Xiaojian Qiu scite author profile

Xiaojian Qiu

2Publications

0Citation Statements Received

39Citation Statements Given

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University of Shanghai for Science and Technology

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Influence of geometric parameters on partial compressive force and pushing performance of flow diverter

Qiu

Liu

et al. 2021

Numer Methods Biomed Eng

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Research on flow diverter (FD) has progressed over the past decades; however, the relationships between parameters such as stent diameter, porosity, and number of wires and the properties of FDs, such as partial compressive force and push resistance, are not well understood. In this study, the partial compressive force and push resistance of braided FDs with varying porosity (61%–75%), diameter (2.5–5.0 mm), and number of wires (48 or 64) were evaluated using finite element analysis (FEA) and bench tests. At a small compression ratio, the 48‐wire stents exhibited a larger partial compressive force than 64‐wire stents of the same diameter. But when the compression ratio was 50%, the 64‐wire stents had better resistance to pressure. The partial compressive force decreased as the stent diameter increased when all other parameters were equal. However, the influence of the diameter decreased as the stent porosity increased. The push resistance decreased as the porosity and diameter increased, and increased with the number of wires. These results provide useful information for FD design. Decreasing the number of wires can reduce the push resistance, while the push resistance is mainly influenced by the porosity and number of wires, and almost has no relationship with the partial compressive force. The FEA model proved very reliable, and corresponded well to the bench test results, which indicates that this model can be utilized to guide the design of FDs.

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The Hemolysis Effect of Rotary Cutting Thrombectomy Device: The CFD and Experimental Study

Zhang

Qiu

et al. 2021

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Percutaneous mechanical thrombectomy (PMT) is an efficient way to treat the deep vein thrombosis (DVT). During the course of treatment, blood cell will be destroyed by the component of thrombectomy device, causing hemolysis. In this research, the computational fluid dynamics (CFD) methodology is used to investigate hemolysis effect of rotary cutting thrombectomy device. And a prototype of rotary cutting thrombectomy device is made to carry out two corresponding experiments to verify the simulation results. CFD results indicate that the hemolysis rate increases significantly with the rise of rotation speed of cutting component. The experimental results are in good consistence with the CFD results, and shows that the longer the working time, the higher the hemolysis rate. Thus a rotation speed between 5,000 rpm and 10,000 rpm can be considered reasonable. The results can be served as a helpful guidance for the design of such thrombectomy devices.

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Xiaojian Qiu

Influence of geometric parameters on partial compressive force and pushing performance of flow diverter

The Hemolysis Effect of Rotary Cutting Thrombectomy Device: The CFD and Experimental Study

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