Review
Copyright ©The Author(s) 2019.
World J Stem Cells. Jan 26, 2019; 11(1): 13-32
Published online Jan 26, 2019. doi: 10.4252/wjsc.v11.i1.13
Table 3 Status of stem cell therapies and bioprinting in tissue repair and regeneration
OrgansStem cellBioprinting
Heart(1) Combination of Mesenchymal and c-kit (+) Cardiac stem cell[141]; and (2) Human embryonic stem cell–derived cardiomyocytes[142](1) 3D bioprinting approach for vascularized heart tissue engineering based on human umbilical vein endothelial cells and induced pluripotent stem cells-derived cardiomyocytes[143]; (2) 3D-printed patch composed of human cardiac-derived progenitor cells in a hyaluronic acid/gelatin (HA/gel) based matrix[144]; and (3) 3D endothelial bed was seeded with cardiomyocytes to generate aligned myocardium capable of spontaneous and synchronous contraction[145]
Blood vessels(1) Endothelial cells derived from human embryonic stem cells[146]; and (2) Human Pluripotent Stem cells[147](1) Pluronic F127 was used as a sacrificial material for the formation of the vasculature through a multi-nozzle 3D bioprinting system[148]; and (2) Drop-on-demand bioprinting technique to generate in vitro blood vessel models[149]
NervesMesenchymal stem cell[150,151](1) Novel technique for bioprinting of fibrin scaffolds by extruding fibrinogen solution into thrombin solution, utilizing hyaluronic acid (HA) and polyvinyl alcohol[152]; and Production of high-resolution 3D structures of polylactide-based materials via multi-photon polymerization and explores their use as neural tissue engineering scaffolds[153]
Eyes(1) Embryonic stem cell[154]; and (2) Limbal stem-cell[155](1) Produced 3D cornea-mimicking tissues using human stem cells and laser-assisted bioprinting[156]; and (2) Physical and chemical signals through 3D-bioprinting of HA hydrogels and co-differentiation of retinal progenitor cells into photo receptors [157]
Kidneys(1) Embryonic stem cell[158]; and (2) Human pluripotent stem cells[159,160]Bioprinting method for creating 3D human renal proximal tubules in vitro that are fully embedded within an extracellular matrix[161]
SkinMesenchymal stem cells[102,162](1) Amniotic fluid-derived stem cells printed in a set of pressure-driven nozzles through hydrogel solutions[102]; (2) Novel bioink made of gelatin methacrylamide and collagen doped with tyrosinase is presented for the 3D bioprinting of living skin tissues[163]; and (3) 3D cell printing of in vitro stabilized skin model and in vivo pre-vascularized skin patch using tissue-specific extracellular matrix bioink[164]
Pancreas(1) Embryonic stem cells[165]; and (2) Human embryonic stem cells[166,167](Not fully developed) reviews[168,169]
Brain(1) Multipotent adult stem cells[170]; and (2) Endogenous neural stem cells[171](1) Method for fabricating human neural tissue by 3D printing human neural stem cells with a bioink, and subsequent gelation of the bioink for cell encapsulation[172]; and (2) 3D bioprinted glioma stem cell model, using modified porous gelatin/alginate/fibrinogen hydrogel that mimics the extracellular matrix[173]
Lungs(1) Distal airway stem cell[174]; (2) Pluripotent stem cells[175]; and (3) Exogenous stem/progenitor cells[176]Reviews[177,178]
Liver(1) Mesenchymal stem cells[179]; and (2) Induced pluripotent stem cells-derived organ bud transplant[180](1) Human embryonic stem cells-derived hepatocyte-like cells were 3D printed using alginate hydrogel matrix[117]; (2) Development of a liver-on-a-chip platform for long-term culture of 3D human HepG2/C3A spheroids for drug toxicity assessment[104]; and (3) Liver tissue model conducive to hepatotoxicity testing was developed by bioprinting hepatic spheroids encapsulated in a hydrogel scaffold into a microfluidic device[181]