2019：

1. 1. Liu Xiaoyu, Chen Zhenxian*, Gao Yongchang, et al. High Tibial Osteotomy: Review of techniques and biomechanics. Journal of Healthcare Engineering. 2019. (SCI: IF9MX)
2. 2. Chen Zhenxian, Zhang jing, et al. Effects of interference assembly of a tibial insert on the tibiofemoral contact mechanics in total knee replacement. Proc Inst Mech Eng H, 2019. (SCI:Accepted)
3. 3. Zhang Qida, Chen Zhenxian*, Zhang Jing, et al. Insert conformity variation affects kinematics and wear performance of total knee replacements. Clinical Biomechanics. 2019; 65: 19-25. (SCI: IB3UF)
4. 4. Ardestani M. M., ZhenXian Chen, et al. Computational analysis of knee joint stability following total knee arthroplasty[J]. J Biomech, 2019. 10.1016/j.jbiomech.2019.01.029 (SCI: HR0ER)
5. 5. Zhang, Z.F., Zhang, Q. D., Zhao, G. H., Huang, J., Chen, Z. X.et al., Morphological Measurements of the Normal Distal Femur and Proximal Tibia between Han Chinese and Mongolian Chinese in a Healthy Chinese Population. International Journal of Morphology, 2019. 37(2): p. 664-670. (SCI: HW9BA)
6. 6. Xiangquan Wu, a., a. Qin Lian, a. Dichen Li and a. Zhongmin Jin (2019). "Biphasic osteochondral scaffold fabrication using multi-material mask projection stereolithography." Rapid Prototyping Journal(2): 277.
7. 7. 范勋健, 陈瑱贤, 曹卓, 夏志辉, 陈军, 靳忠民. 个体化骨肌多体动力学和有限元联合建模的肩胛骨锁定板生物力学评估方法 [J]. 西安交通大学学报. 2019. 53(07): p. 168-176.
8.  

2018：

1. 1. Chen Zhenxian, Gao Yongchang, et al. Biomechanics and wear comparison between mechanical and kinematic alignments in total knee arthroplasty[J]. Proc Inst Mech Eng H, 2018: 232(12): 1209–1218 (SCI: HE7HN)
2. 2. Peng Yinghu, Zhang Zhifeng, Gao Yongchang, Chen Zhenxian*, et al. Concurrent prediction of ground reaction forces and moments and tibiofemoral contact forces during walking using musculoskeletal modelling[J].Medical Engineering and Physics, 2018. 52: 31~40. (SCI: GC1BB)
3. 3. Hu Jiayu; Chen Zhenxian*; Xin Hua; Zhang Qida; Jin Zhongmin. Musculoskeletal multibody dynamics simulation of the contact mechanics and kinematics of a natural knee joint during a walking cycle[J]. Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine.2018. 232(5):508~519 (SCI: GH0LK)
4. 4. Gao Yongchang, Chen Zhenxian, et al. Effect of inclination and anteversion angles on kinematics and contact mechanics of dual mobility hip implants[J]. Clin Biomech (Bristol, Avon), 2018, 57: 48-55. (SCI: GP3TG)
5. 5. Hu Jiayu, Xin Hua, Chen Zhenxian, et al. The role of menisci in knee contact mechanics and secondary kinematics during human walking[J]. Clinical biomechanics (Bristol, Avon), 2018, 61: 58-63. (SCI: HO1ZY)
6. 6. Chen Shibin, Ma Jingcun, Yao Yunshi, Gao Yongchang, Chen Zhenxian, Ping Lin. Investigation of combining dipole antennas with three dimensional photonic crystals[J]. Journal of Physics: Conference Series, 2018, 1053: 012082. 10.1088/1742-6596/1053/1/012082 (SCI)
7. 7. Sun, C., Wang, L., Kang, J., Li, D., & Jin, Z. (2018). Biomechanical Optimization of Elastic Modulus Distribution in Porous Femoral Stem for Artificial Hip Joints. Journal of Bionic Engineering, 15(4), 693-702.
8. 8. Diao, H., H. Xin and Z. Jin (2018). Prediction of in vivo lower cervical spinal loading using musculoskeletal multi-body dynamics model during the head flexion/extension, lateral bending and axial rotation. 232: 1071-1082.
9. 9. Lu, X., Q. Meng, J. Wang and Z. Jin (2018). "Transient viscoelastic lubrication analyses of UHMWPE hip replacements." Tribology International 128: 271-278.
10. 10. Wu, X., Q. Lian, X. He, J. Meng, X. Liu and Z. Jin (2018). "Influence of boundary masks on dimensions and surface roughness using segmented exposure in ceramic 3D printing." Ceramics International.
11. 11. 武向权, 连芩, 何晓宁, 孟佳丽, 李涤尘, 靳忠民, (2018). "多材料面曝光增材制造方法与加工工艺研究" 电加工与模具 (1): 47.
12.  

