Table 1.
Summary of composite nanomaterials developed for cartilage healing and regeneration.
| Scaffolds | Fillers | Tested Cell Cultures | In Vitro Tests | In Vivo Tests | Preparation | Effect | Ref. |
|---|---|---|---|---|---|---|---|
| Collagen, chitosan | Micro graphene oxide, BMP-2 (1:1) | Chondrocytes | SEM, immunofluorescence | Rats, knee, femur cartilages | 3D printed | Enhanced chondrocyte proliferation | [83] |
| Polycaprolactone | Graphene nanoplatelets, polycarboxylate modified graphene nanoplatelets 0.5, 5, 10 wt% | Human chondrocytes knee, hip | Cytotoxicity, cell proliferation | - | Injection molding process to make filaments in form of sticks, 3D printing | Improved mechanical properties, support of proliferation of chondrocytes | [84] |
| Acellular cartilage extracellular matrix, distal femoral condyle of market-weight pigs | Graphene oxide 0, 1, 2, 4, 6 mg/mL | Chondrocytes | Cell viability, adhesion, and proliferation, chondrogenesis | Implantation in rats, cartilage defect model in rabbits and histological evaluation | - | Improvement of internal structure and mechanical properties | [85] |
| Sericin | Reduced graphene oxide in ratio 10:1, 50:1, 100:1 | Mesenchymal stem cells derived from bone marrow of humans | Mesenchymal stem cells differentiation, growth, adhesion | - | - | Increased levels of collagen and glycosaminoglycan, chondrogenic differentiation stimulation | [86] |
| Gelatin, methacrylate polyethylene (glycol) diacrylate | Graphene oxide | Primary human bone marrow mesenchymal stem cells | Mesenchymal stem cells proliferation, chondrogenic differentiation, collagen II secretion, glycosaminoglycan synthesis, total collagen levels, RT-PCR | - | 3D printed scaffolds | Favorable mechanical properties, biocompatibility, increased collagen, glycosaminoglycan, protein levels; chondrogenic differentiation of mesenchymal stem cells | [87] |
| Chitosan, gelatin, anionic non-sulfated glycosaminoglycan | Graphene 0, 0.024, 0.06, 1% | Bone marrow mesenchymal stem cells | - | - | Bioink, 3D-printing | Enhanced water absorption, porosity, compression modulus, cytocompatibility, cell growth, higher cells proliferation survival | [80] |
| Poly(ε-caprolactone) | Graphene nanopowders 1, 3, 5, 10 wt% | Mouse bone marrow mesenchymal stem cells | Cell culture studies, MTT Assay, Live/Dead® assays, glycosaminoglycan formation, cell attachment and morphology | - | Printing ink, 3D-printing, robocasting method | Highest cell viability rates of cells seeded onto composite scaffolds, cells proliferated well, attached to scaffold surfaces | [88] |
| Polycaprolactone | Graphene and single-wall carbon nanotubes, 0.5% and 1.0% poly-l-lysine coated | Mesenchymal stem cells | Mesenchymal stem cells cell adhesion, proliferation, and chondrogenic differentiation | - | Electrospinning, microfibrous scaffolds | Improved mechanical properties, more homogenous fiber morphology, surface properties, good cytocompatibility | [79] |
| α-Chitin, poly(caprolactone) | Chondroitin sulfate, transforming growth factor-β encapsulation | Adipose derived stem cell from inguinal fat pads of female New Zealand albino rabbit | Cell viability, attachment, and proliferation study, chondrogenic differentiation and analysis of a murine rheumatoid arthritis model | - | Lyophilization technique | Prolonged release of TGF-β achieved, macroporous, extremely porous structure, enhanced cell attachment, proliferation, differentiation | [81] |
| - | Graphene oxide granules | Umbilical cord mesenchymal stem cells | - | Male New Zealand white rabbits: expression levels of nitric oxide, interleukin-6, tumor necrosis factor-α, glycosaminoglycan, collagen-II in serum and articular fluid | Mixing | Reduction in inflammatory level, improve of level of biochemical environment in articular cavity, promotion of cartilage repair | [89] |
