A Review of the Application of Natural and Synthetic Scaffolds in Bone Regeneration
Abstract
:1. Introduction
2. The Application of Natural Scaffolds
2.1. Animal and Human-Derived Scaffolds
Type of Scaffold | Type of Model | Findings | Reference |
---|---|---|---|
Decellularised bone scaffold from the cancellous bovine femur | Rat bone marrow mesenchymal stem cells | -The decellularised scaffolds had no host cells with a bone trabecular-to-bone surface ratio similar to the native bone samples. -Cells were distributed between bone trabeculae and cell numbers were increased in the decellularised scaffolds after seeding with rat bone marrow mesenchymal stem cells. | [14] |
Decellularised bone marrow scaffold from the bovine metatarsal and metacarpal bone | hBMSCs | -The decellularised scaffold had no cells and well-arranged bone marrow extracellular matrix components, including adipose tissues, vessels, collagen III, collagen IV, and fibronectin. -The mechanical strength of the decellularised scaffolds was of the same magnitude as that of the native bones. -The decellularised scaffold supported cell growth and adhesion. | [15] |
Demineralised bovine bone matrix scaffold | Human umbilical cord mesenchymal stem cells | -The demineralised scaffold had a lower remaining weight after 14 days of incubation with the cells. -The demineralised scaffold supported cell attachment and biomineralization. | [19] |
Demineralised bovine trabecular bone scaffold | Co-culture of hFOB1.19 and hPBMCs | -Successful colonisation of osteoblasts on the demineralised scaffold. -The demineralised scaffold had increased BMD and BMC. | [20] |
Cuttlefish bone scaffold | MC3T3-E1 cells | -The expressions of ALP and OCN were increased. | [22] |
Fish scale-derived hydroxyapatite scaffold | MG63 cells | -The cells cultured on the fish scale-derived hydroxyapatite scaffold and the control hydroxyapatite without fish scales had similar viability. | [24] |
Albino rabbit with three bone defects (2 mm each) at the cortex region of the femur | -Infiltration of new cells onto the scaffold and new cell lining were noted at the defect site implanted with fish scale-derived hydroxyapatite scaffold. | ||
Cockle shell powder nanobiocomposite bone scaffold | MG63 cells | -The scaffold had an ideal pore size range (50–336 μm), a moderate degradation rate, increased compressive strength, elasticity, and cell proliferation rate. | [26] |
Tutoplast®-processed human bone | Male SCID mice (n = 6, 7 weeks old) | -Increase in bone formation and cell adhesion on the Tutoplast®-processed human bone than on the hydroxyapatite/β-tricalcium phosphate (β-TCP). | [27] |
COL1 + chondroitin-6-sulphate | MC3T3-E1 cells | -Allowed cell growth and cell infiltration. | [30] |
Male Wistar rats with calvarial defect | -A higher bone area and percentage of bone healing were seen in the defects grafted with collagen–glycosaminoglycan scaffold than in the defects that were left empty. -A similar bone area and percentage of bone healing were seen between the groups implanted with collagen–glycosaminoglycan and autologous bone. | [29] | |
Composite scaffold (eggshell membrane + bovine bone ash + gelatin + chitosan) | Amniotic fluid stem cells | -A higher cell viability and lower oxidative stress level in the cells cultured on the composite scaffold. | [31] |
2.2. Plant-Derived Scaffolds
3. The Application of Semi-Synthetic and Synthetic Scaffolds
3.1. Calcium Phosphate Cement and Hydroxyapatite
3.2. Bioglasses
3.3. Chitosan Composite
3.4. Hydrogel
3.5. Polymethyl Methacrylate (PMMA)
3.6. Synthetic Biodegradable Polymers
4. Perspectives
5. Conclusions
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Type of Scaffold | Type of Model | Findings | Reference |
---|---|---|---|
Apple-, broccoli-, sweet pepper-, carrot-, persimmon-, and jujube-derived scaffold | Pluripotent stem cells | -Increased cell viability in apple-derived scaffold. -Cells remained poorly spread and proliferated in other types of plant scaffolds. | [34] |
Apple-derived scaffold | Pluripotent stem cells undergoing osteoblastic differentiation | -Increased cell viability, proliferation, mineralisation, expression of OCN, COL1, and sclerostin (SOST). | |
