Advances on research of physical environment affecting stem cell differentiation in ligament tissue engineering.
10.12200/j.issn.1003-0034.2020.11.019
- Author:
Ya-Qiang ZHANG
1
;
Cheng-Wei YANG
1
;
Guo-Chao FENG
1
;
Chuang-Bing LI
1
;
Pei-Sheng SHI
1
;
Ping ZHEN
1
Author Information
1. The 940th Hospital of Joint Logistics Support Force of Chinese People's Liberation Army, Lanzhou 730050, Gansu, China.
- Publication Type:Journal Article
- Keywords:
Elastic modulus;
Ligament tissue engineering;
Mechanical stimulation;
Uniaxial stretching
- MeSH:
Cell Differentiation;
Environment;
Humans;
Ligaments;
Research;
Tissue Engineering;
Tissue Scaffolds
- From:
China Journal of Orthopaedics and Traumatology
2020;33(11):1080-1084
- CountryChina
- Language:Chinese
-
Abstract:
Ligament tissue engineering is currently a novel approach to the treatment of ligament injury, which can replace the deficiency of autografts. Ligament tissue engineering consists of four basic elements:seed cells, nanoscaffolds, growth factors, and mechanical stimulation. At present, the main problem in ligament tissue engineering is how to control seed cells to ligament cells more controllly. The study found that each physical property of the natural bio ligament and mechanical stimulation (uniaxial stretching) plays an important role in the differentiation of stem cells into ligament cells. Therefore, the design of nanofiber scaffolds must consider the elastic modulus of the material and the material. Structure(material arrangement, porosity and diameter, etc.), elastic modulus and material structure in different ranges will guide cells to differentiate into different lineages. Considering that the ligament is the main force-bearing tissue of the human body, mechanical stimulation is also essential for stem cell differentiation, especially uniaxial stretching, which best meets the stress of the ligament in the body. A large number of studies have found the frequency and amplitude of stretching. And time will also lead the cells to differentiate in different directions. RhoA/ROCK plays a regulatory role in cytoskeletal remodeling and cell differentiation. It is also found that RhoA/ROCK protein participates in the process of nanofiber arrangement and uniaxial stretching to guide stem cells to differentiate into ligament cells, specifically how to influence stem cell differentiation. It is not clear at present that understanding the effects of physical properties on stem cell differentiation and understanding the mechanism of action of RhoA/ROCK protein will provide a new theoretical basis for further optimization of ligament tissue engineering.
