SCI期刊论文(第一&通讯作者):
人工心脏
Wu P*, Xiang WJ, Zhang KJ, Du GT (2024) Turbulentflow field in maglev centrifugal blood pumps of CH-VAD and HeartMate III: secondaryflow and its effects on pump performance, Biomechanics and Modeling in Mechanobiology, https://doi.org/10.1007/s10237-024-01855-1.
Wu P*, Bai YQ, Du GT, Zhang LD, Zhang XY (2023) Resistance valves in circulatory loops have a significant impact on in vitro evaluation of blood damage caused by blood pumps: a computational study, Frontiers in Physiology, 14:1287207. doi: 10.3389/fphys.2023.1287207.
Wu P*, Wu ZJ, Chen HB, Chen ZS, Zhang XW, Yang M (2023) Editorial: Recent advances in the design and preclinical evaluation of ventricular assist devices, Frontiers in Physiology, 14:1322077. doi: 10.3389/fphys.2023.1322077.
Xiang WJ, Wu WT*, Wu P* (2023) Influence of inlet boundary conditions on the prediction of flow field and hemolysis in blood pumps, Bioengineering, 10(2):274.
Wu P*, Huo JD, Zhang ZJ, Wang CJ* (2022) The influence of non-conformal grid interfaces on the results of large eddy simulation of centrifugal blood pumps, Artificial Organs, 46(9): 1804-1816.
Mei X, Lu B, Wu P*, Zhang LD* (2022) In vitro study of red blood cell and VWF damage in mechanical circulatory support devices based on blood-shearing platform, Proceedings of IMechE Part H: Journal of Engineering in Medicine, 236(6):860-866.
Wu P*, Xiang WJ, Yin CK* and Li S* (2021) The design and evaluation of a portable extracorporeal centrifugal blood pump, Frontiers in Physiology, 12:766867. doi: 10.3389/fphys.2021.766867.
Huo JD#, Wu P#*, Zhang LD, Wu WT* (2021) Large eddy simulation as a fast and accurate engineering approach for the simulation of rotary blood pumps, International Journal of Artificial Organs, 44(11):887-899.
Wu P*, Huo JD, Dai WF, Yin CK*, Li S* (2021) On the optimization of a centrifugal maglev blood pump through design variations, Frontiers in Physiology, 12:699891. doi:10.3389/fphys.2021.699891.
Wu P*, Zhang LD, Gao Q, Dai WF (2021) Effect of turbulent inlet conditions on the prediction of flow field and hemolysis in the FDA ideal medical device, Proceedings of IMechE Part H: Journal of Mechanical Engineering Science. 235(2):391-401.
Dai WF, Wu P*, Liu GM* (2021) A two-phase flow approach for modeling blood stasis and estimating the thrombosis potential in ventricular assist devices, International Journal of Artificial Organs, 44(7): 471-480.
Wu P*, Gross-Hardt S, Boehning F, Hsu PL (2020) An energy-dissipation-based power law formulation for estimating hemolysis. Biomechanics and Modeling in Mechanobiology, 19:591-602.
Wu P*, Gao Q, Hsu PL (2019) On the representation of effective stress for computing hemolysis. Biomechanics and Modeling in Mechanobiology, 18:665-679.
Wu P*, Boehning F, Gross-Hardt S, Hsu PL (2018) On the accuracy of hemolysis model in Couette-type of shearing devices, Artificial Organs, 42(10): E290–E303.
心脑血管血流动力学
Wang L, Jiang XD, Zhang KJ, Chen K, Wu P*, Li XQ* (2024) A hemodynamic analysis of energy loss in abdominal aortic aneurysm using three-dimension idealized model, Frontiers in Physiology, 15: 1330848.
Jiang XD#, Xiang GY#, Du GT, Du XL*, Wu P*, Li XQ* (2023) A hemodynamic analysis of fenestrated physician-modified endograft repair for complicated aortic dissections involving the visceral arteries, Computer Methods and Programs in Biomedicine, 242:07785.