Male Sprague–Dawley with calvarial defect | -Increased bone volume/total volume (BV/TV), bone regeneration area, calcium deposition, and blood vessel formation with no sign of inflammation. | ||
Carrot-derived scaffold | MC3T3-E1 cells | -Readily available, low-cost, and ethical compared to animal-derived scaffolds. -Supported the adhesion, proliferation and osteogenic differentiation of MC3T3-E1 pre-osteoblasts. -Increased ALP activity and the presence of bone sialoprotein. | [36] |
Type of Scaffold | Type of Enhancers | Type of Model | Findings | Reference |
---|---|---|---|---|
β-TCP | - | Immunodeficient CD-1 nude mice | -Increased total bone formation, mature bone formation, and neovascularisation. | [38] |
Hydroxyapatite/β-TCP | - | Male SCID mice | -Bone formation and cell adhesion on the scaffold. | [27] |
β-TCP/CS | - | Male New Zealand white rabbits with circular bicortical critical-size cranial defect | -Decreased Gr.V/TV and Gr.Ar. -Increased BV/TV, OV/TV, B.Ar, O.Ar, O.Pm, Oc.N, and mineralisation marginally. -No change in Ob.N, Ob.Pm, and Fb.Ar. | [39] |
Calcium phosphate cement | - | Patients with trochanteric fracture (n = 21; aged 66–95 years) | -Improved fracture stability. | [40] |
Calcium phosphate cement | - | Patients with acute distal radial fracture (n = 48; aged >65 years) | -No association for flexion arc, extension arc, supination arc, pronation arc, grip strength, VAS scores, MMWS, DASH scores, or radiographic parameters. -No association in mean volumes of metaphyseal defects. | [41] |
Hydroxyapatite and calcium phosphate cement | Calcium silicate | Goat bone marrow-derived mesenchymal stem cells | -Increased viability of cells, cell adhesion, cell migration, ALP activity, osteopontin (OPN), and OCN in silica-coated hydroxyapatite compared to pure hydroxyapatite. | [43] |
Hydroxyapatite | Dopamine-modified alginate and quaternised chitosan | Human chondrocytes and fibroblasts | -Gradient scaffold promotes new bone formation and accelerates bone defect repair in vivo compared to the homogenous scaffold. | [44] |
β-TCP | Poly(1,8-octanediol-co-citrate) and cerium oxide nanoparticles | Sprague–Dawley rats | -Scaffold degradation. | [45] |
Primary human osteoblasts | -No cytotoxicity, good cell attachment, proliferation, and mineralisation on the scaffolds. |
Type of Scaffold | Type of Enhancers | Type of Model | Findings | Reference |
---|---|---|---|---|
Bioglass | - | Primary human osteoblast and HUVECs | -Scaffolds were non-toxic to cells and showed increased cell proliferation. | [47] |
Bioglass | - | Male Wistar rats with non-critical-sized tibial defect | -Complete degradation, no inflammation, new bone formation, and increased mechanical strength. | [48] |
Bioglass | - | Male Wistar Lineage rats with femoral bone defect | -Lower BV/TV and Tb.N were found in the animals receiving a bioglass scaffold than those receiving autogenous bone. -No difference in Tb.Th or Tb.Sp were found between the groups receiving a bioglass scaffold and autogenous bone. | [49] |
Niobium | -No difference in BV/TV, Conn.D, Tb.Th, or Tb.N between the groups receiving a niobium-supplemented bioglass scaffold and autogenous bone. | |||
Bioglass | - | Calvaria bone defect rat model | -BV/TV, Tb.Th, Tb.Sp, and Tb.N were comparable between the animals implanted with a bioglass nanoceramic composite, with and without raloxifene. | [50] |
Raloxifene | ||||
Bioglass | Boron | Rat bone marrow mesenchymal stem cells | -Scaffolds were non-toxic to cells and showed proper cell attachment. | [51] |
Male New Zealand white rabbit with mandibular defect | -Fast bone repair, scaffold degradation, bone regeneration with increased BMD, BV/TV, Tb.Th, and decreased Tb.Sp. | |||
Baghdadite | Bioglass | Merino wethers with critical-sized segmented bone defect at right tibia | -No difference in torsional stiffness, ultimate torsional strength, bone volume, bone bridging, or area of infiltrating bone between baghdadite scaffolds, with and without bioglass nanoparticles. | [52] |
Type of Scaffold | Type of Enhancers | Type of Model | Findings | Reference |
---|---|---|---|---|
Chitosan | Hydroxyapatite | MC3T3-E1 cells | -Increased cell number, osterix expression, ALP activity, and mineralisation. | [58] |
