[1] Dagnelie P C, Willems P C, Jørgensen N R. Nutritional status as independent prognostic factor of outcome and mortality until five years after hip fracture: a comprehensive prospective study[J]. Osteoporos Int, 2024, 35(7): 1273-1287.
[2] Woloszyk A, Tuong Z K, Perez L, et al. Fracture hematoma micro-architecture influences transcriptional profile and plays a crucial role in determining bone healing outcomes[J]. Biomater Adv, 2022, 139: 213027.
[3] Brown M G, Brady D J, Healy K M, et al. Stem cells and acellular preparations in bone regeneration/fracture healing: current therapies and future directions[J]. Cells, 2024, 13(12): 1045.
[4] Desbiens L C, Goupil R, Sidibé A, et al. Fracture status in middle-aged individuals with early CKD: cross-sectional analysis of the CARTaGENE survey[J]. Osteoporos Int, 2019, 30(4): 787-795.
[5] Liu M, Wang X, Sun B, et al. Electrospun membranes chelated by metal magnesium ions enhance pro-angiogenic activity and promote diabetic wound healing[J]. Int J Biol Macromol, 2024, 259(Pt 2): 129283.
[6] Chen Z, Jin M, He H, et al. Mesenchymal stem cells and macrophages and their interactions in tendon-bone healing[J]. J Orthop Translat, 2023, 39: 63-73.
[7] Zhang Y, Shu T, Wang S, et al. The osteoinductivity of calcium phosphate-based biomaterials: a tight interaction with bone healing[J]. Front Bioeng Biotech, 2022, 10: 911180.
[8] Rifah S S, Zaman M S, Piya A A, et al. Exploring the anodic performance of ScSeS and TiSeS monolayers of modified transition metal dichalcogenides for Mg ion batteries via DFT calculations[J]. Phys Chem Chem Phys, 2024, 26(8): 6667-6677.
[9] Yang Q, Sun X, Ding Q, et al. An ATP-responsive metal-organic framework against periodontitis via synergistic ion-interference-mediated pyroptosis[J]. Natl Sci Rev, 2024, 11(8): nwae225.
[10] Zawisza B, Sitko R, Gagor A. Determination of ultra-trace gold in cosmetics using aluminum-magnesium layered double hydroxide/graphene oxide nanocomposite[J]. Talanta, 2022, 245: 123460.
[11] Liu C, Bian X, Kwok R T K, et al. Biological synthesis and process monitoring of an aggregation-induced emission luminogen-based fluorescent polymer[J]. JACS Au, 2022, 2(9): 2162-2168.
[12] Chopra H, Bibi S, Singh I, et al. Green metallic nanoparticles: biosynthesis to applications[J]. Front Bioeng Biotechnol, 2022, 10: 874742.
[13] Liu H, Wang X. Esophageal organoids: applications and future prospects[J]. J Mol Med(Berl), 2023, 101(8): 931-945.
[14] Chormey D S, Zaman B T, Borahan Kustanto T, et al. Biogenic synthesis of novel nanomaterials and their applications[J]. Nanoscale, 2023, 15(48): 19423-19447.
[15] Tariq M, Mohammad K N, Ahmed B, et al.Biological synthesis of silver nanoparticles and prospects in plant disease management[J]. Molecules, 2022, 27(15): 4754.
[16] Oladipo A O, Nkambule T T I, Mamba B B, et al. Therapeutic nanodendrites: current applications and prospects[J]. Nanoscale Adv, 2020, 2(11): 5152-5165.
[17] Chandrasekaran R, Patil S, Krishnan M, et al.The characteristics of Green-synthesized magnesium oxide nanoparticles(MgONPs) and their biomedical applications[J]. Mini Rev Med Chem, 2023, 23(9): 1058-1069.
[18] Khalid A, Norello R, N Abraham A, et al. Biocompatible and biodegradable magnesium oxide nanoparticles with in vitro photostable near-infrared emission: short-term fluorescent markers[J]. Nanomaterials(Basel), 2019, 9(10): 1360.
[19] Pryjmaková J, Vokatá B, Slepicka P, et al. Laser-processed PEN with Au nanowires array: a biocompatibility assessment[J]. Int J Mol Sci, 2022, 23(18): 10953.
