Molecular mechanism of Shaofu Zhuyu decoction in treating endometriosis dysmenorrhea based on GPER2/MAPK/STAT1 axis / 中国中药杂志

The aim of this paper is to study the molecular mechanism of Shaofu Zhuyu decoction in treating dysmenorrhea of endometriosis based on GPER2/MAPK/STAT1 axis. In this study, HE staining was used to observe the pathological changes of the rats in each group. The levels of TNF-α and IL-6 were detected by ELISA assay. The mRNA expressions of neurotransmitter receptor (NK1) and GPER were detected by qPCR. The protein contents of MAPK and STAT1 were detected by Western blot. According to the results, compared with the model group, Shaofu Zhuyu decoction could significantly improve the inflammation of the ectopic uterine cavity tissue, decrease the contents of TNF-α and IL-6 in the uterine cavity, the mRNA expressions of NK1 and GPER, and the protein expressions of MAPK and STAT1. In conclusion, Shaofu Zhuyu decoction could effectively inhibit the expressions of GPER2, MAPK and STAT1, decrease the levels of TNF-α, IL-6 and NK1 mRNA and relieve the inflammatory pain in patients with endometriosis.

Effectsof shear stress at physiological level on mechanical sensitivity, adhesion and differentiation of MC3T3-E1 cells in three-dimensional porous scaffold / 医用生物力学

Objective To construct the three-dimensional (3D) fluid model at the physiological level of shear stresses and study the effects of fluid shear stress (FSS) on adhesion, differentiation and mechanical sensitivity of osteoblasts. Methods The MC3T3-E1 osteoblasts cultured on β-tricalcium phosphate (β-TCP) scaffolds were subjected to various FSSs in the perfusion flow chamber for 6 hours to compare cell adhesion in FSS-loading groups and control group. Nitric oxide (NO) and alkaline phosphatase (ALP) were detected to compare mechanical sensitivity and cell differentiation. The FSS magnitude and distributions corresponding to various fluid rates were calculated with nonlinear fluid-structure coupling analysis. Results Cell adhesion rate was up to 74%~81% when the average FSS magnitude was lower than 0.4 Pa, but reduced to 60.22% when the average FSS was 0.41 Pa. The NO production rate reached the maximal concentration after loading for 5 min, then significantly reduced at 15 min, and gradually diminished to none at 30 min. ALP level significantly increased (P0.05) with the increase of shear stress. Conclusions Majority of the cells kept a normal adherence to the scaffold at the physiological level of shear stresses. The mechanical sensitivity of the cells under 3D condition was dependent on the FSS rate, which was consistent with two-dimensional (2D) condition. When the average FSS was lower than 0.304 Pa in the scaffold, FSS could significantly promote cell differentiation, but no significant change in cell differentiation could be found when FSS was higher than 0.304 Pa. The present study is expected to accelerate the realization of bone tissue engineering.

Reevaluation on the mechanical properties of dentine microstructure / 医用生物力学

Objective It is demostrated that the porous protein mineral mechanics model could provide more accurate prediction for biomaterial properties of dentine compared with the other established models. This paper would use the model to reevaluate the mechanical properties and its interacting mechanism of human dentine. Method By using a porous protein mineral mechanics model, the effect from the interactions between tubules, peritubular and intertubular matrix on dentine microstructure was discussed. Results The dentinal micromechanical properties were dependent on the tubular direction, and the absolute values of the stresses derived from the hydraulic and gas tubular pressures increased parabolically with the increasing diameter of the tubules. It was also found that the effective elastic constants of the dentine microstructure would vary with the aging and the distribution of mineral and collagen within peritubular and intertubular matrix of detine. Conclusions The theoretical analyses provided in this paper demonstrated that the microstructural characteristics of tubules, peritubular and intertubular dentinal matrix could have different influences on the micromechanical properties of human dentine, which showed the validity of porous protein mineral mechanics model, and the limitation of some models that neglected the interacting mechanism.

Reevaluation on the mechanical properties of dentine microstructure / 医用生物力学

Objective:It is demostrated that the porous protein-mineral mechanics model could provide more accurate prediction for biomaterial properties of dentine compared with the other established models.This paper would use the model to reevaluate the mechanical properties and its interacting mechanism of human dentine.Method:By using a porous proteinmineral mechanics model,the effect from the interactions between tubules,pedtubular and intertubular matrix on dentine microstructure was discussed.Results:The dentinal micromechanical properties were dependent on the tubular direction,and the absolute values of the stresses derived from the hydraulic and gas tubular pressures increased parabolically with theincreasing diameter of the tubules.It was also found that the effective elastic constants of the dentine microstructure would vary with the aging and the distribution of mineral and collagen within peritubular and intertubular matrix of detine.Conclusions:The theoretical analyses provided in this paper demonstrated that the microstructural characteristics of tubules,peritubular and intertubular dentinal matdx could have different influences on the micromechanical properties of human dentine,which showed the validity of porous protein-mineral mechanics model,and the limitation of some models that neglected the interacting mechanism.

