专著和著名期刊专辑
[1] 张胜民、翁杰 主编,《生物医用陶瓷》 , 科学出版社,北京,2022
[2] 尹光福,张胜民著,《生物医学材料学:材料生物学》,人民卫生出版社,北京,2021
[3] Ma J. , Tan S. , Zhang S. (2018) Biomimetic lon-Substituted Calcium Phosphates. ln: Liu C. , He H. (eds) Devel-opments and Applications of Calcium Phosphate Bone Cements. Springer Series in Biomaterials Science and Engineering, vol 9, Springer, Singapore, https://do.org/10.1007/978-981-10-5975-9_8
[4] Shengmin Zhang and Antonios G. Mikos. Special lssue: Biomaterials for Repenerative Medicine. Advanced Healthcare Materials, Wiley 出版社,02 Dec 2020
代表性论文
一、新理论新技术
[1] 3D micropattern force triggers YAP nuclear entry by transport across nuclear pores and modulates stem cells paracrine. NATIONAL SCIENCE REVIEW, 2023, 10(8):nwad165
[2] Polymeric Systems for Bioprinting. CHEMICAL REVIEWS, 2020, 120(19):10547-10595
[3] Bioenergetic-active materials enhance tissue regeneration by modulating cellular metabolic state. SCIENCE ADVANCES, 2020, 6(13):eaay7608
[4] Nanoparticulate cell-free DNA scavenger for treating inflammatory bone loss in periodontitis. NATURE COMMUNICATIONS, 2022, 13(1):5925
[5] Hypoxia-triggered exosomemimetics accelerate vascularized osteogenesis. MATERIALS TODAY, 2023:10.1016/j.mattod.2023.09.026
[6] Bioinspired membrane provides periosteum-mimetic microenvironment for accelerating vascularized bone regeneration. BIOMATERIALS, 2021, 268: 120561
[7] Hierarchically designed bone scaffolds: From internal cues to external stimuli. BIOMATERIALS, 2019, 218:119334
[8] Injectable scaffolds for in vivo programmed macrophages manufacture and postoperative cancer immunotherapy. ADVANCED FUNCTIONAL MATERIALS, 2023, 33(26):2300058
[9] Micropatterned composite membrane guides oriented cell growth and vascularization for accelerating wound healing. REGENERATIVE BIOMATERIALS, 2023, 10 :rbac108
[10] A high-strength biodegradable thermoset polymer for internal fixation bone screws: Preparation, in vitro and in vivo evaluation. COLLOIDS AND SURFACES B-BIOINTERFACES, 2019, 183:110445
二、活性元素掺杂CaP 生物材料
[11] Novel calcium silicate/calcium phosphate composites for potential applications as injectable bone cements. BIOMEDICAL MATERIALS, 2008, 3(4):44102
[12] Fine structure study on low concentration zinc substituted hydroxyapatite nanoparticles. MATERIALS SCIENCE & ENGINEERING C-MATERIALS FOR BIOLOGICAL APPLICATIONS, 2012, 32(8):2404-2410
[13] Dual functional selenium-substituted hydroxyapatite. INTERFACE FOCUS, 2012, 2(3):378-386
[14] Preparation and characterization of selenite substituted hydroxyapatite. MATERIALS SCIENCE & ENGINEERING C-MATERIALS FOR BIOLOGICAL APPLICATIONS, 2013, 33(1):440-445
[15] Silicate-doped hydroxyapatite and its promotive effect on bone mineralization. FRONTIERS OF MATERIALS SCIENCE, 2013, 7(1):40-50
[16] Electrophoretic deposition of zinc-substituted hydroxyapatite coatings. MATERIALS SCIENCE & ENGINEERING C-MATERIALS FOR BIOLOGICAL APPLICATIONS, 2014, 39:67-72
[17] Synthesis and thermal stability of selenium-doped hydroxyapatite with different substitutions. FRONTIERS OF MATERIALS SCIENCE, 2015, 9(4):392-396
[18] Selenite-Releasing Bone Mineral Nanoparticles Retard Bone Tumor Growth and Improve Healthy Tissue Functions In Vivo. ADVANCED HEALTHCARE MATERIALS, 2015, 4(12):1813-1818
[19] Repair of Rat Calvarial Defects Using Si-Doped Hydroxyapatite Scaffolds Loaded With a Bone Morphogenetic Protein-2-Related Peptide. JOURNAL OF ORTHOPAEDIC RESEARCH, 2016, 34(11):1874-1882
[20] In Vitro and in Vivo Mechanism of Bone Tumor Inhibition by Selenium-Doped Bone Mineral Nanoparticles. ACS NANO, 2016, 10(11):9927-9937
[21] Si-doping bone composite based on protein template-mediated assembly for enhancing bone regeneration. FRONTIERS OF MATERIALS SCIENCE, 2017, 11(2):106-119
