代表性学术论著:
[1] Juyang Jiao, Qimin Hong, Dachen Zhang, Minqi Wang, Haozheng Tang, Jingzhou Yang*, Xinhua Qu*, Bing Yue*. Influence of porosity on osteogenesis, bone growth and osteointegration in trabecular tantalum scaffolds fabricated by additive manufacturing. Frontiers in Bioengineering and Biotechnology, 2023, DOI:10.3389/fbioe.2023.1117954 (Q1, IF=6.1)
[2] Faqiang Zhang#, Yangbo Zuo#, Kesheng Zhang, Hairui Gao, Shupei Zhang, Haishen Chen, Guangwang Liu, Xia Jin*, and Jingzhou Yang*. Fabrication of Zirconia Ceramic Dental Crowns by Digital Light Processing: Effects of the Process on Physical Properties and Microstructure, 3D Printing and Additive Manufacturing, 2023, doi/10.1089/3dp.2022.0342 (Q2, IF=5.4)
[3] Qi Liu#, Jingzhou Yang#, Yingjie Wang, Tianhao Wu, Yuting Liang, Keqi Deng, Guifang Luan, Yutong Chen, Zhenkai Huang, Kan Yue*. Direct 3D Bioprinting of Tough and Antifatigue Cell-Laden Constructs Enabled by a Self-Healing Hydrogel Bioink. Biomacromolecules,2023,24,6,2549–2562 (Q1, IF=7.0)
[4] Faqiang Zhang, Jingzhou Yang, Yangbo Zuo, et al. Digital light processing of β-tricalcium phosphate bioceramic scaffolds with controllable porous structures for patient specific craniomaxillofacial bone reconstruction.Materials & Design,2022,216:110558. (Q1, IF=7.991)
[5] Hairui Gao, Jingzhou Yang, Xia Jin, et al. Porous tantalum scaffolds: Fabrication, structure, properties, and orthopedic applications. Materials & Design, 2021, 210: 110095. (Q1, IF=7.991)
[6] Hairui Gao, Xia Jin, Jingzhou Yang, et al. Porous structure and compressive failure mechanism of additively manufactured cubic-lattice tantalum scaffolds. Materials Today Advances, 2021, 12: 100183. (Q1, IF=7.579)
[7] Hairui Gao#, Jingzhou Yang#,*, Xia Jin*, Dachen Zhang, Shupei Zhang, Faqiang Zhang, Haishen Chen. Static compressive behavior and failure mechanism of tantalum scaffolds with optimized periodic lattice fabricated by laser-based additive manufacturing. 3D Printing and Additive Manufacturing, 2022, DOI:10.1089/3dp.2021.0253 (Q2, IF=5.4)
[8] Jingzhou Yang1, Hairui Gao1, Dachen Zhang, et al. Static compressive behavior and material failure mechanism of trabecular tantalum scaffolds fabricated by laser powder bed fusion-based additive manufacturing. International Journal of Bioprinting, 2021, 8(1). (Q1, IF=6.638)
[9] Jingzhou Yang, Xia Jin, Hairui Gao, et al. Additive manufacturing of trabecular tantalum scaffolds by laser powder bed fusion: Mechanical property evaluation and porous structure characterization. Materials Characterization, 2020, 170: 110694. (Q1, IF=4.342)
[10] Wenliang Chen, Jingzhou Yang, Hui Kong, Mark Helou, Dachen Zhang, Jinhui Zhao, Weitao Jia, Qian Liu, Peidong He, Xiaopeng Li. Fatigue behaviour and biocompatibility of additively manufactured bioactive tantalum graded lattice structures for load-bearing orthopaedic applications. Materials Science & Engineering C,2021,130:112461.(Q1,IF=7.328)
[11]Jingzhou Yang, 《Orthopedic Biomaterials: Progress in Biology, Manufacturing and Industry Perspectives》, Chapter 18, Progress of Bioceramic and Bioglass Bone Scaffolds for Load-Bearing Applications, Springer Publisher, 2018, ISBN: 978-3-319-89541-3. Chief Editor: Thomas Webster, Bingyun Li. (专著章节)
[12]Yang JZ, Hu XZ, Huang JT, Huang ZH, YG Liu, Sun XD. Novel porous calcium aluminate/phosphate nanocomposites: in situ synthesis, microstructure and permeability. Nanoscale 2016, 8, 3599 – 3606. (SCI 期刊,影响因子=7.233)
[13]Yang JZ, YS Zhang, PF Lei, XZ Hu, M Wang, HT Liu, XL Shen, K Li, ZH Huang, JT Huang, J Ju, YH Hu, A Khademhosseini. Biofunctional Layered Hybrid Cage for Spine Fusion and Segmental Bone Reconstruction, ACS Biomaterials Science and Engineering 2017, 3 (4), 637–647. (SCI 期刊,影响因子=4.432)
