ABSTRACT
<p><b>OBJECTIVE</b>To observe the effect of cyclic equiaxial tensile strain in the early differentiation of bone marrow mesenchymal stem cells(BMSCs) into cartilage in mouse under conditions of two-dimensional culture, and to investigate the mechanism of cyclic equiaxial tensile strain in early chondrogenic differentiation.</p><p><b>METHODS</b>Sixteen KM mouse aged 4 weeks were selected, male and female unlimited, with an average weight of 19.5 g (17 to 21 g). After extracting and isolating the BMSCs from KM mouse, then subculture the BMSCs to the 3rd generation. Seed the cells in the biological plate(BioFlex). According to experimental design, the cells were divided into 6 groups, blank group: ordinary culture medium was cultured for 8 days without isometric cyclic tensile strain stimulation. Control group: chondrogenic differentiation medium was used to culture for 8 days without isometric cyclic tensile strain stimulation. Experimental group: the experimental group was divided into 4 groups, all of which were cultured with chondrogenic differentiation medium for 8 days. During which isometric cyclic tensile strain stimulation was given for 1, 3, 5 and 7 days respectively. At the 8th day, all the cells were collected, the expression of the Sox9, Col-II and ROCK 1 signaling pathway-related molecules was analyzed by RT-PCR. Cells in each group were extracted, and the efficiency of cell proliferation in each group was detected by CCK-8. Glycosaminoglycan content in medium changed last was detected using ELISA. Pericellular matrix was observed by Safranin O staining and Alcian Blue staining. Normal measurement data using mean±standard deviation compared between the blank group and control group using paired t-test, compared between the experimental group and relative group using single factor analysis of variance.</p><p><b>RESULTS</b>(1)After 8 days of culture, compared with the control group, the relative expression of Sox 9 and Col-II mRNA in the experimental group increased gradually with the increase of loading time(<0.05), while the relative expression of ROCK1 mRNA decreased(<0.05). Compared with the blank group, the relative expression of ROCK1 mRNA in experimental group and control group increased (<0.05). (2)With the increase of loading time, the experimental group showed a trend of decreasing at first and then increasing, but compared with the blank group and the control group, the control group decreased significantly. (3)Glycosaminoglycan content in the medium changed last was detected by ELISA. The glycosaminoglycans in the experimental group increased gradually, and the content changes on 7 days loading group were statistically significant compared with other groups(<0.05). (4)Safranin O and Alcilan staining showed that there was a tendency of cartilage differentiation in the experimental group, and the shape gradually increased with time, which was more obvious than that in the control group; The PCM, Col-II and GAG in the experimental group increased gradually with the increase of mechanical stimulation days, which were more obvious than those in the control group.</p><p><b>CONCLUSIONS</b>Under conditions of two-dimensional culture, in the early differentiation of mesenchymal stem cells into cartilage, cyclic equiaxial tensile strain can promote the proliferation of BMSCs and the differentiation into chondrocytes. Moreover, cyclic equiaxial tensile strain may promote chondrogenic differentiation through inhibiting the Rho/ROCK 1 signaling pathway.</p>
ABSTRACT
Mechanical stimulation widely exists in the body and participates in adjusting biological behavior of many kinds of cells. As a common stress pattern in the body, the tensile strain widely exists in many organs, such as bone and cartilage, muscle tendon, cardiac and pulmonary vessels, and so on. In recent years, with the development of the researches of biomechanics, a variety of mechanical loading devices, which are used to simulate the complex mechanical stimulation in the body to provide the tensile strain including the isometric, uniaxial and various types of mechanical waveform, came into being. This is a huge boost to biomechanical research. Many researchers have found that the tensile strain stimulation can lead to the transformation of proliferation, differentiation and apoptosis of cells and change of cell matrix. However, for the same kind of cells, different kinds of tensile strain stimulation can lead to different and even the contrary results. In this paper, the effects of the tensile strain on the proliferation, differentiation and matrix of cartilage were reviewed. Understanding these characteristics will have important implications for the mechanism of cell proliferation and differentiation under the biomechanic stimulation and the prevention and treatment of diseases.
ABSTRACT
Patients who suffer from the recurrent patellar dislocation mainly show the recurrent dislocation of patellar, giving way, most patients have the history of trauma or dysplasia of keen joint. Traditional therapies of recurrent patellar dislocation include medical retinaculum placation, lateral retinaculum release, tibial tubercle osteotomy, femoral trochleoplasty etc. In recent years, with the development of anatomical and biomechanical researches on medial patellofemoral ligament(MPFL), more and more experts focus on the role of MPFL played in preventing the patellar dislocation. The treatment of recovering and correcting patellar tracking through MPFL reconstruction has been increasing gradually. However, till now, there was no therapy which could heal the recurrent patellar dislocation completely. The specific therapies of recurrent patellar dislocation are combination therapies, decided according to the anatomical and biomechanical conditions of patients, for recovering the stability of patients' patellar, the lower limb alignment and the function of keen-joint.