Gong Yu, Song Bo, Jin Xi-yu, Xiong En-qing
Urology Center, Southwest Hospital, Third Military University, Chongqing 400038, China.
Zhonghua Wai Ke Za Zhi. 2003 Dec;41(12):901-5.
To investigate the relationship between phenotype transformation and biomechanical properties of detrusor smooth muscle cell (DSMC) subjected to the cyclic mechanical stretch.
Cultured rat DSMCS were grown on collagen-coated silicone membranes and subjected to continuous cycles of stretch-relaxation. All experiments were made on cells between passage 2 and 4. Each cycle consists of 5-second stretch and 5-second relaxation. The computer controlled vacuum induced 10% (I), 20% (II) and 30% (III) maximum elongation of the plate membrane at different designed pressures. We assessed DNA synthesis rate using tritiated thymidine incorporation assay. Using immunofluorescent assay and flow cytometer, we analysed the expression of SM-alpha-actin and proliferation of DSMC. The image analysis and micropipette aspiration systems were employed to investigate the single cell contraction and viscoelasticity. The elastic modulus K(1), K(2) and viscoelastic coefficient micro were determined using the three-element standard linear solid model, thus demonstrating the passive deformation ability of detrusor cells.
As the basic structural changes to mechanical stretch, DSMCs underwent phenotypic modulation from their normal contractile phenotype to a "synthetic" phenotype: the DSMCs became more proliferative and the actin less organized along the cell's long axis. The cell proliferation index (CPI) of control and stretched group (10%, 20%, 30% elongation) were 0.24, 0.43, 0.58 and 0.65 respectively. After mechanical stretch, the well-spread filaments changed their orientation. Contraction and viscoelasticity of single DSMC subjected to stretch both decreased significantly compared to control. The Vmax and. DeltaLmax of group III (30% elongation) saw significant decreases compared with unstretched control (P < 0.01). K(1) and K(2) decreased with the increasing of mechanical overload, however, there was no statistic difference between groups II and group III.
Structure determines function. Conversely, dysfunction implies the structural transformation. Functional abnormalities of BOO have the structural basis: phenotype transformation of detrusor cells. Cyclic stretch and relaxation applied to DSMCs in vitro can be used to model the increases in urodynamic load experienced by the bladder detrusor muscle under the conditions of bladder outlet obstruction. Phenotypic transformation is the structural basis of functional changes of DSMC subjected to periodic overload mechanical stretch.
研究周期性机械牵张作用下逼尿肌平滑肌细胞(DSMC)表型转化与其生物力学特性之间的关系。
将培养的大鼠DSMC接种于胶原包被的硅膜上,进行连续的牵张 - 松弛循环。所有实验均在第2至4代细胞上进行。每个循环包括5秒的牵张和5秒的松弛。计算机通过控制真空在不同设计压力下使平板膜产生10%(I组)、20%(II组)和30%(III组)的最大伸长。采用氚标记胸腺嘧啶核苷掺入法评估DNA合成率。利用免疫荧光分析和流式细胞仪分析DSMC的平滑肌α - 肌动蛋白(SM - alpha - actin)表达及细胞增殖情况。采用图像分析和微吸管抽吸系统研究单细胞收缩和黏弹性。使用三元标准线性固体模型测定弹性模量K(1)、K(2)和黏弹性系数μ,从而展示逼尿肌细胞的被动变形能力。
作为对机械牵张的基本结构变化,DSMC经历了从正常收缩表型到“合成”表型的表型调节:DSMC增殖增多,肌动蛋白沿细胞长轴的排列变得不那么规则。对照组和牵张组(10%、20%、30%伸长)的细胞增殖指数(CPI)分别为0.24, 0.43, 0.58和0.65。机械牵张后,伸展良好的细丝改变了其方向。与对照组相比,牵张后的单个DSMC的收缩和黏弹性均显著降低。III组(30%伸长)的Vmax和ΔLmax与未牵张对照组相比显著降低(P < 0.01)。K(1)和K(2)随机械负荷增加而降低,但II组和III组之间无统计学差异。
结构决定功能。反之,功能异常意味着结构转变。膀胱出口梗阻(BOO)的功能异常具有结构基础:逼尿肌细胞的表型转化。体外对DSMC施加周期性牵张和松弛可用于模拟膀胱出口梗阻情况下膀胱逼尿肌所经历的尿动力学负荷增加。表型转化是周期性过载机械牵张作用下DSMC功能变化的结构基础。
