Zinc doped silica nanoparticles gelatin methacrylate hydrogel on BMSCs cell viability and differentiation: Potential for rat mandibular bone defect repair
Restricted accessResearch articleFirst published online February, 2026
Zinc doped silica nanoparticles gelatin methacrylate hydrogel on BMSCs cell viability and differentiation: Potential for rat mandibular bone defect repair
The various maxillofacial bone defect caused by fractures, tumors, and inflammationsis challenging to repair clinically. Therefore, developing a functional material with bone tissue regeneration capabilities has significant practical importance. In this study, Zn doped silica nanoparticles were produced by microemulsion assisted sol-gel method and then different concentrations of nanoparticles was added to the gelatin methacrylated hydrogel to form the composite materials for potential rat mandibular bone defect repair. First, the elements of Zn, O, and Si were effectively integrated into nanoparticles. SEM analysis revealed the presence of Zn doped silica nanoparticles on the hydrogel’s surface. Second, the 0.2 ZnSNPs/GelMA had good biocompatibility, and the ability to effectively induce osteogenic differentiation in Bone marrow mesenchymal stem cells (BMSCs). Finally, in vivo 4 mm diameter circular bone defect repair experiments indicated that the 0.2 ZnSNPs/GelMA promoted new bone regeneration in vivo. Overall, we believe that composite material with good biocompatibility and excellent osteoinductive property will provide new ideas for enhancing the efficacy of hard tissue repair.
ShiZXuYMulatibiekeR, et al.Nano-silicate-reinforced and SDF-1α-Loaded gelatin-methacryloyl hydrogel for bone tissue engineering. Int J Nanomed2020; 15: 9337–9353.
2.
NogueiraLFBManigliaBCBuchetR, et al.Three-dimensional cell-laden collagen scaffolds: from biochemistry to bone bioengineering. J Biomed Mater Res B Appl Biomater2022; 110: 967–983.
3.
StoilovBTruongVKGronthosS, et al.Noninvasive and microinvasive nanoscale drug delivery platforms for hard tissue engineering. ACS Appl Bio Mater2023; 6: 2925–2943.
4.
BerberiAFayyad-KazanMAyoubS, et al.Osteogenic potential of dental and oral derived stem cells in bone tissue engineering among animal models: an update. Cell2021; 71: 101515.
5.
ZhangSLiXQiY, et al.Comparison of autogenous tooth materials and other bone grafts. Eng Regen Med2021; 18: 327–341.
6.
SmeetsRMatthiesLWindischP, et al.Horizontal augmentation techniques in the mandible: a systematic review. Int J Implant Dent2022; 8: 23.
7.
ParkHYJooMWChoiYH, et al.Simple curettage and allogeneic cancellous bone chip impaction grafting in solitary enchondroma of the short tubular bones of the hand. Sci Rep2023; 13: 2081.
8.
Meza-MauricioJFurquimCPDos ReisLD, et al.How efficacious is the combination of substitute bone graft with autogenous bone graft in comparison with substitute bone graft alone in the horizontal bone gain? A systematic review and meta-analysis. J Clin Exp Dent2022; 14: e678–e688.
9.
DecPModrzejewskiAPawlikA. Existing and novel biomaterials for bone tissue engineering. Int J Mol Sci2022; 24: 529.
10.
QiJYuTHuB, et al.Current biomaterial-based bone tissue engineering and translational medicine. Int J Mol Sci2021; 22: 10233.
11.
ZenebeCG. A review on the role of wollastonite biomaterial in bone tissue engineering. BioMed Res Int2022; 2022: 4996530.
12.
GuYZhangJZhangX, et al.Three-dimensional printed Mg-Doped β-TCP bone tissue engineering scaffolds: effects of magnesium ion concentration on osteogenesis and angiogenesis in vitro. Eng Regen Med2019; 16: 415–429.
13.
KongCHSteffiCShiZ, et al.Development of mesoporous bioactive glass nanoparticles and its use in bone tissue engineering. J Biomed Mater Res B Appl Biomater2018; 106: 2878–2887.
14.
ShiDShenJZhangZ, et al.Preparation and properties of dopamine-modified alginate/chitosan-hydroxyapatite scaffolds with gradient structure for bone tissue engineering. J Biomed Mater Res2019; 107: 1615–1627.
15.
SannaAFirinuDZavattariP, et al.Zinc status and autoimmunity: a systematic review and meta-analysis. Nutrients2018; 10: 68.
16.
ParkKHChoiYYoonDS, et al.Zinc promotes osteoblast differentiation in human mesenchymal stem cells via activation of the cAMP-PKA-CREB signaling pathway. Stem Cell Dev2018; 27: 1125–1135.
17.
ZhaoDWZuoKQWangK, et al.Interleukin-4 assisted calcium-strontium-zinc-phosphate coating induces controllable macrophage polarization and promotes osseointegration on titanium implant. Mater Sci Eng C2021; 118: 111512.
18.
BaiLSongPSuJ. Bioactive elements manipulate bone regeneration. Biomater Transl2023; 4: 248–269.
19.
QiaoWPanDZhengY, et al.Divalent metal cations stimulate skeleton interoception for new bone formation in mouse injury models. Nat Commun2022; 13: 535.
20.
KargozarSMozafariMGhodratS, et al.Copper-containing bioactive glasses and glass-ceramics: from tissue regeneration to cancer therapeutic strategies. Mater Sci Eng C2021; 121: 111741.
21.