Zhang ZJ#, Zhu JD#, Wu M*, Wu WT, Wu P* (2023). Computational modeling of hemodynamics and risk of thrombosis in the left atrial appendage using patient-specific blood viscosity and boundary conditions at the mitral valve, Biomechanics and Modeling in Mechanobiology, 22(4):1447-1457.
Jiang XD, Cao HY, Zhang ZJ, Zheng TH, Li XQ, Wu P* (2022). A hemodynamic analysis of the thrombosis within occluded coronary arterial fistulas with terminal aneurysms using a blood stasis model, Frontiers in Physiology, 13:906502. doi: 10.3389/fphys.2022.906502.
Jiang XD#, Li Da#, Wu P*, Li XQ, Zheng TH* (2022) A two-fluid blood stasis model for false lumen thrombosis after type B dissection repair, Computer Methods in Biomechanics and Biomedical Engineering, 25(13):1499-1508.
Jiang XD#,Gu XP#,Xu TZ, Li XQ*, Wu P*, Sun LL* (2022) Patient-specific hemodynamic analysis of IVCS-induced DVT, Computer Methods in Biomechanics and Biomedical Engineering, 25(11): 1211-1221.
仿生与智能流体力学
Hua Y, Yu CH, Zhao Q, Li MG, Wu WT*, Wu P* (2023) Surrogate modeling of heat transfers of nanofluids in absorbent tubes with fins based on deep convolutional neural network, International Journal of Heat and Mass Transfer, 20: 123736.
Liu GC, Jiang YG*, Wu P*, Ma ZQ, Chen HW, Zhang DY (2022). Artificial Whisker Sensor with Undulated Morphology and Self-Spread Piezoresistors for Diverse Flow Analyses, Soft Robotics, 10(1):97-105.
Jiang YG*, Zhao P, Cai XF, Dong ZH, Chen HW, Wu P*, Hu HY, Jin XX, Zhang DY, Liu H* (2022) Bristled-wing design of materials, microstructures, and aerodynamics enables flapping flight in tiny wasps, iScience, 25(1): 103692.
Wu P, Feng ZB, Cao SJ* (2018) Fast and accurate prediction of airflow and drag force for duct ventilation using wall-modeled large-eddy simulation, Building and Environment, 141: 226-235.
Wu P, Meyers J* (2013) A constraint for the subgrid-scale stresses in the logarithmic region of high Reynolds number turbulent boundary layers: a solution to the log-layer mismatch problem, Physics of Fluids, 25, 015104.
Wu P, Meyers J* (2011) Globally conservative high-order filters for large-eddy simulation and computational aero-acoustics, Computers & Fluids, 48(5):150-162. 2011.
其他期刊论文(第一&通讯作者):
徐健,陈凯,王相权,肖华伟,王铃,吴鹏*复合型形态学特征联合流体力学对肾下型腹主动脉瘤破裂风险的评估,2024,33(2),102-107
张子健,余晴阳,邓业林,吴鹏*考虑叶轮与蜗壳间隙的风机多因素正交优化设计, 流体机械,2023, 51(6):26-32.
Wu P* (2022). Recent advances in the application of computational fluid dynamics in the development of rotary blood pumps, Medicine in Novel Technology and Devices, 16: 100177.
陆斌,张柳笛*,梅旭,尹成科,蒋秋波,郇娜娜,吴鹏*, 基于新型磁悬浮Taylor-Couette血液剪切平台研究VWF损伤规律, 医用生物力学, 2022, 37(4):699-705。
江旭东,许天泽,孙莉莉,李晓强*,吴鹏*, 髂静脉狭窄所致侧支循环与下肢深静脉血栓之间关联的血流动力学研究, 医用生物力学, 2022,37(1):105-111。
王晨,徐博翎,吴鹏*, 叶片倒角对FDA标准血泵流场和溶血预测的影响, 医用生物力学, 2019,34(1):57-63。
Wu P, Meyers J* (2012) An improved blending formulation for wall-modeled large-eddy simulations, Progress in Hybrid RANS-LES Modelling (Editors: S Fu, W Haase, SH Peng and D Schwamborn), Springer, ISBN 978-3-642-31817-7, 111-120, 2012. EI