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SIMULATION OF TISSUE DIFFERENTIATION DURING FRACTURE HEALING WITHIN A COLLAGENOUS SCAFFOLD IMPLANTED IN A MURINE TIBIA WITH AN OBLIQUE FRACTURE

机译：用斜骨折植入鼠胫骨植入胶囊骨折内部骨折愈合期间的组织分化模拟

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It is known that mechanical factors play a key role in bone formation and regulation of tissue regeneration during skeletal healing. However, the underlying mechanisms are not fully understood. Mechanical loads, such as cyclic compression, torsion and bending are key factors driving the differentiation of mesenchymal stem cells (MSCs). On the other hand, excessive mechanical loading may disrupt the process of healing and lead to non-unions and cell apoptosis. Therefore, effective positive mechanical factors are bounded by a range and frequency. A number of mechanoregulation algorithms have been developed by comparing tissue differentiation patterns under different loading regimes [1, 2, 3, 4]. The aim of this study was to predict the development of differentiated tissues in a closed fracture model treated with a stem cell seeded soft collagenous scaffold under load regimes of axial compression, bending and torsion. The long term goal is to improve our understanding of fracture healing in non-union fractures and develop stem cell based tissue engineering treatments.

机译：众所周知，机械因素在骨骼愈合期间在骨形成和组织再生调节中发挥着关键作用。但是，潜在机制尚未完全理解。机械载荷，例如循环压缩，扭转和弯曲是驱动间充质干细胞（MSCs）的分化的关键因素。另一方面，过度的机械负载可能会破坏愈合过程，导致非工会和细胞凋亡。因此，有效的正极机械因子由范围和频率有界限。通过比较不同负载制度下的组织分化模式[1,2,3,4]来开发了许多机械调节算法。本研究的目的是预测，在轴向压缩，弯曲和扭转的负载制度下，用干细胞种子软胶原支架处理的封闭断裂模型中的分化组织的发育。长期目标是改善我们对非联合骨折的骨折愈合的理解，并发展基于干细胞基组织工程治疗。

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《ASME bioengineering conference》|2012年||共2页
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Saghar Nasr; Neil A. Duncan;
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中图分类人体工程学;
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1. The simulation of bone healing process of fractured tibia applied with composite bone plates according to the diaphyseal oblique angle and plate modulus [J] . Dae-Sung Son, Seung-Hwan Chang Composites . 2013,第1期

机译：根据骨干斜角和板模量模拟复合骨板施加胫骨骨折的愈合过程
2. Numerical simulation of the tissue differentiation and corrosion process of biodegradable magnesium implants during bone fracture healing [J] . Songyun Ma, Bei Zhou, Bernd Markert Zeitschrift fur Angewandte Mathematik und Mechanik . 2018,第12期

机译：骨折愈合期间可生物降解镁植入物组织分化及腐蚀过程的数值模拟
3. Simulation of cell differentiation in fracture healing: mechanically loaded composite scaffolds in a novel bioreactor system. [J] . Matziolis G, Tuischer J, Kasper G, Tissue engineering . 2006,第1期

机译：骨折愈合过程中细胞分化的模拟：新型生物反应器系统中机械负载的复合支架。
4. SIMULATION OF TISSUE DIFFERENTIATION DURING FRACTURE HEALING WITHIN A COLLAGENOUS SCAFFOLD IMPLANTED IN A MURINE TIBIA WITH AN OBLIQUE FRACTURE [C] . Saghar Nasr, Neil A. Duncan ASME summer bioengineering conference;SBC2012 . 2012

机译：胫骨倾斜胫骨植入胶原支架内骨折愈合过程中组织分化的模拟
5. Fracture healing and regeneration in the context of an altered collagenous extracellular matrix. [D] . Meganck, Jeffrey Albert. 2010

机译：在胶原细胞外基质改变的情况下骨折的愈合和再生。
6. Minimally invasive plate osteosynthesis for short oblique diaphyseal tibia fractures: does fracture site affect the outcomes? [O] . Gokay Eken, Cenk Ermutlu, Kemal Durak, 2020

机译：微创板骨骨合成短斜透明性胫骨骨折：骨折部位是否影响结果？
7. Simulation of fracture healing incorporating mechanoregulation of tissue differentiation and dispersal/proliferation of cells [O] . Andreykiv, A., Van Keulen, F., Prendergast, P.J. 2007

机译：结合组织分化和细胞分散/增殖的机械调节骨折愈合的模拟

SIMULATION OF TISSUE DIFFERENTIATION DURING FRACTURE HEALING WITHIN A COLLAGENOUS SCAFFOLD IMPLANTED IN A MURINE TIBIA WITH AN OBLIQUE FRACTURE

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