Table 1.
Summary of the research studies on NP–hydrogel composites for tissue engineering applications.
| Tissue Regeneration | Nanoparticles | Scaffolds | Synthesis Method | Cell Line/Animal Tested | Effect of NPs Addition on the Physical Property of Material | Effect of NPs Addition on the Biological Property of Material | Reference |
|---|---|---|---|---|---|---|---|
| Soft Tissues | Collagen-coated Ag NPs | Collagen | Crosslinking of the hydrogel in NPs/polymer mixture | Primary human epidermal keratinocytes; Dermal fibroblasts; Mice | Hydrogel containing 0.2 µM Ag NPs has similar Young’s modulus as human skin | Biocompatibility, anti-inflammatory, and anti-bacterial activities | [71] |
| Ag NPs | Poly(hydroxyethyl methacrylate) | In situ synthesis of NPs during hydrogel formation | Mouse embryo fibroblasts (NIH-3T3); BALB/c female mice | Increased amounts of Ag NPs loading slightly enhanced the compressive modulus of hydrogel | Biocompatibility, anti-bacterial, and in vivo resistance to foreign-body reactions | [68] | |
| Ag NPs | Hydroxyethyl cellulose | Crosslinking of the hydrogel in NPs/polymer mixture | Human fibroblasts | Glass transition temperature of scaffold increases as concentration of AgNO3 increases | Biocompatibility | [70] | |
| Ag NPs & Ag-Palladium NPs | Chitosan/Hydroxyapatite & Chitosan/Beta-tricalcium phosphate | Crosslinking of hydrogel in NPs/polymer mixture | Normal skin fibroblasts (BJ1); Hepatocellular carcinoma cells (HEPG2); Breast cancer cells (MCF7); | N/A | Biocompatibility and anti-bacterial activity | [69] | |
| Chitosan-coated Ag NPs | Agarose | Crosslinking of the hydrogel in NPs/polymer mixture | Human cervical carcinoma cells (HeLa); Human pancreatic epithelial carcinoma cells (MiaPaCa2); Human embryonic kidney cells (HEK); | Mechanical strength (five to eight Mpa) falls within range for soft tissue engineering | Biocompatibility, anti-bacterial activity, and hemocompatibility | [72] | |
| Au NPs | Alginate | Crosslinking of the hydrogel in NPs/polymer mixture | Human umbilical vein endothelial cells (HUVECs) | N/A | Enhanced HUVECs adhesion rate and cell spreading | [74] | |
| Au NPs | Collagen | Conjugation of Au NPs to collagen fibrils | Swine | Enhanced longevity of the material | Biocompatibility and low irritation | [73] | |
| Bone Tissues | Ag NPs | α-chitin and β-chitin/Bioactive glass ceramic NPs | Crosslinking of hydrogel in NPs/polymer mixture | Human periodontal ligament cells (hPDL); Human primary osteoblasts (POB) | Composite scaffold has decreased porosity and enhanced compressive strength. | Anti-bacterial activity, differentiation, and mineralization of POB in the absence of osteogenic supplements | [78] |
| Ag NPs | Poly (ethylene glycol) | In situ synthesis of NPs within the hydrogel matrix | Osteoblast cells (MC3T3-E1); Sprague–Dawley rats | N/A | Anti-bacterial activity, promoted osteogenesis in vitro and in vivo | [75] | |
| Ag NPs | Methacrylate | Crosslinking of hydrogel in NPs/polymer mixture; diffusion reaction; adsorption of NPs | Osteoblast cells (MC-3T3) | No effect on mechanical properties (absorption method) | Biocompatibility and anti-bacterial activity (absorption method) | [76] | |
| Au NPs | Chitosan/Pectin | Crosslinking of the hydrogel in NPs/polymer mixture; diffusion reaction; adsorption of NPs | Normal kidney epithelial cells (VERO); Epithelial colorectal adenocarcinoma cells (HT-29); HPV-16 positive human cervical tumor cells (SiHa); Kidney epithelial cells (LLCMK2); Murine macrophage cells (J774A1 cells); Mouse preosteoblastic cells (MC3T3-E1) | Gelation temperature decreases with decrease in pectin concentration and increase in Au NPs levels | Biocompatibility and promoted growth of MC3T3-E1 cells | [77] | |
| Au NPs | Gelatin | Crosslinking of the hydrogel in NPs/polymer mixture | Human adipose-derived stem cells (ADSCs); New Zealand Rabbit | N/A | Biocompatibility, promoted differentiation toward osteoblast cells, and improved bone regeneration in vivo | [80] | |
| N-acetyl cysteine-Au NPs | Gelatin-tyramine | Crosslinking of hydrogel in NPs/polymer mixture | Human adipose derived-stem cells (hASCs) | N/A | Biocompatibility and promoted osteodifferentiation | [81] | |
| Ag and Au NPs | Silk fibroin/Nanohydroxyapatite | In situ synthesis of NPs within the hydrogel matrix | Osteoblast-like cells (MG63) | Hydrogels containing Ag and Au NPs have enhanced mechanical stiffness | Biocompatibility and anti-bacterial activity | [16] | |
| Cardiac Tissues | Peptide-modified Ag and Au NPs | Collagen | Crosslinking of the hydrogel in NPs/polymer mixture | Neonatal rat ventricular cardiomyocytes and cardiac fibroblasts | Enhanced mechanical and electrical properties of the material | Promoted reparative macrophage migration | [87] |
| Au NPs | Decellularized omental matrices | Evaporation of Au for deposition | Neonatal rat ventricular cardiomyocytes, Cardiac fibroblasts | Au NPs patches have enhanced conductivity and similar longitudinal elastic modulus as pristine patches | Aligned cardiac cells with organized connexin 43 and attenuation of fibroblast proliferation | [84] | |
| Au NPs | Thiol 2-hydroxyethyl methacrylate (HEMA)/HEMA | In situ synthesis of NPs within the hydrogel matrix | Neonatal rat ventricular cardiomyocytes | Conductive hydrogel has tunable conductive and mechanical property, with Young’s modulus similar to myocardium | Increased expression of connexin 43 | [86] | |
| Chitosan-modified Au NPs | Chitosan | Crosslinking of the hydrogel in NPs/polymer mixture | Mesenchymal stem cells | Tunable electrical conductivity of the hydrogel by different concentration of Au NPs | Biocompatibility, enhanced differentiation into cardiac lineages | [91] | |
| Au nanorods | Gelatin methacrylate | Crosslinking of the hydrogel in NPs/polymer mixture | Neonatal rat ventricular cardiomyocytes | Enhanced mechanical and electrical properties of the material | Enhanced formation of cardiac tissues | [88,89] | |
| Au nanorods | Gelatin methacryloyl | Crosslinking of the hydrogel in NPs/polymer mixture (3D bioprinting) | Neonatal rat ventricular cardiomyocytes and cardiac fibroblasts | Nanocomposite bioink has increased shear-thinning effect and enhanced printability | Enhanced cell adhesion and organization, electrical propagation, and synchronized contraction | [90] |