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. 2023 Jul 1;9:215. doi: 10.1038/s41420-023-01532-9

Table 1.

In vitro differentiation protocols for per neural lineage phenotype and their application in models of neurological diseases.

Phenotypes Source of NSCs Differentiation Protocol Differentiation factors Phenotypic markers (% cells) in vitro/vivo Models Functional outcome Reference
DAergic neurons Human fetal VM tissue Chemical-defined system BDNF, AA, low oxygen

40–50% MAP2+

15% TH+/MAP2+

 NA NA [55]
NA
DAergic neurons Human fetal VM tissue (passage 2) Chemical-defined system WNT5 (SHH, FGF8, FGF2 for proliferation) 35%TH+ NA NA [62]
NA
DAergic neurons Rat embryonic VM tissue Transfected by electroporation Nurr1, Brn4 NA 6-OHDA PD rats Increased DA level; Improved rotational behavior [67]

18%TH+

14%DAT+

DAergic neurons Rat embryonic VM tissue Transfected by lentivirus TH, Brn4

65.71 ± 5.18%TH+

32.28 ± 4.39% DAT+

 NA NA [66]
NA
DAergic neurons Rat embryonic VM tissue Chemical-defined system and transfected by lipofectamine SHH, FGF8 and Wnt5a a 20-fold TH+ cells increase 6-OHDA PD mice Increased DA level, improved rotational behavior [60]
9.5% TH+
DAergic neurons Rodents embryonic cortical tissue Transfected by retroviruses Foxa2, Nurr1

37.1% TH+

55.1% PITX3+/TH+

>78% VMAT2+/TH+

 6-OHDA PD rats Exhibited a mature midbrain DAergic neuronal morphology, improved rotational behavior [73]
about 14-fold TH+ cells increase
DAergic neurons Rats embryonic cortical tissue Transfected by retroviruses with appropriate vectors and promoters Foxa2, Nurr1, ca-PKA

60% TH+/TUJ1+

80–90% PITX3+/TH+

VMAT2+/TH+

DAT+/TH+

 6-OHDA PD rats Exhibited an extremely mature midbrain DAergic neuronal morphology, no rotational behavior improvement [74]

few TH+ cells

<100 cells

DAergic neurons Primate ESCs (Co-culture with PA6) Chemical-defined system NA

25 ± 6% TUJ1+

35 ± 6% TH+/TUJ1+

 6-OHDA PD mice NA [43]
0.7% TH+
DAergic neurons Human ESCs (Co-culture with PA6) Chemical-defined system SHH, FGF8

46 ± 8% MAP+

80 ± 11% TH+/MAP+

32% TH+

 NA NA [75]
DAergic neurons Mouse ESCs (Co-culture with MS5) Chemical-defined system SHH, FGF8 50 ± 10% TH+/TUJ1+ 6-OHDA PD mice improved rotational behavior [42]
10–20% TH+
DAergic neurons Human ESCs (EB) Chemical-defined system SHH, FGF8

50–60% TH+/TUJ1+

31.8 ± 3.1% TH+

 NA NA [77, 79]
NA
DAergic neurons Human PESCs (EB/Dual SMAD inhibition) Chemical-defined system SHH C25II, FGF8, PUR and CHIR99021

60–80%/70-100% TUJ1+

20–40%/30-40% TH+

 MPTP PD primates Increased DA level, improved rotational behavior [76]
5.2–8.1% TH+
DAergic neurons Human iPSC (EB) Chemical-defined system SHH, FGF8

30 ± 5% TH+

100% GIRK2+/TH+

 6-OHDA PD rats Improved rotational behavior [78]
~2% TH+
DAergic neurons Human ESCs/iPSCs (Dual SMAD- inhibition) Chemical-defined system CHIR99021, FGF8, PUR and SHH-C25II

±75% TH+

±50% NURR1+

±80% FOXA2+

±60% LMX1A+

6-OHDA PD mice/rats

MPTP PD primates

 Exhibited excellent DA neuron survival, improved motor deficits. [84]
6% TH+ (rats)
DAergic neurons Human ESCs (Dual SMAD inhibition with EB) Chemical-defined system CHIR99021, SHH- C24II NA 6-OHDA PD rats Increased DA level, improved motor deficits, showed similar efficacy and potency to fetal DAergic neurons [82, 178]

54.2 ± 2.5% TH+

81% LMX1A+/FOXA2+

DAergic neurons Human/primate ESCs/iPSCs (Dual SMAD- inhibition) Chemical-defined system CHIR99021, FGF8b and SHH- C25II

43.6 ± 6.2% TH+

95.3 ± 2.4% NURR1+/TH+

96.7 ± 1.8% FOXA2+/TH+

96.5 ± 2.3% LMX1A+/TH+

56.3 ± 6.7% GIRK2+/TH+

 NA NA [83]
DAergic neurons Human iPSCs (Dual SMAD- inhibition) Chemical-defined system CHIR99021, FGF8, and PUR

42 ± 4.4% TH+

19.9 ± 6.9% NURR1+

70–75% FOXA2+

 6-OHDA PD rats /MPTP PD primates Improved rotational behavior(rats) increased spontaneous movement, extended dense neurites into the host striatum, increased DA synthesis [81, 85]