Male C57BL/6J mice with rod-fixated tibia fracture | -Increased total bone volume, tissue volume, Tb.N, Conn.D, polar moment of inertia, and osteoid volume. -Decreased Tb.Sp and trabecular pattern factor. -Presence of cartilage matrix | |||
Chitosan | Hydroxyapatite | MC3T3-E1 cells | -Increased ALP, cell proliferation, and cell viability. | [57] |
Chitosan | Nano-sized silica | Mice bone marrow stromal cells | -Non-cytotoxic. | [59] |
Chitosan | Gelatin and nano-silica | MG63 cells | -Non-cytotoxic, proper cell attachment, and increased cell proliferation. | [60] |
Chitosan | Two dimensional-layered nanoparticles consisting of Mg-Al-PO4-layer double hydroxide and nanoclay | NIH 3T3 cells | -Enhanced mechanical property as compared to pure chitosan. -Increased cell viability and cell proliferation within pores. | [61] |
Albino Wistar rats with femoral bone defect | -Faster bone healing, denser bone morphology, and higher osteoblast number as compared to pure chitosan. -No changes in the levels of liver enzymes (aspartate aminotransferase and alanine aminotransferase), urea, or creatinine. | |||
Chitosan | Polytrimethylene carbonate/polylactic acid (PLLA)/oleic acid-modified hydroxyapatite/vancomycin hydrochloride | MC3T3-E1 cells | -Slow biodegradability. -Increased osteogenic proliferation, adhesion of osteoblasts, and high mechanical and surface strength. | [62] |
Type of Scaffold | Type of Enhancers | Type of Model | Findings | Reference |
---|---|---|---|---|
Gelatin methacryloyl hydrogel | - | 4-month-old New Zealand white rabbit with large segmental defect at the radius | -Implantation of hydrogel increased new bone formation, healing rate, bone remodelling, and bone volume. -Higher degradation rate, formation of fibrous tissue between trabeculae, cell number, and bone marrow tissue were observed in animals implanted with hydrogel than control. | [66] |
Bone marrow mesenchymal stem cells (BMSCs) | -Increased cell proliferation, chemotactic effect, regulation of COL1, ALP, OCN, Runx-2, OPN, and bone mineralisation. | |||
Gelatin methacylamide hydrogel | - | ADSCs | -Increased cell proliferation, ALP activity, and mineralisation. | [67] |
Sprague–Dawley rats with critical-size calvarial bone defect | -Increased regeneration of defective bone. | |||
CBM peptide-alginate gel | - | Rabbits with calvarial defect | -Increased new bone formation and BMD. | [69] |
hBMSCs | -Increased ALP, Smad1/5/8, cell proliferation, osteogenesis, calcein uptake, and BMD. | |||
Methacrylated gelatin hydrogel | Bioglass | Human tonsil-derived mesenchymal stem cells | -Increased mechanical strength and increased osteogenic differentiation of cells. | [70] |
Female balb-C mice with cranial defect | -Increased bone formation in the animal. | |||
Gelatin-alginate hydrogel | Bioglass | Rat bone marrow mesenchymal stem cell | -Proliferation of viable cells. -Increased osteogenic differentiation. | [65] |
COL1 and elastin-like polypeptide-based hydrogel | Bioglass | Human adipose-derived stem cells | -Increased cell viability, spreading, attachment, proliferation, ALP activity, OCN content, and mineralisation. | [71] |
Gelatin methacrylate hydrogel | Octacalcium phosphate | Mouse multipotent mesenchymal C3H10T1/2 cells | -Increased cell proliferation, cell differentiation, and angiogenesis. | [72] |
Poly(ethylene glycol)-based hydrogel | siRNA/nanoparticle | Female BALB/c mice with mid-diaphyseal femoral fracture | -Increased callus area, cartilage formation, and bone area. -Decreased unmineralised cartilage and fibrotic tissue formation. | [73] |
Chitosan-based hydrogel | Zeolitic imidazolate framework-8 | Rat bone marrow mesenchymal stem cells | -Increased ALP, COL1, OCN, and vascular endothelial growth factor (VEGF). -Extracellular matrix mineralisation and has antibacterial effects. | [74] |
Male Sprague–Dawley (8 weeks) cranial defect model | -Increased BV/TV, BMD, ALP, OCN, and mineralisation. -Increased angiogenesis. -Decreased inflammatory cells. |
Type of Scaffold | Type of Enhancers | Type of Model | Findings | Reference |
---|---|---|---|---|
PMMA | Tricalcium phosphate and chitosan | Mouse fibroblastic cell line | -Non-cytotoxic. | [80] |
