-transparent.png){kind=logo}
BACKGROUND This study was aimed at developing a myocardial bridge-mural coronary artery simulative device and analyzing the relationship between shear stress on the mural coronary artery and atherosclerosis. METHODS A myocardial bridge-mural coronary artery simulative device was used to simulate experiments in vitro. In the condition of maintaining any related parameters such as system temperature, average flow rate, and heart rate, we calculated and observed changes in proximal and distal mean values, and oscillatory value of shear stress on the mural coronary artery by regulating the compression level of the myocardial bridge to the mural coronary artery. RESULTS Under 0% compression, no significant differences were observed in distal and proximal mean values and oscillatory value of the shear stress on the mural coronary artery. With the increase in the degree of compression, the mean shear stress at the distal end was greater than that at the proximal end, but the oscillatory value of the shear stress at the proximal end was greater than that at the distal end. CONCLUSIONS The experimental results of this study indicate that myocardial bridge compression leads to abnormal hemodynamics at the proximal end of the mural coronary artery. This abnormal phenomenon is of great significance in the study of atherosclerosis hemodynamic pathogenesis, which has potential clinical value for pathological effects and treatments of myocardial bridge.
Hao Ding, and
Qian Yang, and
Kun Shang, and
Hailian Lan, and
Jie Lv, and
Zhilin Liu, and
Yang Liu, and
Lixing Sheng, and
Yanjun Zeng
June 2009,
Australasian physical & engineering sciences in medicine,
Hao Ding, and
Qian Yang, and
Kun Shang, and
Hailian Lan, and
Jie Lv, and
Zhilin Liu, and
Yang Liu, and
Lixing Sheng, and
Yanjun Zeng
October 2017,
Zhongguo yi xue ke xue yuan xue bao. Acta Academiae Medicinae Sinicae,
Hao Ding, and
Qian Yang, and
Kun Shang, and
Hailian Lan, and
Jie Lv, and
Zhilin Liu, and
Yang Liu, and
Lixing Sheng, and
Yanjun Zeng
January 2010,
Journal of medical engineering & technology,
Hao Ding, and
Qian Yang, and
Kun Shang, and
Hailian Lan, and
Jie Lv, and
Zhilin Liu, and
Yang Liu, and
Lixing Sheng, and
Yanjun Zeng
December 2016,
Zhongguo yi xue ke xue yuan xue bao. Acta Academiae Medicinae Sinicae,
Hao Ding, and
Qian Yang, and
Kun Shang, and
Hailian Lan, and
Jie Lv, and
Zhilin Liu, and
Yang Liu, and
Lixing Sheng, and
Yanjun Zeng
October 2016,
Zhonghua xin xue guan bing za zhi,
Hao Ding, and
Qian Yang, and
Kun Shang, and
Hailian Lan, and
Jie Lv, and
Zhilin Liu, and
Yang Liu, and
Lixing Sheng, and
Yanjun Zeng
January 2013,
TheScientificWorldJournal,
Hao Ding, and
Qian Yang, and
Kun Shang, and
Hailian Lan, and
Jie Lv, and
Zhilin Liu, and
Yang Liu, and
Lixing Sheng, and
Yanjun Zeng
January 2023,
American journal of translational research,
Hao Ding, and
Qian Yang, and
Kun Shang, and
Hailian Lan, and
Jie Lv, and
Zhilin Liu, and
Yang Liu, and
Lixing Sheng, and
Yanjun Zeng
April 1997,
American heart journal,
Hao Ding, and
Qian Yang, and
Kun Shang, and
Hailian Lan, and
Jie Lv, and
Zhilin Liu, and
Yang Liu, and
Lixing Sheng, and
Yanjun Zeng
October 2022,
Cardiovascular engineering and technology,
Hao Ding, and
Qian Yang, and
Kun Shang, and
Hailian Lan, and
Jie Lv, and
Zhilin Liu, and
Yang Liu, and
Lixing Sheng, and
Yanjun Zeng
October 2006,
Zhonghua yi xue za zhi,