[14]Yang JZ, Zhang YS, Yue K, Khademhosseini A, Cell-Laden Hydrogels for Osteochondral and Cartilage Tissue Engineering. Acta Biomaterialia, S1742-7061 (17) 30036-3. DOI: 10.1016/j.actbio.2017.01.036. (SCI 期刊,影响因子=6.383)
[15]YS Zhang, WJ Liu, MA Heinrich, FD Ferrari, SM Bakht, HL Jiang, MM Alvarez, JZ Yang, YC Li, GT Santiago, AK Miri, P Khoshakhlagh, G Prakash, H Cheng, XF Guan, Z Zhong, SR Shin, J Ju, G Zhu, E Laukaitis, MR Dokmeci, XY Jin, A Khademhosseini. Rapid Continuous Multi-Materials Extrusion Bioprinting. Advanced Materials 2017, 29(3):1604630 DOI: 10.1002/adma.201604630. (SCI 期刊,影响因子=21.95)
[16]Guoliang Ying; Nan Jiang; Sushila Maharjan; Yixia Yin; Rongrong Chai; Xia Cao; Jingzhou Yang; Amir K. Miri; Shabir Hassan; Yu Shrike Zhang. Aqueous Two Phase Emulsion Bioink Enabled 3D Bioprinting of Porous Hydrogels. Advanced Materials, 2018 DOI: 10.1002/adma.201805460 (SCI 期刊,影响因子=21.95)
[17]Yang JZ, Hu XZ, Sultana R, Day RE, Ichim P. Structure design and manufacturing of bioceramic scaffolds for load-bearing bone reconstruction. Biomedical Materials 2015; 10:045006. (SCI 期刊,影响因子=2.897)
[18]Yang JZ, Sultana R, Hu XZ, Ichim P. Novel Layered Hydroxyapatite/Tri-Calcium Phosphate-Zirconia Scaffold Composite with High Bending Strength for Load-Bearing Bone Implant Application. International Journal of Applied Ceramics Technology, 2014;1-9. (SCI 期刊,影响因子=1.53)
[19]Yang JZ, Sultana R, Ichim P, Hu XZ, Huang ZH, Yi W, Jiang B, Xu YG. Micro-porous calcium phosphate coatings on load-bearing zirconia substrate: processing, property and application. Ceramics International, 2013, 39 (6): 6533-42. (SCI 期刊,影响因子=3.057)
[20]Sultana R, Yang JZ, Hu XZ. Deposition of Micro-Porous Hydroxyapatite/Tri-Calcium Phosphate Coating on Zirconia-Based Substrate. Journal of the American Ceramic Society 2012;95:1212-1215. (SCI 期刊,影响因子=2.956)
[21]Yang JZ, Sultana R, Hu XZ, Huang ZH. Porous Hydroxyapatite Coating on Strong Ceramic Substrate Fabricated by Low Density Slip Coating-Deposition and Coating-Substrate Co-sintering. Journal of the European Ceramic Society 2011;31:2065-2071. (SCI 期刊,影响因子=3.794)
[22]Yang JZ, Fang MH, Huang ZH, Hu XZ, Liu YG, Sun HR, Huang JT, Li XC. Solid particle erosion of alumina-based refractories at elevated temperatures. Journal of the European Ceramic Society 2012;32:283-289. (SCI 期刊,影响因子=3.794)
[23]Huang ZH , Yang JZ, Liu YG, Fang MH, Huang JT, Sun HR, Huang SF. Novel Sialon based ceramics toughened by ferro-molybdenum alloy. Journal of the American Ceramic Society 2012;95:859-861. (SCI 期刊,影响因子=2.956)
[24]Zhang CG, Yang JZ, Hu XZ, Lu PM, Zhao MM. Microstructure characteristics and fatigue properties of welded HSLA with and without buffer layer. Materials Science and Engineering: A 2012;546:169-179. (SCI 期刊,影响因子=2.108)
[25]Yang JZ, Huang ZH, Hu XZ, Fang MH, Liu YG, Huang JT. Microstructure characteristics of FeMo-Sialon ceramic composite. Materials Science and Engineering A 2011;528:2196-2199. (SCI 期刊,影响因子=2.108,JCR一区))
[26]Yang JZ, Huang ZH, Fang MH, Liu YG, Huang JT, Hu JH. Preparation and mechanical properties of Fe/Mo-Sialon ceramic composites. Scripta Materialia 2009;61:632-635. (SCI 期刊,影响因子=4.163)
[27]Jing-Zhou Yang, Zhao-Hui Huang, Ming-Hao Fang, Xiao-Zhi Hu, Yan-Gai Liu, Hao-Ran Sun. Reaction sintered Fe-Sialon ceramic composite: Processing, characterization and high temperature erosion wear behaviour. Journal of Asian Ceramic Societies 2013, 1: 163-169
[28]YS Zhang, K Yue, J Aleman, KM Moghaddam, SM Bakht, JZ Yang, V Dell’Erba, P Assawes, SR Shin, R Oklu, M Dokmeci, A Khademhosseini. 3D Bioprinting for Tissue and Organ Fabrication. Annals of Biomedical Engineering 2016, PP 1-16. (SCI 期刊,影响因子=3.405)
[29]Liu HT, Huang ZH, Huang JT, Yang JZ, Liu YG, Wu XW. Unique single-crystal TiN1+x nano-rods: synthesis, electrical transportation, and electric field effect conductivity. Materials and Design 111 (2016) 541–547. (EI期刊,影响因子=3.50)