| 2% chitosan | 0, 0.1, 0.2, 0.3 (w/v) % suspensions of graphene oxide in deionized water | Human articular chondrocytes | MTT assay | - | Ultra-sonication process | Improvement of physical, mechanical properties, increased proliferation of human articular chondrocytes | [90] |
| Poly(lactide-co-glycolide acid) | Graphene oxide | Bone marrow mesenchymal stem cells | Rabbit bone marrow mesenchymal stem cells | Rabbit supraspinatus tendon repair model | Electrospining | Accelerated proliferation and osteogenic differentiation, promoted healing, increased bone and cartilage generation, improved collagen arrangement | [91] |
| Collagen-I, genipin | Carbon dots | Bone marrow derived stem cells | Chondrocyte differentiation medium, intracellular ROS production, Cell Counting Kit (CCK)-8 assay, cell viability | Articular cartilage intracellular ROS production | Mixing | ROS production by photodynamic therapy, enhanced cartilage regeneration, chondrogenic differentiation, increased stiffness, reduced degradation | [92] |
| Collagen-II, chitosan, poly(lactic-co-glycolic acid) | - | Rabbit chondrocytes labelled with magnetic Iron oxide nanoparticles, TANBead® USPIO-101 (Amine group, Taiwan Advanced Nanotech Inc., Taipei, Taiwan) |
Cell proliferation assay reagent WST-1, cell viability, cytotoxicity, relative proliferation activity | New Zealand White rabbits: levels of chondrogenetic marker genes including Sox-9, aggrecan, collagen-II | Mixing | Incorporation of chondrocytes into cartilage by magnetic force | [93] |
| Chitosan, collagen-I | Bioactive glass nanoparticles | Human osteosarcoma cell culture (SAOS) and kidney cells line of human embryo (HEK 293T) | The cytotoxicity and cell viability of hydrogels, MTT, Live/Dead® assays | - | Mixing | Improvement of physicochemical, morphological and rheological properties | [94] |
| 2-Hydroxypropyltrimethyl ammonium chloride chitosan, polyvinyl alcohol | Nano-hydroxyapatite, sodium citrate dihydrate | Mouse preosteoblast cells MC3T3-E1 | Tests of cell viability and proliferation | - | Freezing/thawing technique and immersing process | Improvement of mechanical and tribological properties, biological compatibility | [95] |
| Polyvinyl alcohol, polyvinyl pyrrolidone | Stick-like TiO2 nanostructures | Human osteosarcoma (HOS; MG-63) cell line | Osteoblast adhesion and proliferation | - | Sol–gel method | Excellent antibacterial efficiency, well cell adhesion and proliferations, bone formation improved | [96] |
| Glycol, chitosan | Nano-hydroxyapatite | Human sarcoma cell line culture, kidney cell line of a human embryo culture (HEK293T cells) and human bone marrow mesenchymal stem cells (HBMS) | MTT assay, Live/Dead® assays | - | solvent cast and evaporation | Potential bone-related biomedical applications | [97] |
| Chitosan, β-glycerophosphate disodium salt, gelatin | Bioactive glass nanoparticles | Rat bone marrow mesenchymal stem cells | Cytocompatibility of the hydrogels | Injecting hydrogels into dorsum of Swiss rats | Sol gel method | 27% increase in cell viability | [98] |
| Alginate, polyvinyl alcohol | Chondroitin sulfate loaded zein nanoparticles | Chondrocytes | Degradation studies, chondrocyte culture, Live/Dead® assays, MTS assay, RT-PCR, western blotting | - | Constant stirring and ultrasonication | Chondrocyte improvement, biomimetic matrices upregulating early chondrogenic marker gene (Sox-9) and differentiated genes specific for hyaline cartilage | [99] |
| Cellulose nanocrystal/dextran hydrogels | Kartogenin and ultrasmall superparamagnetic iron-oxide | Bone marrow-derived mesenchymal stem cells | CCK-8 assay, Live/Dead® assays, gene expression levels | Rabbit articular cartilage | - | Mechanical strength, kartogenin long-term release, support of hyaline cartilage regeneration | [100] |