[22] Selective laser sintering scaffold with hierarchical architecture and gradient composition for osteochondral repair in rabbits. BIOMATERIALS, 2017, 137:37-48
[23] 3D printing of strontium-doped hydroxyapatite based composite scaffolds for repairing critical-sized rabbit calvarial defects. BIOMEDICAL MATERIALS, 2018, 13(6) :65004
[24] Assembly Mechanism of Highly Crystalline Selenium-Doped Hydroxyapatite Nanorods via Particle Attachment and Their Effect on the Fate of Stem Cells. ACS BIOMATERIALS SCIENCE & ENGINEERING, 2019, 5(12):6703-6714
[25] Biomimetic synthesis of Mg-substituted hydroxyapatite nanocomposites and three-dimensional printing of composite scaffolds for bone regeneration. JOURNAL OF BIOMEDICAL MATERIALS RESEARCH PART A, 2019, 107(11):2512-2521
[26] Hierarchically constructed selenium-doped bone-mimetic nanoparticles promote ROS-mediated autophagy and apoptosis for bone tumor inhibition. BIOMATERIALS, 2020, 257:120253
[27] Enhanced effect of nano-monetite hydrosol on dentin remineralization and tubule occlusion. DENTAL MATERIALS , 2020, 36(6):816-825
[28] Injectable bone cement with magnesium-containing microspheres enhances osteogenesis via anti-inflammatory immunoregulation. BIOACTIVE MATERIALS, 2021, 6(10):3411-3423
[29] Zn/Sr dual ions-collagen co-assembly hydroxyapatite enhances bone regeneration through procedural osteo-immunomodulation and osteogenesis. BIOACTIVE MATERIALS, 2022, 10:195-206
[30] Nanoparticulate cell-free DNA scavenger for treating inflammatory bone loss in periodontitis. NATURE COMMUNICATIONS, 2022, 13(1):5925
[31] 双离子掺杂轻基磷灰石材料及其在硬组织工程中的应用.硅酸盐学报,2023,51(10): 2566-2578
三、双分子模板共组装技术及仿生矿化
[32] Biomimetic apatite formation on calcium phosphate-coated titanium in Dulbecco's phosphate-buffered saline solution containing CaCl2 with and without fibronectin. ACTA BIOMATERIALIA, 2010, 6(6):2274-2281
[33] Collagen/silk fibroin bi-template induced biomimetic bone-like substitutes. JOURNAL OF BIOMEDICAL MATERIALS RESEARCH PART A, 2011, 99A(3):327-334
[34] Biomimetic fibronectin/mineral and osteogenic growth peptide/mineral composites synthesized on calcium phosphate thin films. CHEMICAL COMMUNICATIONS, 2011, 47(39):11056-11058
[35] Osteogenic differentiation of bone marrow mesenchymal stem cells on the collagen/silk fibroin bi-template-induced biomimetic bone substitutes. JOURNAL OF BIOMEDICAL MATERIALS RESEARCH PART A, 2012, 100A(11):2929-2938
[36] Biomimetic self-assembly of apatite hybrid materials: From a single molecular template to bi-/multi-molecular templates. BIOTECHNOLOGY ADVANCES, 2014, 32(4):744-760
[37] Graphene-like Zinc Substituted Hydroxyapatite. CRYSTAL GROWTH & DESIGN, 2015, 15(3):1273-1279
[38] Chimeric Protein Template-Induced Shape Control of Bone Mineral Nanoparticles and Its Impact on Mesenchymal Stem Cell Fate. BIOMACROMOLECULES, 2015, 16(7):1987-1996
[39] Bio-inspired hybrid nanoparticles promote vascularized bone regeneration in a morphology-dependent manner. NANOSCALE, 2017, 9 (18): 5794-5805
[40] Si-doping bone composite based on protein template-mediated assembly for enhancing bone regeneration. FRONTIERS OF MATERIALS SCIENCE, 2017, 11(2):106-119
[41] 3D printing of strontium-doped hydroxyapatite based composite scaffolds for repairing critical-sized rabbit calvarial defects. BIOMEDICAL MATERIALS, 2018, 13(6) :65004
[42] Biomimetic synthesis of Mg-substituted hydroxyapatite nanocomposites and three-dimensional printing of composite scaffolds for bone regeneration. JOURNAL OF BIOMEDICAL MATERIALS RESEARCH PART A, 2019, 107(11):2512-2521
[43] Zn/Sr dual ions-collagen co-assembly hydroxyapatite enhances bone regeneration through procedural osteo-immunomodulation and osteogenesis. BIOACTIVE MATERIALS, 2022, 10:195-206