SadeghianAKharazihaMKhoroushiM. Dentin extracellular matrix loaded bioactive glass/GelMA support rapid bone mineralization for potential pulp regeneration. Int J Biol Macromol2023; 234: 123771.
22.
KermaniFMollazadeh BeidokhtiSBainoF, et al.Strontium- and cobalt-doped multicomponent mesoporous bioactive glasses (MBGs) for potential use in bone tissue engineering applications. Materials2020; 13: 1348.
23.
Vallet-RegiMSalinasAJ. Mesoporous bioactive glasses for regenerative medicine. Mater Today Bio2021; 11: 100121.
24.
Vallet-RegíMColillaMIzquierdo-BarbaI, et al.Achievements in mesoporous bioactive glasses for biomedical applications. Pharmaceutics2022; 14: 2636.
25.
ChengSZhangDLiM, et al.Osteogenesis, angiogenesis and immune response of Mg-Al layered double hydroxide coating on pure Mg. Bioact Mater2020; 6: 91–105.
26.
LiJWangWLiM, et al.Biomimetic methacrylated gelatin hydrogel loaded with bone marrow mesenchymal stem cells for bone tissue regeneration. Front Bioeng Biotechnol2021; 9: 770049.
27.
ZhouJLiuWZhaoX, et al.Natural melanin/alginate hydrogels achieve cardiac repair through ROS scavenging and macrophage polarization. Adv Sci (Weinh)2021; 8: e2100505.
28.
WangWYeungKWK. Bone grafts and biomaterials substitutes for bone defect repair: a review. Bioact Mater2017; 2: 224–247.
29.
WeiBWangWLiuX, et al.Gelatin methacrylate hydrogel scaffold carrying resveratrol-loaded solid lipid nanoparticles for enhancement of osteogenic differentiation of BMSCs and effective bone regeneration. Regen Biomater2021; 8: rbab044.
30.
HeJSunYGaoQ, et al.Gelatin methacryloyl hydrogel, from standardization, performance, to biomedical application. Adv Healthcare Mater2023; 12: e2300395.
31.
ArmientoARHattLPSanchez RosenbergG, et al. Functional biomaterials for bone regeneration: a lesson in complex biology. Adv Funct Mater. 2020; 30: 1909874.
32.
LinCHSuJJLeeSY, et al.Stiffness modification of photopolymerizable gelatin-methacrylate hydrogels influences endothelial differentiation of human mesenchymal stem cells. J Tissue Eng Regen Med2018; 12: 2099–2111.
33.
GuanXAvci-AdaliMAlarçinE, et al. Development of hydrogels for regenerative engineering. Biotechnol J. 2017; May 12(5): 10.1002/biot.201600394. doi:10.1002/biot.201600394.
34.
PurohitSDBhaskarRSinghH, et al.Development of a nanocomposite scaffold of gelatin-alginate-graphene oxide for bone tissue engineering. Int J Biol Macromol2019; 133: 592–602.
35.
AbdulHNAHusseinMZKandarMK. Nanomaterials-upconverted hydroxyapatite for bone tissue engineering and a platform for drug delivery. Int J Nanomed2021; 16: 6477–6496.
36.
XinTGuYChengR, et al.Inorganic strengthened hydrogel membrane as regenerative periosteum. ACS Appl Mater Interfaces2017; 9: 41168–41180.
37.
YangZLiuXZhaoF, et al.Bioactive glass nanoparticles inhibit osteoclast differentiation and osteoporotic bone loss by activating lncRNA NRON expression in the extracellular vesicles derived from bone marrow mesenchymal stem cells. Biomaterials2022; 283: 121438.
38.
MengLZhaoPJiangY, et al.Extracellular and intracellular effects of bioactive glass nanoparticles on osteogenic differentiation of bone marrow mesenchymal stem cells and bone regeneration in zebrafish osteoporosis model. Acta Biomater2024; 174: 412–427.
39.
YangLGuoPNiuZ, et al.Influence of Mg on the mechanical properties and degradation performance of as-extruded ZnMgCa alloys: in vitro and in vivo behavior. J Mech Behav Biomed Mater2019; 95: 220–231.
40.
VimalrajS. Alkaline phosphatase: structure, expression and its function in bone mineralization. Gene2020; 754: 144855.
41.
JiaBYangHZhangZ, et al.Biodegradable Zn-Sr alloy for bone regeneration in rat femoral condyle defect model: in vitro and in vivo studies. Bioact Mater2020; 6: 1588–1604.
42.
QuXYangHJiaB, et al.Zinc alloy-based bone internal fixation screw with antibacterial and anti-osteolytic properties. Bioact Mater2021; 6: 4607–4624.
43.
ZhuDSuYYoungML, et al.Biological responses and mechanisms of human bone marrow mesenchymal stem cells to Zn and Mg biomaterials. ACS Appl Mater Interfaces2017; 9: 27453–27461.
44.
LiuJZhaoYZhangY, et al.Exosomes derived from macrophages upon Zn ion stimulation promote osteoblast and endothelial cell functions. J Mater Chem B2021; 9: 3800–3807.
45.
KaurGPandeyOPSinghK, et al.A review of bioactive glasses: their structure, properties, fabrication and apatite formation. J Biomed Mater Res2014; 102: 254–274.
46.
OzakiMTakayamaTYamamotoT, et al.A collagen membrane containing osteogenic protein-1 facilitates bone regeneration in a rat mandibular bone defect. Arch Oral Biol2017; 84: 19–28.
47.
ZhangWShiWWuS, et al.3D printed composite scaffolds with dual small molecule delivery for mandibular bone regeneration. Biofabrication2020; 12: 035020.
