Frank A Petrigliano, Christopher S English, David Barba, Sean Esmende, Benjamin M Wu, David R McAllister
{"title":"局部bFGF释放和单轴应变对三维环境下细胞适应和基因表达的影响:对韧带组织工程的影响。","authors":"Frank A Petrigliano, Christopher S English, David Barba, Sean Esmende, Benjamin M Wu, David R McAllister","doi":"10.1089/ten.2006.0434","DOIUrl":null,"url":null,"abstract":"<p><p>The objectives of this investigation were (1) to characterize the growth factor release profile of a basic fibroblast growth factor (bFGF)-coated three-dimensional (3D) polymer scaffold under static and cyclically strained conditions, and (2) to delineate the individual and collective contributions of locally released bFGF and mechanical strain on cellular morphology and gene expression in this 3D system. Scaffolds were treated with I(125)-bFGF and subjected to mechanical strain or maintained in a static environment and the media sampled for factor release over a period of 6 days. Over the first 10 hours, a burst release of 25% of the incorporated growth factor into the surrounding media was noted. At 24 hours, approximately 40% of the bFGF was released into the media, after which steady state was achieved and minimal subsequent release was noted. Mechanical stimulation had no effect on growth factor release from the scaffold in this system. To test the concerted effects of bFGF and mechanical stimulation on bone marrow stromal cells (BMSCs), scaffolds were loaded with 0, 100, or 500 ng of bFGF, seeded with cells, and subjected to mechanical strain or maintained in a static environment. Scaffolds were harvested at 1, 7, and 21 days for RT-PCR and histomorphometry. All scaffolds subjected to growth factor and/or mechanical stimulation demonstrated cellular adherence and spreading at 21 days. Conversely, in the absence of both bFGF and mechanical stimulation, cells demonstrated minimal cytoplasmic spread. Moreover, at 21 days, cells subjected to both mechanical stimulation and bFGF (500 ng) demonstrated the highest upregulation of stress-resistive (collagen I, III) and stress-responsive proteins (tenascin-C). The effect of growth factor may be dose sensitive, however, as unstrained scaffolds treated with 100 ng of bFGF demonstrated upregulation of gene expression comparable to strained scaffolds treated with lower doses of bFGF (0 or 100 ng). In conclusion, results from this study suggest that the stimulatory effects of bFGF are dose sensitive and appear to be influenced by the addition of mechanical strain. The concurrent application of biochemical and mechanical stimuli may be important in promoting the adaptation of BMSCs and driving the transcription of genes essential for synthesis of a functional ligament replacement tissue.</p>","PeriodicalId":23102,"journal":{"name":"Tissue engineering","volume":"13 11","pages":"2721-31"},"PeriodicalIF":0.0000,"publicationDate":"2007-11-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.1089/ten.2006.0434","citationCount":"52","resultStr":"{\"title\":\"The effects of local bFGF release and uniaxial strain on cellular adaptation and gene expression in a 3D environment: implications for ligament tissue engineering.\",\"authors\":\"Frank A Petrigliano, Christopher S English, David Barba, Sean Esmende, Benjamin M Wu, David R McAllister\",\"doi\":\"10.1089/ten.2006.0434\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>The objectives of this investigation were (1) to characterize the growth factor release profile of a basic fibroblast growth factor (bFGF)-coated three-dimensional (3D) polymer scaffold under static and cyclically strained conditions, and (2) to delineate the individual and collective contributions of locally released bFGF and mechanical strain on cellular morphology and gene expression in this 3D system. 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引用次数: 52
摘要
本研究的目的是:(1)表征碱性成纤维细胞生长因子(bFGF)包被的三维(3D)聚合物支架在静态和循环应变条件下的生长因子释放谱;(2)描述局部释放的bFGF和机械应变对该3D系统中细胞形态和基因表达的个体和集体贡献。支架用I(125)-bFGF处理,在6天内进行机械应变或在静态环境和介质中取样以释放因子。在前10小时内,观察到25%的结合生长因子突然释放到周围介质中。在24小时内,大约40%的bFGF被释放到培养基中,之后达到稳定状态,并且注意到最小的后续释放。机械刺激对支架中生长因子的释放没有影响。为了测试bFGF和机械刺激对骨髓间质细胞(BMSCs)的协同作用,我们在支架上分别加载0、100或500 ng bFGF,然后植入细胞,并施加机械应力或保持在静态环境中。分别于第1、7和21天收获支架,进行RT-PCR和组织形态测定。所有生长因子和/或机械刺激的支架在21天表现出细胞粘附和扩散。相反,在没有bFGF和机械刺激的情况下,细胞表现出最小的细胞质扩散。此外,在第21天,受到机械刺激和bFGF (500 ng)的细胞显示出最高的抗逆性(胶原I, III)和应激反应蛋白(tenascin-C)的上调。然而,生长因子的作用可能是剂量敏感的,因为与低剂量的bFGF(0或100 ng)处理的支架相比,未经拉伸的支架用100 ng bFGF处理显示出基因表达的上调。综上所述,本研究结果表明bFGF的刺激作用是剂量敏感的,并且似乎受到机械应变的影响。在促进骨髓间充质干细胞的适应和驱动合成功能性韧带替代组织所需基因的转录方面,生化和机械刺激的同时应用可能是重要的。
The effects of local bFGF release and uniaxial strain on cellular adaptation and gene expression in a 3D environment: implications for ligament tissue engineering.
The objectives of this investigation were (1) to characterize the growth factor release profile of a basic fibroblast growth factor (bFGF)-coated three-dimensional (3D) polymer scaffold under static and cyclically strained conditions, and (2) to delineate the individual and collective contributions of locally released bFGF and mechanical strain on cellular morphology and gene expression in this 3D system. Scaffolds were treated with I(125)-bFGF and subjected to mechanical strain or maintained in a static environment and the media sampled for factor release over a period of 6 days. Over the first 10 hours, a burst release of 25% of the incorporated growth factor into the surrounding media was noted. At 24 hours, approximately 40% of the bFGF was released into the media, after which steady state was achieved and minimal subsequent release was noted. Mechanical stimulation had no effect on growth factor release from the scaffold in this system. To test the concerted effects of bFGF and mechanical stimulation on bone marrow stromal cells (BMSCs), scaffolds were loaded with 0, 100, or 500 ng of bFGF, seeded with cells, and subjected to mechanical strain or maintained in a static environment. Scaffolds were harvested at 1, 7, and 21 days for RT-PCR and histomorphometry. All scaffolds subjected to growth factor and/or mechanical stimulation demonstrated cellular adherence and spreading at 21 days. Conversely, in the absence of both bFGF and mechanical stimulation, cells demonstrated minimal cytoplasmic spread. Moreover, at 21 days, cells subjected to both mechanical stimulation and bFGF (500 ng) demonstrated the highest upregulation of stress-resistive (collagen I, III) and stress-responsive proteins (tenascin-C). The effect of growth factor may be dose sensitive, however, as unstrained scaffolds treated with 100 ng of bFGF demonstrated upregulation of gene expression comparable to strained scaffolds treated with lower doses of bFGF (0 or 100 ng). In conclusion, results from this study suggest that the stimulatory effects of bFGF are dose sensitive and appear to be influenced by the addition of mechanical strain. The concurrent application of biochemical and mechanical stimuli may be important in promoting the adaptation of BMSCs and driving the transcription of genes essential for synthesis of a functional ligament replacement tissue.