王慧枝，中国科学技术大学苏州高等研究院特任副研究员，硕士生导师。主要研究方向为骨肌系统生物力学、植入物设计、数字骨科。获得国自然青年科学基金项目、中国博士后面上项目、上海市“超级博士后”激励计划资助，发表论文27篇，其中SCI论文23篇，JCR一区14篇，申请/授权国家专利4项，撰写/参与撰写英文著作章节2章，作国内外学术报告7次。此外，担任SCI期刊Bioengineering-Basel（IF₂₀₂₁=5.046）的共同客座主编。

联系方式: wang_huizhi8866@ustc.edu.cn

联系地址：中国科学技术大学苏州高等研究院明德楼A325

工作经历

2023/06-至今，中国科学技术大学苏州高等研究院，特任副研究员

2020/06-2023/06，上海交通大学生物医学工程学院，博士后研究员

学习经历

2014/09-2020/06，北京航空航天大学，生物医学工程，博士

2010/09-2014/06，首都医科大学，生物医学工程，学士

项目经历

国自然青年科学基金项目，2022.01 - 2024.12，主持

中国博士后科学基金面上项目，2022.01 - 2024.12，主持

上海市“超级博士后”激励计划，2022.01 - 2023.12，主持

代表论文

1. Wang H, He K, Cheng C-K^*. (2024) The structure, biology and mechanical function of tendon/ligament-bone interfaces. Tissue Engineering. Part B, Reviews. 

2. Wang H, Zhang Z, Shi Q, Zeng Y-M, Cheng C-K^*. (2023) Correlation between Morphological Features of the Anterior Cruciate Ligament: A Quantitative Study Using a Porcine Model. Frontiers in Veterinary Science, 10:1115068.

3. Wang H^#, Fang C^#, Tao M, Shi Q, He K, Cheng CK^*. (2022) Hourglass-shaped Grafts Are Superior to Conventional Grafts for Restoring Knee Stability and Graft Force at Knee Flexion Angle of 30° Following Anterior Cruciate Ligament Reconstruction: a finite element analysis. Frontiers in Bioengineering and Biotechnology, 10:967411.

4. Shi Q, Wang H^*, He K, Tao M, Cheng C-K^*. (2022) Comparison of the morphology of the anterior cruciate ligament and related bony structures between pigs and humans. Frontiers in Veterinary Science, 9:1045785.

5. Wang H, Tao M, Shi Q, He K, Cheng C-K^*. (2022) Graft Diameter Should Reflect the Size of the Native Anterior Cruciate Ligament (ACL) to Improve the Outcome of ACL Reconstruction: A Finite Element Analysis. Bioengineering-Basel, 9(10), 507.

6. Cheng R^#, Wang H^#, Dimitriou D, Jiang Z, Cheng C-K^*, Tsai T-Y^*. (2022) Central femoral tunnel placement can reduce stress and strain around bone tunnels and graft more than anteromedial femoral tunnel in anterior cruciate ligament reconstruction. International Journal For Numerical Methods In Biomedical Engineering, e3590.

7. Wang H^#, Zhang Z^#, Qu Y, Shi Q, Ai S^*, Cheng C-K^*. (2022) Correlation between ACL size and dimensions of bony structures in the knee joint. Annals of Anatomy-Anatomischer Anzeiger, 241:151906.

8. Cheng R^#, Wang H^#, Jiang Z, Dimitriou D, Cheng C-K^*, Tsai T-Y^*. (2021) The femoral tunnel drilling angle at 45° coronal and 45° sagittal provided the lowest peak stress and strain on the bone tunnels and anterior cruciate ligament graft. Frontiers in Bioengineering and Biotechnology, 9:797389.

9. Wang H, Zhang M, Cheng CK^*. (2020) Changing the diameter of the bone tunnel is more effective than changing the tunnel shape for restoring joint functionality after ACL reconstruction. Frontiers in Bioengineering and Biotechnology, 8:173.

10. Wang H, Zhang M, Cheng C-K^*. (2020) A novel protection liner to improve graft-tunnel interaction following anterior cruciate ligament reconstruction: a finite element analysis. Journal of Orthopaedic Surgery and Research, 15(1):1-10.

11. Wang H, Zhang B, Cheng C-K^*. (2020) Stiffness and shape of the ACL graft affects tunnel enlargement and graft wear. Knee Surgery Sports Traumatology Arthroscopy, 28(7):2184-2193.

12. Wang H, Kang H, Yao J, Cheng C-K^*, Woo SL-Y^*. (2019) Evaluation of a magnesium ring device for mechanical augmentation of a ruptured ACL: Finite element analysis. Clinical Biomechanics, 68:122-127.