[20] Wang G, Luo J, Qiao Y, et al. AMPK/mTOR pathway is involved in autophagy induced by magnesium-incorporated TiO2 surface to promote BMSC osteogenic differentiation[J]. J Funct Biomater, 2022, 13(4): 221.
[21] Yan Z, Sun T, Tan W, et al. Magnetic field boosts the transmembrane transport efficiency of magnesium ions from PLLA bone scaffold[J]. Small, 2023, 19(40): e2301426.
[22] 纪振冰. 3D打印Ti-6Al-4V植入体表面功能化及其生物相容性研究[D]. 济南:山东大学, 2024.
[23] Zhao Y, He P, Wang B, et al. Incorporating pH/NIR responsive nanocontainers into a smart self-healing coating for a magnesium alloy with controlled drug release, bacteria killing and osteogenesis properties[J]. Acta Biomater, 2024, 174: 463-481.
[24] Zhao Y, He P, Yao J, et al. pH/NIR-responsive and self-healing coatings with bacteria killing, osteogenesis, and angiogenesis performances on magnesium alloy[J]. Biomaterials, 2023, 301: 122237.
[25] Laurenti M, Al Subaie A, Abdallah M N,et al. Two-dimensional magnesium phosphate nanosheets form highly thixotropic gels that up-regulate bone formation[J]. Nano Lett, 2016, 16(8): 4779-4787.
[26] Qi T, Weng J, Yu F, et al. Insights into the role of magnesium ions in affecting osteogenic differentiation of mesenchymal stem cells[J]. Biol Trace Elem Res, 2021, 199(2): 559-567.
[27] Wang C, Liu J, Min S, et al. The effect of pore size on the mechanical properties, biodegradation and osteogenic effects of additively manufactured magnesium scaffolds after high temperature oxidation: an in vitro and in vivo study[J]. Bioact Mater, 2023, 28: 537-548.
[28] Yang M, Cai X, Wang C,et al. Highly stable amorphous(Pyro)phosphate aggregates: pyrophosphate as a carrier for bioactive ions and drugs in bone repair applications[J]. ACS Omega, 2024, 9(22): 23724-23740.
[29] 乔昕瑞. 纯钛表面二氧化钛纳米管注入镁离子对成骨性能的影响[D]. 天津:天津医科大学, 2021.
[30] 景玺瑞. 光响应多功能水凝胶用于感染性骨缺损抗菌与成骨治疗的实验研究[D]. 武汉:华中科技大学, 2024.
[31] Li J, Ke H, Lei X, et al. Controlled-release hydrogel loaded with magnesium-based nanoflowers synergize immunomodulation and cartilage regeneration in tendon-bone healing[J]. Bioact Mater, 2024, 36: 62-82.
[32] Zhao Y, Liang H, Zhang S, et al. Effects of magnesium oxide(MgO) shapes on in vitro and in vivo degradation behaviors of PLA/MgO composites in long term[J]. Polymers(Basel), 2020, 12(5): 1074.
[33] Pan H, Gao H, Li Q, et al. Engineered macroporous hydrogel scaffolds via pickering emulsions stabilized by MgO nanoparticles promote bone regeneration[J]. J Mater Chem B, 2020, 8(28): 6100-6114.
[34] Chen R, Chen H B, Xue P P, et al. HA/MgO nanocrystal-based hybrid hydrogel with high mechanical strength and osteoinductive potential for bone reconstruction in diabetic rats[J]. J Mater Chem B, 2021, 9(4): 1107-1122.
[35] Huang L, Cai P, Bian M, et al. Injectable and high-strength PLGA/CPC loaded ALN/MgO bone cement for bone regeneration by facilitating osteogenesis and inhibiting osteoclastogenesis in osteoporotic bone defects[J]. Mater Today Bio, 2024, 26: 101092
[36] Zhang K, Lin S, Feng Q, et al. Nanocomposite hydrogels stabilized by self-assembled multivalent bisphosphonate-magnesium nanoparticles mediate sustained release of magnesium ion and promote in-situ bone regeneration[J]. Acta Biomater, 2017, 64: 389-400.
