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2
Chimeric Self-assembling Nanofiber Containing Bone Marrow Homing Peptide's Motif Induces Motor Neuron Recovery in Animal Model of Chronic Spinal Cord Injury; an In Vitro and In Vivo Investigation.含骨髓归巢肽基序的嵌合自组装纳米纤维在慢性脊髓损伤动物模型中诱导运动神经元恢复:一项体外和体内研究。
Mol Neurobiol. 2016 Jul;53(5):3298-3308. doi: 10.1007/s12035-015-9266-3. Epub 2015 Jun 11.
3
Functionalized self-assembling peptide improves INS-1 β-cell function and proliferation via the integrin/FAK/ERK/cyclin pathway.功能化自组装肽通过整合素/黏着斑激酶/细胞外信号调节激酶/细胞周期蛋白途径改善INS-1β细胞功能和增殖。
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4
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Biomaterials. 2014 Jul;35(20):5316-5326. doi: 10.1016/j.biomaterials.2014.03.035. Epub 2014 Apr 6.
5
Differential regulation of morphology and stemness of mouse embryonic stem cells by substrate stiffness and topography.基质硬度和形貌对小鼠胚胎干细胞形态和干性的差异调控。
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6
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Differential regulation of stiffness, topography, and dimension of substrates in rat mesenchymal stem cells.大鼠间充质干细胞中基质硬度、形貌和维度的差异调节。
Biomaterials. 2013 Oct;34(31):7616-25. doi: 10.1016/j.biomaterials.2013.06.059. Epub 2013 Jul 14.
9
Neural stem cells encapsulated in a functionalized self-assembling peptide hydrogel for brain tissue engineering.神经干细胞包被于功能化自组装肽水凝胶用于脑组织工程。
Biomaterials. 2013 Mar;34(8):2005-16. doi: 10.1016/j.biomaterials.2012.11.043. Epub 2012 Dec 11.
10
Stem cell response to spatially and temporally displayed and reversible surface topography.干细胞对空间和时间显示以及可逆表面形貌的反应。
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工程化具有特定功能基序的自组装亮氨酸拉链水凝胶系统用于组织再生。

Engineering a Self-Assembling Leucine Zipper Hydrogel System with Function-Specific Motifs for Tissue Regeneration.

机构信息

Brodie Tooth Development Genetics & Regenerative Medicine Research Laboratory Department of Oral Biology, University of Illinois at Chicago, 801 South Paulina Street, Room 561C, Chicago, Illinois 60612, United States.

出版信息

ACS Biomater Sci Eng. 2020 May 11;6(5):2913-2928. doi: 10.1021/acsbiomaterials.0c00026. Epub 2020 Apr 7.

DOI:10.1021/acsbiomaterials.0c00026
PMID:33463282
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8080846/
Abstract

Protein-based self-assembling hydrogels can exhibit remarkably tunable properties as a scaffold for regenerative medicine applications. In this study, we sought to develop a leucine zipper (LZ) based self-assembling hydrogel with function-specific motifs for tissue-specific regeneration. As a proof-of-concept approach, we incorporated (a) calcium-binding domains ESQES and QESQSEQS derived from dentin matrix protein 1 (DMP1) and (b) an heparin-binding domain adjacent preceded by an MMP2 (matrix metalloprotease 2) cleavage site to facilitate loading of heparin binding growth factors, such as BMP-2, VEGF, and TGF-β1, and their release in vivo by endogenous MMP2 proteolytic cleavage. These scaffolds were characterized and evaluated in vitro and in vivo. In vivo studies highlighted the potential of the engineered LZ hydrogel with respect to osteogenic differentiation of stem cells. The premineralized LZ scaffold loaded with HMSCs showed an enhanced osteoinductive property when compared with the control nonmineralized scaffold. The LZ backbone with heparin-binding domain containing an MMP2 cleavage site facilitated tethering of heparin-binding growth factors, such as VEGF, TGF-β1 and BMP2 and demonstrated controlled release of these active growth factor both in vitro and in vivo and demonstrated growth factor specific activity in vivo (BMP-2 and TGF-β1). Overall, we present a versatile protein based self-assembling system with tunable properties for tissue regeneration.

摘要

基于蛋白质的自组装水凝胶可以作为再生医学应用的支架,表现出显著可调的特性。在这项研究中,我们试图开发一种基于亮氨酸拉链(LZ)的自组装水凝胶,该水凝胶具有特定于组织的再生功能的基序。作为一种概念验证方法,我们将(a)来源于牙本质基质蛋白 1(DMP1)的钙结合结构域 ESQES 和 QESQSEQS,以及(b)紧邻基质金属蛋白酶 2(MMP2)切割位点的肝素结合结构域掺入其中,以促进肝素结合生长因子(如 BMP-2、VEGF 和 TGF-β1)的负载,并通过内源性 MMP2 蛋白水解切割在体内释放。这些支架在体外和体内进行了表征和评估。体内研究突出了工程化 LZ 水凝胶在干细胞成骨分化方面的潜力。与对照非矿化支架相比,负载 HMSC 的预矿化 LZ 支架显示出增强的成骨诱导特性。含有 MMP2 切割位点的肝素结合结构域的 LZ 骨架便于肝素结合生长因子(如 VEGF、TGF-β1 和 BMP2)的固定,并在体外和体内均表现出这些活性生长因子的受控释放,并在体内表现出生长因子的特定活性(BMP-2 和 TGF-β1)。总体而言,我们提出了一种具有可调特性的多功能基于蛋白质的自组装系统,用于组织再生。

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