Sprague–Dawley rats with skull-cap fractures | -Increased bone ingrowth. | |||
PMMA | β-TCP | New Zealand white rabbits with bilateral mandibular defect | -Bone ingrowth, no inflammation, and thin fibrous tissue observed at the surface of bone-cement. | [79] |
PMMA | MgO nanoparticles | Mouse embryo osteoblast precursor cells | -Better biocompatibility, presence of calcium nodules, and higher osteogenic gene expression. | [81] |
Sprague–Dawley rats with calvarial critical bone defect | -New bone formation and higher BMD. | |||
PMMA | Platelet gel | Sprague–Dawley rats with forearm radii defect | -Less inflammation and increased density of cartilage and osseous tissue. | [82] |
PMMA | Linoleic acid | Female sheep with humerus and femur defects | -Good biocompatibility and harmless tissue healing, but lacks mechanical strength. | [83] |
Type of Scaffold | Type of Enhancers | Type of Model | Findings | Reference |
---|---|---|---|---|
PGA | - | MC3T3-E1 cells | -Increased cell proliferation, differentiation, and calcification. | [85] |
Rabbits with calvarial bone defect | -Increased bone mineral density and connective tissue formation. | |||
PGA | Collagen | New Zealand white rabbits with calvarial bone defect | -Formation of fibrous connective tissue and bony bridging at the defect site. -Damage area at the defect site was reduced. -Increased ALP and sialoprotein expressions. | [86] |
PLA | Nano-hydroxyapatite | Rabbit bone marrow mesenchymal stem cells | -Formation of calcium nodules. -Expression of Runx-2, COL1, OPN, and bone morphogenetic protein-2 (BMP-2). | [87] |
Male New Zealand white rabbit femoral defect model | -Good osteointegration and biocompatibility. -No inflammation and no tissue necrosis. -New bone growth. -Composite scaffolds have higher bone growth and BV/TV than PLA scaffolds. | |||
PLGA | - | New Zealand white rabbit with osteochondral defect at femoral condyles | -Increased compressive modulus. -No inflammation at the synovial membrane and joint tissues. -Increased percentage of hyaline cartilage. -Increased aggrecan, COL1, and COL2 levels. | [88,89,90] |
PLGA | Octacalcium phosphate | Male Sprague–Dawley rats with femoral defect | -Increased BV/TV and Tb.Th, and decreased Tb.Sp. -Accumulation of osteoclast-like cells at week 4 and osteocalcin-positive osteoblast cells at week 8. | [91] |
PLGA | Tricalcium phosphate, icaritin | Male New Zealand white rabbit with ulnar-bone-defect model | -Neovascularisation and new mineralised bone formation. | [92] |
PLGA | β-TCP and magnesium | Male New Zealand white rabbit with osteonecrosis induced by methylprednisolone | -Increased BV/TV, BMD, Tb.N, bone surface/tissue surface, and decreased Tb.Sp. -Increased energy and maximum load of bone. -Increased expression of BMP-2 and vascular endothelial cell growth factor A. | [93] |
PCL and PLA | - | Human mesenchymal stem cell | -Enhance cell viability and osteogenic differentiation. | [94] |
Male C57BL/6NHsd mice critical-sized cranial bone defect | -New bone formation. | |||
PCL and PLA | - | New Zealand rabbit with distal ulna defect | -Great bone regeneration. -Higher BMD than pure PLA. | [95] |
PCL and PLA | Hydroxyapatite | MG63 cells | -Cell adhesion, cell viability and mineral deposition. | [96] |
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Wong, S.K.; Yee, M.M.F.; Chin, K.-Y.; Ima-Nirwana, S. A Review of the Application of Natural and Synthetic Scaffolds in Bone Regeneration. J. Funct. Biomater. 2023, 14, 286. https://doi.org/10.3390/jfb14050286
Wong SK, Yee MMF, Chin K-Y, Ima-Nirwana S. A Review of the Application of Natural and Synthetic Scaffolds in Bone Regeneration. Journal of Functional Biomaterials. 2023; 14(5):286. https://doi.org/10.3390/jfb14050286
Chicago/Turabian StyleWong, Sok Kuan, Michelle Min Fang Yee, Kok-Yong Chin, and Soelaiman Ima-Nirwana. 2023. "A Review of the Application of Natural and Synthetic Scaffolds in Bone Regeneration" Journal of Functional Biomaterials 14, no. 5: 286. https://doi.org/10.3390/jfb14050286
APA StyleWong, S. K., Yee, M. M. F., Chin, K. -Y., & Ima-Nirwana, S. (2023). A Review of the Application of Natural and Synthetic Scaffolds in Bone Regeneration. Journal of Functional Biomaterials, 14(5), 286. https://doi.org/10.3390/jfb14050286