[37] Nan J, Liu W, Zhang K, et al. Tantalum and magnesium nanoparticles enhance the biomimetic properties and osteo-angiogenic effects of PCL membranes[J]. Front Bioeng Biotechnol, 2022, 10: 1038250.
[38] Zhang X, Gong C, Wang X, et al. A bioactive gelatin-methacrylate incorporating magnesium phosphate cement for bone regeneration[J]. Biomedicines, 2024, 12(1): 228.
[39] Pei M, Li P, Guo X, et al. Sustained release of hydrogen and magnesium ions mediated by a foamed gelatin-methacryloyl hydrogel for the repair of bone defects in diabetes[J]. ACS Biomater Sci Eng, 2024, 10(7): 4411-4424.
[40] 黄锦锋.负载工程化黑磷纳米片的丝素蛋白水凝胶构建及其促骨缺损修复作用的研究[D]. 西安:空军军医大学,2024.
[41] 刘明月. 含硅/镁复合纳米纤维材料的制备及应用于皮肤/骨组织再生的研究[D]. 上海:东华大学, 2024.
[42] 刘书博. 基于三维纳米复合支架镁离子可控释放介导的CD4~+T细胞骨免疫调节及其机理研究[D]. 广州:南方医科大学, 2024.
[43] Li X, Dai B, Guo J, et al. Biosynthesized bandages carrying magnesium oxide nanoparticles induce cortical bone formation by modulating endogenous periosteal cells[J]. ACS Nano, 2022, 16(11): 18071-18089.
[44] Li D, Dai D, Wang J, et al. Honeycomb bionic graphene oxide quantum dot/layered double hydroxide composite nanocoating promotes osteoporotic bone regeneration via activating mitophagy[J]. Small, 2024, 20(50): e2403907.
[45] Zheng Z, Chen Y, Hong H, et al. The “Yin and Yang” of immunomodulatory magnesium-enriched graphene oxide nanoscrolls decorated biomimetic scaffolds in promoting bone regeneration[J]. Adv Healthc Mater, 2021, 10(2): e2000631.
[46] Perumal G, Ramasamy B, Nandkumar A M, et al. Bilayer nanostructure coated AZ31 magnesium alloy implants: in vivo reconstruction of critical-sized rabbit femoral segmental bone defect[J]. Nanomedicine, 2020, 29: 102232.
[47] 成伟男. 丝蛋白可注射凝胶的血管化和骨诱导性优化及其促进骨愈合的研究[D].苏州:苏州大学, 2023.
[48] Zhang Z, Gong N, Wang Y, et al. Impact of strontium, magnesium, and zinc ions on the in vitro osteogenesis of maxillary sinus membrane stem cells[J]. Biol Trace Elem Res, 2024.
[49] Li C, Sun J, Shi K, et al. Preparation and evaluation of osteogenic nano-MgO/PMMA bone cement for bone healing in a rat critical size calvarial defect[J]. J Mater Chem B, 2020, 8(21): 4575-4586.
[50] Lee H, Shin D Y, Na Y, et al. Antibacterial PLA/Mg composite with enhanced mechanical and biological performance for biodegradable orthopedic implants[J]. Biomater Adv, 2023, 152: 213523.
[51] Wang W, Song Y, Tian Y, et al. TCPP/MgO-loaded PLGA microspheres combining photodynamic antibacterial therapy with PBM-assisted fibroblast activation to treat periodontitis[J] Biomater Sci, 2023, 11(8): 2828-2844.
[52] Varsavas S D, Michalec P, Khalifa M, et al. Cytocompatibility of polymers for skin-contact applications produced via pellet extrusion[J]. J Funct Biomater, 2024, 15(7): 179.
[53] Sood K, Shanavas A. Autologous serum protein stabilized silver quantum clusters as host-specific antibacterial agents[J]. Nanomedicine(Lond), 2024, 19(21-22): 1761-1778.
[54] Foo M A, You M, Chan S L, et al. Clinical translation of patient-derived tumour organoids- bottlenecks and strategies[J]. Biomark Res, 2022, 10(1): 10.