2017：

1. 1. Zhang Jing, Chen Zhenxian*, Wang Ling, Li Dichen, Jin Zhongmin. A patient-specific wear prediction framework for an artificial knee joint with coupled musculoskeletal multibody-dynamics and finite element analysis[J]. Tribology International, 2017, 109: 382-389. (SCI: EM9DM)
2. 2. Zhang Jing, Chen Zhenxian*, Wang Ling, et al. Load application for the contact mechanics analysis and wear prediction of total knee replacement[J]. Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine, 2017, 231:444-454. (SCI:ET3RX)
3. 3. Fan Xunjian, Chen Zhenxian*, Jin Zhongmin, et al. Parametric study of patient-specific femoral locking plates based on a combined musculoskeletal multibody dynamics and finite element modeling[J]. Proceedings of the Institution of Mechanical Engineers Part H, Journal of engineering in medicine, 2017. 232(2):114~126. (SCI: FV2KB)
4. 4. Sun, C., Tian, X., Wang, L., Liu, Y., Wirth, C. M., Günster, J.,LI, D., Jin, Z. (2017). Effect of particle size gradation on the performance of glass-ceramic 3D printing process. Ceramics International, 43(1), 578-584.
5. 5. Wu, X., Q. Lian, D. Li and Z. Jin (2017). "Tilting separation analysis of bottom-up mask projection stereolithography based on cohesive zone model." Journal of Materials Processing Tech. 243: 184-196.
6. 6. Zhang, X., L. Wang, X. Peng, D. Li, J. He, Y. Liu, Q. I. N. Lian, Z. Jin and C. Liu (2017). "THE EFFECT OF ASPHERICITY OF ACETABULAR BEARING SURFACE ON CONTACT MECHANICS OF UHMWPE TOTAL HIP IMPLANTS BY FINITE ELEMENT ANALYSIS." Journal of Mechanics in Medicine & Biology 17(1): -1.
7.  

2016：

1. 1. Jin, Z. M., J. Zheng, W. Li and Z. R. Zhou (2016). "Tribology of medical devices." Biosurface and Biotribology 2(4): 173-192.
2. Chen Zhenxian, Zhang Zhifeng, Wang Ling, et al. Evaluation of a Subject-Specific Musculoskeletal Modeling Framework to Predict Load in Total Knee Arthroplasty [J]. Medical Engineering & Physics, 2016. 38(8): 708–716 (SCI:DR7KV )
3. 2. Chen Zhenxian*, Jin Zhongmin. Prediction of In-vivo Kinematics and Contact Track of Total Knee Arthroplasty during Walking[J]. Biosurface and Biotribology, 2016, 2:86-94.
4. 3. Qiu, C., L. Wang, D. Li and Z. Jin (2016). The influence of metallic shell deformation on the contact mechanics of a ceramic-on-ceramic total hip arthroplasty. 230: 4-12.
5. 4. Gao Y, Chai W, Wang L, et al. Effect of friction and clearance on kinematics and contact mechanics of dual mobility hip implant[J]. Proc Inst Mech Eng H, 2016, 230(1):39-49. (SCI:DA1YU).
6.  

