[196] |
Collagen/PPy |
C2C12 mouse myoblast |
3D, highly aligned, and electrically conductive collagen scaffold via directional lyophilization of a polypyrrole-doped collagen suspension |
Increasing electrical conductivity by using polypyrrole (PPy) |
[197] |
Collagen |
C2C12 murine skeletal muscle myoblast cell |
Fused deposition modeling (FDM) |
Increased IGF1 mRNA and, Akt, p70S6K, and 4EBP1 phosphorylation, along with myotube hypertrophy and improved designed muscle functionality |
[198] |
Alginate/Gelatin/Heparin |
Human skeletal muscle progenitor cells (hSMPCs) |
Hydrogel |
Cost-effective and an alternative for commercial biomaterials |
[199] |
Alginate |
Mesenchymal stromal cells (MSCs) |
Hydrogel |
IGF-1 and VEGF165 had significant effects on muscle progenitor cells |
[188] |
Alginate/Gelatin |
C2C12 |
Extrusion-bioprinting of hydrogel |
Alginate–gelatin hydrogel is a simple and cost-efficient biodegradable bio-ink |
[200] |
Gelatin/Hyaluronic acid |
C2C12 |
Hydrogel |
Myotube production was established throughout the hydrogel when both gelatin and hyaluronic acid were present, and no shrinkage occurred |
[201] |
Fibrin/Polyethylene oxide (PEO) |
C2C12 |
C2C12s are encapsulated and electrospun into fibrin/polyethylene oxide (PEO) microfiber bundles with aqueous solution electrospinning. |
Loading C2C12s as cellular aggregates increasing cell viability |
[202] |
Fibrin |
Muscle progenitor cells (MPCs) adipogenic |
Hydrogel |
Adipogenic differentiation was decreased by myogenic differentiation but not prevented, and MPCs produced from diabetic animals had a higher capacity for adipogenic differentiation. |
[203] |
Fibrin/Laminin |
C2C12 |
Hydrogel |
Integrating laminin-111 into fibrin hydrogels is possible |
[204] |
Fibrin/Alginate |
C2C12 |
Three-dimensional engineering of skeletal muscle tissue using electrospun fibrin microfiber bundles |
To promote tissue formation, myoblasts should undergo biophysical stimulation |
[205] |
Fibrin/Thrombin |
C2C12 |
3D printing, co-extruding fibrinogen and thrombin |
Enhancing the regeneration of functional muscle tissue by tuning the topographic features of scaffolds |
[206] |
Fibrin/Collagen |
Primary human skeletal muscle cells |
Hydrogels |
The Young’s modulus increased twofold, maximum strain decreased 2.5 times, and collagen deposition increased 1.6 times |
[207] |
Gelatin methacrylate (GelMA) |
C2C12 |
Under single UV exposure, silicone tubes-based coagulant produces cell-laden GelMA microfibers |
Increased uniaxial strain ratio of up to 35–45% and significantly improved myotube contractility |
[208] |
Fibrin + Alginate |
Primary human myoblasts |
Injectable gel |
Optimization of myoblast transplantation can include consideration of cell state |
[209] |
Fibrin/Alginate/Collagen |
Human umbilical vein endothelial cells (HUVEC) |
The use of 3D printing to create scaffolds composed of multiple gel layers and hollow channels |
They developed a very cost-effective 3D printing system |
[210] |
Fibrin/Collagen-I |
Mesenchymal stem cells (MSCs) |
Parallel nanofiber electrospinning |
When myogenic differentiation occurs, IGFBPs play a role, varying based on culture and stimulation conditions. |
[211] |
Fibrin |
Muscle-derived stem cells (MDSCs) |
Gel |
SW033291 increased MDSC myogenic differentiation and myotube creation in a significant way. |
[212] |
Gelatin |
C2C12 |
Cell-based 3D bioprinting |
The dECM components accelerated myogenic differentiation, while topographical cues caused cellular alignment |
[213] |
Gelatin |
C2C12 |
Cryogel |
Myoblasts organize themselves around this pore structure and colonize the entire three-dimensional structure |
[214] |
Gelatin/Chitosan |
L929 fibroblasts cell line |
Hydrogel–3D printing |
Increased cell viability |
[215] |
Gelatin/Alginate |
C2C12 |
Hydrogel–3D printing |
Adding calcium peroxide (CPO) as an oxygen-generating source to bio-ink can improve cell metabolic activity in Gelma bio-ink |
[216] |
Gelatin |
C2C12 |
Hydrogel |
Soft substrates can support longer-term cell culture |
[217] |
Fibrin |
Bovine satellite cells (BSCs) |
Hydrogel |
Up to a 15-fold increase in myoglobin expression in vascular smooth muscle cells |
[218] |
Gelatin |
C2C12 |
Hydrogel |
An increase in sarcomere formation in myotube cultures using micropatterned gelatin hydrogels |