Your search keyword '"Liu, Zhehao"' showing total 2 results

1. Effects of treadmill with different intensities on bone quality and muscle properties in adult rats.

Author

Liu, Zhehao, Gao, Jiazi, and Gong, He

Subjects

*TREADMILL exercise, *COMPACT bone, *TREADMILLS, *MUSCLES, *NANOINDENTATION tests, *BONE growth, *SOLEUS muscle, *FEMUR

Abstract

Background: Bone is a dynamically hierarchical material that can be divided into length scales of several orders of magnitude. Exercise can cause bone deformation, which in turn affects bone mass and structure. This study aimed to study the effects of treadmill running with different intensities on the long bone integrity and muscle biomechanical properties of adult male rats.Methods: Forty-eight 5-month-old male SD rats were randomly divided into 4 groups: i.e., sedentary group (SED), exercise with speed of 12 m/min group (EX12), 16 m/min group (EX16), and 20 m/min group (EX20). The exercise was carried out for 30 min every day, 5 days a week for 4 weeks. The femurs were examined using three-point bending test, microcomputer tomography scanning and nanoindentation test; the soleus muscle was dissected for tensile test; ALP and TRACP concentrations were measured by serum analysis.Results: The failure load was significantly increased by the EX12 group, whereas the elastic modulus was not significantly changed. The microstructure and mineral densities of the trabecular and cortical bone were significantly improved by the EX12 group. The mechanical properties of the soleus muscle were significantly increased by treadmill exercise. Bone formation showed significant increase by the EX12 group. Statistically higher nanomechanical properties of cortical bone were detected in the EX12 group.Conclusion: The speed of 12 m/min resulted in significant changes in the microstructure and biomechanical properties of bone; besides, it significantly increased the ultimate load of the soleus muscle. The different intensities of treadmill running in this study provide an experimental basis for the selection of exercise intensity for adult male rats. [ABSTRACT FROM AUTHOR]

Published

2019

2. The adaptive response of rat tibia to different levels of peak strain and durations of experiment.

Author

Liu, Zhehao, Gao, Jiazi, and Gong, He

Subjects

*TIBIA, *RATS, *AXIAL loads, *COMPACT bone, *ACID phosphatase, *BONE diseases

Abstract

• Tibia axial loading model was used to study the bone adaptive response. • Low-level strain did not stimulate osteogenic response, regardless of time. • Mid-level strain can improve bone quality by prolonging experiment time. • High-level strain can significantly stimulate osteogenic response in a short time. • It provides a theoretical basis for further study of improving human bone quality. The osteogenic response of bone to compressive load is affected by peak strain and duration of experiment, however, combined effect of peak load and duration of experiment on the rat tibia axial loading model remains unclear. In this study, rat tibia axial loading models with different levels of peak strains and durations of experiments were established (peak loads: 10 N, 20 N and 40 N, experimental duration: 2 weeks and 4 weeks). Microcomputer tomography scanning (Micro-CT), compression mechanical test and bone tissue alkaline phosphatase (ALP) and tartrate-resistant acid phosphatase (TRAP) staining were used to investigate the effects of cyclic loading with different levels of peak strains and durations of experiments on osteogenic response of tibia in adult female Sprague-Dawley (SD) rats. This experiment demonstrates that high-level strain can significantly stimulate the osteogenic response of cancellous and cortical bones in a short period of time. However, under mid-level strain, prolonging the experiment time can significantly improve the microsturcture and macromechanical properties of bone, increase the number of osteoblasts, and achieve the goal of improving bone quality. In this study, two loading schemes of mid-level-long-term and high-level-short-term were analyzed, and the mechanical response of the tibia under two different loading schemes was investigated. It provided a theoretical basis for further promoting the study of improving human bone quality and preventing aging-related bone diseases through mechanical stimulation. [ABSTRACT FROM AUTHOR]

Published

2022