2015：

1. 1. Chen Zhenxian, Wang Ling, Liu Yaxiong, et al. Effect of Component Mal-rotation on the Knee Loading in Total Knee Arthroplasty using Multi-body Dynamics Modelling Under a Simulated Walking Gait[J]. Journal of Orthopaedic Research, 2015, 33(9): 1287–1296. (SCI:CO60E)
2. 2. Zhang Xuan, Chen Zhenxian, Wang L, et al. Prediction of hip joint load and translation using musculoskeletal modelling with force-dependent kinematics and experimental validation[J]. Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine. 2015. 229(7):477-490. (SCI:CL9LI)
3. 3. Qiao, F., Li, D., Jin, Z., Gao, Y., Zhou, T., He, J., & Cheng, L. (2015). Application of 3D printed customized external fixator in fracture reduction. Injury, 46(6), 1150-1155.
4. 4. Sun, C., Wang, L., Wang, Z., Geng, L. E. I., Li, D., Sui, M., & Jin, Z. (2015). Finite Element Analysis of a Retrieved Custom-Made Knee Prosthesis. Journal of Mechanics in Medicine and Biology, 15(03), 1550020.
5. 5. Gao, Y., Zhang, J., Jin, Z.. Explicit finite element modeling of kinematics and contact mechanics of artificial hip and knee joints. The 14th IFToMM World Congress,2015[C], Taipei, Taiwan.
6. 6. Gao, Y., Jin, Z., Wang, L. Wang, M. (2015) .Finite element analysis of sliding distance and contact mechanics of hip implant under dynamic walking conditions. Proc Inst Mech Eng H, 229(6), 469-474.
7. 7. Ardestani, M. M., M. Moazen and Z. Jin (2015). "Contribution of geometric design parameters to knee implant performance: Conflicting impact of conformity on kinematics and contact mechanics." The Knee 22(3): 217-224.
8. 8. Zhou, Z. R. and Z. M. Jin (2015). "Biotribology: Recent progresses and future perspectives." Biosurface and Biotribology 1(1): 3-24.
9. 9. Gao Y, Jin Z. Effect of inclination angle on kinematics and contact mechanics of dual mobility hip implant[C]. 8th International Biotribology Forμm and the 36th Japanese Biotribology Symposiμm, Yokohama, Japan, Sep. 21-22, 2015.
10. 10. 陈瑱贤，王玲，李涤尘，靳忠民. 全膝关节置换个体化患者右转步态的骨肌多体动力学仿真[J]. 医用生物力学 ，2015 ，30（5）：397-403
11. 11. 高永昌, 靳忠民. 表面织构对双动全髋关节运动学和接触力学影响. 第二屆臺灣磨潤科技研討會暨2015海峽兩岸學術研討會－CTTT2015 [C]. 台北：2015.
12.  

2014：

1. 1. 1. Ardestani MM, Chen Zhenxian, Wang L, et al. Feed forward artificial neural network to predict contact force at medial knee joint: Application to gait modification[J]. Neurocomputing, 2014, 139: 114-29. (SCI:AJ4QV)
   2. 2. Ardestani MM, Chen Zhenxian, Wang L, et al. A neural network approach for determining gait modifications to reduce the contact force in knee joint implant[J]. Medical Engineering & Physics. 2014, 36: 1253-65. (SCI:AR5ML)
   3. 3. Ardestani MM, Chen Zhenxian, et al. A real-time topography of maximum contact pressure distribution at medial tibiofemoral knee implant during gait: Application to knee rehabilitation[J]. Neurocomputing, 2014, 154:174–188. (SCI:CC1DR)
   4. 4. Chen Zhenxian, Zhang Xuan, Ardestani MM, et al. Prediction of in vivo joint mechanics of an artificial knee implant using rigid multi-body dynamics with elastic contacts[J]. Proceedings of the Institution of Mechanical Engineers Part H, Journal of engineering in medicine, 2014, 228:564–575. (SCI:AJ9NA)
   5. 5. Ardestani, M. M., M. Moazen and Z. Jin (2014). "Gait modification and optimization using neural network–genetic algorithm approach: Application to knee rehabilitation." Expert Systems With Applications 41(16): 7466-7477.
   6. 6. Ardestani, M. M., X. Zhang, L. Wang, Q. Lian, Y. Liu, J. He, D. Li and Z. Jin (2014). "Human lower extremity joint moment prediction: A wavelet neural network approach." Expert Systems With Applications 41(9): 4422-4433.
   7. 7. 张文友，贺健康，李翔，刘亚雄，边卫国，李涤尘, 靳忠民. (2014). "基于 3-D 打印技术的韧带 - 骨复合支架制造与体内植入研究." FABRICATION AND IN VlVO IMPLANTATION OF LIGAMENT-BONE COMPOSITE SCAFFOLDS BASED ON THREE-DIMENSIONAL PRINTING TECHNIQUE(3): 314.