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©2014 Baishideng Publishing Group Co.
World J Stem Cells. Jan 26, 2014; 6(1): 11-23
Published online Jan 26, 2014. doi: 10.4252/wjsc.v6.i1.11
Published online Jan 26, 2014. doi: 10.4252/wjsc.v6.i1.11
Table 1 Protocols and in vivo studies for oligodendrocyte progenitor cells differentiation from human pluripotent stem cells
| Growth factors | Cell source | Cell characteristics | Ref. |
| EGF-dependent protocol | |||
| RA/EGF (short FGF-2 exposure) | hESC lines: H1 and H7 | Olig1 (80%-90%), Sox10 (76%-84%), NG2 (95%); remyelinated in a rat thoracic contusion model | Nistor et al[21], 2005; Keirstead et al[19], 2006; Li et al[13], 2013 |
| RA/EGF (short FGF-2 exposure) | hiPSC lines: Royan hiPSC1, hiPSC8 | > 90% Olig2, Sox 10, > 80% NG2 and PDGFRα; tested in a rat model of optic chiasm demyelination | Pouya et al[33], 2011 |
| RA/EGF (short FGF-2 exposure) | hESC H7 line | OPCs remyelinated in a rat cervical contusion model | Sharp et al[94], 2010 |
| RA/EGF (short FGF-2 exposure) | hiPSC lines: 201B7, 253G1 | O4+ cells were observed in EGF-dependent protocol | Ogawa et al[20], 2011 |
| PDGF-dependent protocol | |||
| PDGF/FGF-2 (short EGF exposure) | SNUhES1 line | PDGFRα (81%), A2B5 (90.4%), NG2 (91.3%) and O1 (81%); myelinate axons in co-cultures with fetus hippocampal neurons. | Kang et al[24], 2007 |
| RA/Shh/FGF-2/PDGF | hESC lines: H1, H9 H14 | > 80% PDGFRα+, also co-express Olig2, Nkx2.2, Sox10 and NG2 | Hu et al[26], 2009 |
| RA/Shh/FGF-2/PDGF | hiPSC lines: K04, C14, and C27 | 70%-90% Olig2+/Nkx2.2+, OPCs myelinated the brains of myelin-deficient shiverer mice | Wang et al[7], 2013 |
| FGF-2/EGF/PDGF/CNTF plus laminin; Shh, PDGF, IGF-1, EGF, FGF-2 and CNTF plus RA and laminin | hESC lines: HS360 and HS362; Regea 06/040 and Regea 08/023 | > 90% NG2+, > 80% PDGFRα+; multilayered myelin sheet formation around axons was detected in co-culture with neuronal cells | Sundberg et al[28], 2010 Sundberg et al[27], 2011 |
| Noggin/FGF-2/FGF-4/PDGF/EGF | hESC H1 line | > 95% cells expressing Sox10, A2B5, PDGFRα, NG2, O4, O1; increased neurological response in a rat contusion model | Kerr et al[29], 2010 |
Table 2 Effects of extracellular matrices proteins on neural differentiation of pluripotent stem cells
| ECM protein | Integrins | Cell source | Neural differentiation | Ref. |
| Laminin Matrigel (rich in laminin) | α6β1 α3β1 | HESC lines: TE03 and TE06 | Neuronal generation and neurite outgrowth were significantly greater on laminin and laminin-rich Matrigel than fibronectin, poly-D-lysine, and collagen I | Ma et al[16], 2008 |
| Fibronectin | α5β1 | Oligodendrocyte progenitor cells from rats | Promoted OPC survival, proliferation, migration, process extension, and OPC purity | Hu et al[35], 2009 |
| Vitronectin | αvβ1, αvβ3, αvβ5 | hESC lines: Miz-hES4, Miz-hES6 | Promoted oligodendrocyte differentiation in the presence of RA/Shh/Noggin | Gil et al[36], 2009 |
| Collagen IV | α1β1, α10β1 | Rabbit neural progenitor cells | Conducive for both neuronal and glial cell differentiation | Raghavan et al[61], 2013 |
| Collagen I | α2β1 | Rabbit neural progenitor cells | Conducive for both neuronal and glial cell differentiation | Raghavan et al[61], 2013 |
| Vitronectin-derived synthetic peptide acrylate surface | αvβ5 | hESC line: H1 | Promoted oligodendrocyte progenitor differentiation; higher NG2 expression compared to Matrigel | Li et al[13], 2013 |
| Heparan sulfate | Binding heparin | Rabbit neural progenitor cells | Addition of heparan sulfate to collagen mixtures improved neuronal differentiation | Raghavan et al[61], 2013 |
Table 3 Protocols and in vivo studies for neural progenitor cells differentiation from human pluripotent stem cells
| Growth factors | Cell source | Cell characteristics | Ref. |
| EB-based protocol | |||
| FGF-2/RA/ascorbic acid, db-cAMP, HAg | 16 hiPSC lines | 13 of the cell lines produced functional motor neurons. Treat with BDNF, GDNF, CNTF to produce motor neurons (4%-15% ISL+ neurons) | Boulting et al[43], 2011 |
