwich, is that two pieces of PLGA nanofiber films clamped gelatin film which contained chitosan microspheres. In the in vitro release experiment, we could detect the release of Klotho after seven days in the compound material, but the release time was approximately 40 hours for the chitosan microspheres. After seeded bone mesenchymal stem cells (BMSCs) on the surface of the compound material, we observed morphologies of the chitosan microsphere, the PLGA nanofiber and BMSCs by scanning electron microscopy. The nanofiber mesh biological tissue materials could supply an appropriate microenvironment and cell factors for the survival of BMSCs. Compared with the control group, the biological tissue material seeded with BMSCs significantly promoted angiogenesis in the lower limb of diabetic C57BL/6J mice and accelerated diabetic foot wound healing. The compound biomaterial which could continuously stimulate BMSCs through releasing Klotho protein could accelerate wound healing in the diabetic foot and other ischemic ulcers.

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Klotho蛋白复合纳米材料对骨间充质干细胞在糖尿病缺血性溃疡治疗中的作用
血管生成的缺乏是糖尿病足溃疡愈合的关键问题。干细胞已经被证明在血管生成方面具有很高的潜力。干细胞治疗最重要的方面是改善微环境、细胞归巢和持续因子刺激。我们在体外研究了Klotho蛋白通过促进骨间充质干细胞和内皮细胞的增殖和迁移来促进伤口愈合的作用。在此基础上,采用电纺丝技术,以聚乳酸-羟基乙酸(PLGA)、壳聚糖微球和明胶为原料制备了复合材料。这种复合材料的结构就像三明治一样,两片聚乳酸纳米纤维薄膜夹住了含有壳聚糖微球的明胶薄膜。体外释放实验表明,壳聚糖微球的释放时间约为40小时,而Klotho的释放时间约为7 d。将骨间充质干细胞(BMSCs)植入复合材料表面后,通过扫描电镜观察壳聚糖微球、PLGA纳米纤维和BMSCs的形态。纳米纤维网状生物组织材料可为骨髓间充质干细胞的存活提供适宜的微环境和细胞因子。与对照组相比,植入BMSCs的生物组织材料显著促进糖尿病C57BL/6J小鼠下肢血管生成,加速糖尿病足创面愈合。该复合生物材料通过释放Klotho蛋白持续刺激骨髓间充质干细胞,可促进糖尿病足及其他缺血性溃疡的创面愈合。
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来源期刊
IET nanobiotechnology
IET nanobiotechnology 工程技术-纳米科技
CiteScore
6.20
自引率
4.30%
发文量
34
审稿时长
1 months
期刊介绍: Electrical and electronic engineers have a long and illustrious history of contributing new theories and technologies to the biomedical sciences. This includes the cable theory for understanding the transmission of electrical signals in nerve axons and muscle fibres; dielectric techniques that advanced the understanding of cell membrane structures and membrane ion channels; electron and atomic force microscopy for investigating cells at the molecular level. Other engineering disciplines, along with contributions from the biological, chemical, materials and physical sciences, continue to provide groundbreaking contributions to this subject at the molecular and submolecular level. Our subject now extends from single molecule measurements using scanning probe techniques, through to interactions between cells and microstructures, micro- and nano-fluidics, and aspects of lab-on-chip technologies. The primary aim of IET Nanobiotechnology is to provide a vital resource for academic and industrial researchers operating in this exciting cross-disciplinary activity. We can only achieve this by publishing cutting edge research papers and expert review articles from the international engineering and scientific community. To attract such contributions we will exercise a commitment to our authors by ensuring that their manuscripts receive rapid constructive peer opinions and feedback across interdisciplinary boundaries. IET Nanobiotechnology covers all aspects of research and emerging technologies including, but not limited to: Fundamental theories and concepts applied to biomedical-related devices and methods at the micro- and nano-scale (including methods that employ electrokinetic, electrohydrodynamic, and optical trapping techniques) Micromachining and microfabrication tools and techniques applied to the top-down approach to nanobiotechnology Nanomachining and nanofabrication tools and techniques directed towards biomedical and biotechnological applications (e.g. applications of atomic force microscopy, scanning probe microscopy and related tools) Colloid chemistry applied to nanobiotechnology (e.g. cosmetics, suntan lotions, bio-active nanoparticles) Biosynthesis (also known as green synthesis) of nanoparticles; to be considered for publication, research papers in this area must be directed principally towards biomedical research and especially if they encompass in vivo models or proofs of concept. We welcome papers that are application-orientated or offer new concepts of substantial biomedical importance Techniques for probing cell physiology, cell adhesion sites and cell-cell communication Molecular self-assembly, including concepts of supramolecular chemistry, molecular recognition, and DNA nanotechnology Societal issues such as health and the environment Special issues. Call for papers: Smart Nanobiosensors for Next-generation Biomedical Applications - https://digital-library.theiet.org/files/IET_NBT_CFP_SNNBA.pdf Selected extended papers from the International conference of the 19th Asian BioCeramic Symposium - https://digital-library.theiet.org/files/IET_NBT_CFP_ABS.pdf
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