Reevaluation on the mechanical properties of dentine microstructure / 医用生物力学

Objective:It is demostrated that the porous protein-mineral mechanics model could provide more accurate prediction for biomaterial properties of dentine compared with the other established models.This paper would use the model to reevaluate the mechanical properties and its interacting mechanism of human dentine.Method:By using a porous proteinmineral mechanics model,the effect from the interactions between tubules,pedtubular and intertubular matrix on dentine microstructure was discussed.Results:The dentinal micromechanical properties were dependent on the tubular direction,and the absolute values of the stresses derived from the hydraulic and gas tubular pressures increased parabolically with theincreasing diameter of the tubules.It was also found that the effective elastic constants of the dentine microstructure would vary with the aging and the distribution of mineral and collagen within peritubular and intertubular matrix of detine.Conclusions:The theoretical analyses provided in this paper demonstrated that the microstructural characteristics of tubules,peritubular and intertubular dentinal matdx could have different influences on the micromechanical properties of human dentine,which showed the validity of porous protein-mineral mechanics model,and the limitation of some models that neglected the interacting mechanism.

Numerical computation on the scaffolds models with regular square holes using nonlinear fluid-solid-coupling approaches / 医用生物力学

Objective The influencing parameters of solid and fluid computing fields for the scaffolds models with regular square holes were discussed by nonlinear fluid-solid-coupling approaches, the numerical computational results of which the models were regarded as both rigid body and non-linear elasticity were compared as well. Method one direct fluid-solid-coupling approach and two indirect fluid-solid-coupling approaches were adopted, and the calculating reliability of three kinds of fluid-solid coupling methods were verified. Results The solid-fluid-coupling computational results are obtained in light of 12 kinds of scaffolds which were constructed by 3 groups of square side length (50,100 and 150μm) and 4 groups of porosity (61%,65%,77% and 84%). The field parameters of those solid models including stress, strain and displacement and those fluid models including static pressure, velocity, wall shear stress and strain rate are achieved and compared.Conclusions A quiet difference between the results of porous scaffold models as a rigid body and that of non-linear elasticity. The different porosity with the same pore radius or the different pore radius with the same porosity effected the field parameters of solid models and fluid models in varying degrees.

Numerical computation on the scaffolds models with regular square holes using nonlinear fluid-solid-coupling approaches / 医用生物力学

Objective The influencing parameters of solid and fluid computing fields for the scaffolds models with regular square holes were discussed by nonlinear fluid-solid-coupling approaches.The numerical computational resuits of which the models were regarded as both rigid body and non-linear elasticity were compared as well.Method One direct fluid-solid-coupling approach and two indirect fluid-solid-coupling approaches were adopted,and the calculating reliability of three kinds of fluid-solid coupling methods was verified.Rasults The solid-fluidcoupling computational results are obtained in light of 12 kinds of scaffolds models which are constructed by 3 groups of square side length(50,100 and 150 μm)and 4 groups of porosity(61%,65%,77%and 84%).The field parameters of those solid models including stress,strain and displacement and those fluid models including static pressure,velocity,wall shear stress and strain rate are achieved and compared.Conclusion There appear some difference between the results of porous scaffold models as a rigid body and as non-linear elasticity.The different porosity with the same pore radius or the different pore radius with the same porosity would affect the field parameters of solid models and fluid models in varying degrees.

Numerical computation on the scaffolds models with regular square holes using nonlinear fluid-solid-coupling approaches / 医用生物力学

Objective The influencing parameters of solid and fluid computing fields for the scaffolds models with regular square holes were discussed by nonlinear fluid-solid-coupling approaches.The numerical computational resuits of which the models were regarded as both rigid body and non-linear elasticity were compared as well.Method One direct fluid-solid-coupling approach and two indirect fluid-solid-coupling approaches were adopted,and the calculating reliability of three kinds of fluid-solid coupling methods was verified.Rasults The solid-fluidcoupling computational results are obtained in light of 12 kinds of scaffolds models which are constructed by 3 groups of square side length(50,100 and 150 μm)and 4 groups of porosity(61%,65%,77%and 84%).The field parameters of those solid models including stress,strain and displacement and those fluid models including static pressure,velocity,wall shear stress and strain rate are achieved and compared.Conclusion There appear some difference between the results of porous scaffold models as a rigid body and as non-linear elasticity.The different porosity with the same pore radius or the different pore radius with the same porosity would affect the field parameters of solid models and fluid models in varying degrees.