| RA/FGF-2 | hESC lines: H7, hCSC14, hCSC14-CL1 | Produce neuronal progenitors (> 95% nestin and Musashi-1), can become cholinergic neurons, GABA neurons, etc | Nistor et al[47], 2011 |
| Isolated Rosette expanded with EGF/FGF-2 | hiPSC lines | Generate long-term expandable neuro-epithelial like stem cells (Lt-NES); in stoke model, the cells improved recovery of fine forelimb movements | Oki et al[53], 2012 |
| RA/Shh | hESC lines H1 and H9 | To generate motor neurons (50% HB9+ motor neurons) | Hu et al[51], 2009 |
| Monolayer-based protocol | |||
| Noggin and SB431542 | hESC line: H9 hiPSC lines: iPS-14, iPS-27 | > 80% PAX6+ cells; Shh/FGF8 for midbrain dopamine neurons; BDNF, Shh, RA, ascorbic acid for motor neurons | Chambers et al[12], 2009 |
| Noggin and SB431542 | hESC line: H9 hiPSC line: 253G4 | Treat BDNF, GDNF, NT-3 for forebrain neurons which secrete Aβ for drug screening. | Yahata et al[52], 2011 |
| Noggin only; FGF-2 may be added at later stage | hESC line: H1, H7, H9 | > 90% nestin, musashi, and PSA-NCAM; For TH neurons, add Shh/FGF8/ascorbic acid; followed by BDNF, GDNF, ascorbic acid and laminin | Gerrard et al[48], 2005 |
| FGF-2 | hESC line: SA002 and AS034 | > 90% nestin, NCAM; For neuronal lineage, add Shh/FGF8; after differentiation TH+ cells, MAPab+ cells and astrocytes existed | Axell et al[49], 2009 |
Table 4 Three-dimensional natural and synthetic extracellular matrices scaffolds for neural differentiation of pluripotent stem cells
| Scaffolds | Cell source | Neural differentiation | Ref. |
| Poly(lactic-co-glycolic acid) and poly(L- lactic acid) scaffolds | hESC | Enhanced numbers of neural structures and staining of nestin and β-tubulin III were observed | Levenberg et al[74], 2005 |
| Synthetic hydrogel matrix PuraMatrix | hESC-derived neuronal cells | HESC-derived neurons, astrocytes, and oligodendrocytes grew, matured and migrated in hydrogel; neuronal cells had electrically active connections. | Ylä-Outinen et al[76], 2012 |
| Poly(epsilon-caprolactone)-poly(beta-hydroxybutyrate) scaffolds | Mouse iPSCs | Improved iPSCs to differentiate into neurons and inhibited other differentiations. | Kuo et al[79], 2012 |
| Polycaprolactone nanofiber matrices | HESC-derived neural precursors | Aligned fibrous matrices showed higher rate of neuronal differentiation compared to random micro- and nano- fibers (62%-86% vs 27%-32%). | Mahairaki et al[77], 2011 |
| Polyurethane nanofibrous scaffolds | hESC line SA002 | Neuronal differentiation was preferred over astrocyte differentiation. | Carlberg et al[80], 2009 |
| Tissue-engineered fibrin scaffolds | Mouse ESC-derived NPCs | Enhanced NPC survival and directed differentiation into neurons. | Johnson et al[82], 2010 |
| PET microfibrous scaffolds | Mouse ESC D3 line | Enhanced neuronal differentiation indicated by nestin, Nurr1, and tyrosine hydroxylase compared to 2-D culture. | Liu et al[84,85], 2013, 2013 |
| Multiwalled carbon nanotube modified PET microfibrous scaffolds | Mouse ESC D3 line | Enhanced neuronal differentiation compared to unmodified scaffolds | Zang et al[83], 2013 |
| Chitin-alginate 3-D microfibrous scaffolds | hESC line: HUES 7 hiPSC lines: PD-iPS5 and hFib2-iPS4 | Efficient neuronal differentiation: > 95% nestin+; able to mature into neurons (> 90% β-tubulin III+) | Lu et al[75], 2012 |
| 3-D ECM scaffolds derived from ESC aggregates | Mouse ESC D3 line | ECM scaffolds derived from RA-treated EBs enhanced nestin and β-tubulin III expressions | Sart et al[60], 2013 |
| Inverted colloidal crystal (ICC) scaffolds containing alginate, poly(gamma- glutamic acid), and surface peptide; or chitin-chitosan-gelatin ICC scaffolds | Mouse iPSCs | Accelerated neuronal differentiation (β-tubulin III expression) of iPSCs. | Kuo et al[86,87], 2013, 2013 |
- Citation: Li Y, Liu M, Yan Y, Yang ST. Neural differentiation from pluripotent stem cells: The role of natural and synthetic extracellular matrix. World J Stem Cells 2014; 6(1): 11-23
- URL: https://www.wjgnet.com/1948-0210/full/v6/i1/11.htm
- DOI: https://dx.doi.org/10.4252/wjsc.v6.i1.11