±17% TH+

±28%TH+/NEUN+(rats)

33.3 ± 24.4% TH+(primates)

DAergic neurons Human ESCs (Dual SMAD- inhibition) Chemical-defined system CHIR99021, FGF8b, SHH- C25II and SAG

69% TH+

84% TH+/TUJ1+

>85% GIRK2+/ TH+

 6-OHDA PD mice Displayed A9 characteristics, restored functionality of the reconstructed nigrostriatal circuit, improved motor deficits. [179]
68% TH+/survived
DAergic neurons Human iPSC (Dual SMAD- Inhibition with EB) Human iNSC Chemical-defined system CHIR 99021, FGF8, PUR, BMP5 and BMP7 30–50% TH+/TUJ1+ NA NA [86]
NA
DAergic neurons Human ESCs/iPSC (dual SMAD- Inhibition) Chemical-defined system (3D) CHIR99021, FGF8b and PUR 47% TH+ Fischer rats NA [87]

8.12% TH+/transplanted

46.7% FOXA2/ TH+

DAergic neurons INSCs reprogrammed from PBMNCs Chemical-defined system SAG1, FGF8

57.23% TH+

62.87% TH+/FOXA2

58.69% TH+/NURR1+

13.84% TH+

86.78% FOXA2+/TH+ 91.72% NURR1+/TH+

98.77% GIRK2+/TH+

 6-OHDA PD mice Improved rotational behavior [88]
GABAergic neurons Immortalized striatal human NSC line (STROC05) Chemical-defined system PUR

6.3% DARPP-32+

46% TUJ+

27%+ MAP2+

 NA NA [99]
GABAergic neurons Immortalized striatal human NSC line (ST14A) Chemical-defined system RA, KCl 74% GABA+ QA HD rats maintained neuronal GABAergic phenotype, established pre- and postsynaptic contacts with endogenous striatal cells, improved motor deficits [100]
GABAergic neurons Immortalized human NSC line (ReNcell VM) Chemical-defined system VPA

68 ± 4% MAP2+

90% GABA+/MAP2+

54% CALB1+/MAP2+

 NA NA [101]
DKK1, SHH

63 ± 4% MAP2+

96% GABA+/MAP2+

84% CALB1+/MAP2+
GABAergic neurons Human ESCs (EB) Chemical-defined system SHH/PUR

90.2 ± 4.2% GABA+/TUJ1+

89.7 ± 8.3% DARPP32+/TUJ1+

 QA HD mice Projected to the anterior substantia nigra and potentially form connections with DAergic neurons, improved motor deficits [102]

62.8 ± 2.6% GABA+

58.6 ± 3% DARPP-32+/ GABA+

GABAergic neurons Human iPSCs (Co-culture with PA6) Chemical-defined system BDNF

34.1 ± 4.5% DLX2

27.0 ± 1.7%DARPP-32+

19.1 ± 2.1% CALB1+

 QA HD rat Improved motor deficits [41]
GABAergic neurons Human ESCs/iPSC (Dual SMAD- Inhibition) Chemical-defined system DKK1, SHH-C25II

±51% MAP2+

±78% GABA+/MAP2+

±60.3% CTIP2+/MAP2+

±86% GABA+/CTIP2+/MAP2+

±53% CALB1+/MAP2+

±70.6% CTIP2+/CALB1+/MAP2+

 QA HD rat Improved rotational behavior [103]
GABAergic neurons Human ESCs (Dual SMAD- Inhibition with EB) Chemical-defined system XAV939, SAG

±87% DARPP32+/MAP2+

±89.5% GABA+/TUJ1+

80–100% DARPP-32+/GABA+

80–100% CALB1+/TUJ1+

 QA HD mice Improved motor deficits [104]
48.7 ± 2.8% DARPP32+/hN+
GABAergic neurons Human ESCs/iPSC (Dual SMAD- Inhibition) Chemical-defined system (3D) PUR, DKK1

78%MAP2+

61% GABA+/MAP2+

55%DARPP-32+/MAP2+

70%CTIP2+/MAP2+

46%CALB1+/MAP2+

100%CTIP2+/DARPP-32+

 R6/2 HD mice Innervated substantia nigra, improved motor deficits. [105]
GABAergic neurons Human ESCs/iPSCs (Dual SMAD- Inhibition) Chemical-defined system Activin A 20–50%DARPP-32+ QA HD rats no motor improvement [106]

49 ± 5% DARPP-32+/hN+

86 ± 4.6%GABA+/hN+

35 ± 8%CALB1+/hN+

GABAergic neurons Human ESCs/iPSCs (Dual SMAD- Inhibition) Chemical-defined system IWR1

±6%DARPP-32+/Map2b+

±6%DARPP-32+/CTIP2+

±60 %CTIP2+

 NA NA [107]
NA
Cholinergic motor neurons Human fetal cortical NSCs Chemical-defined system FGF2

61% HB9+

50% H9+/ChAT+

 NA NA [114]
NA
Cholinergic motor neurons HB1.F3 human NSC line Chemical-defined system and transfected by vector Olig2, SHH NA SOD1G93A mutant mice Migrated into ventral horn, and replaced lost host motor neurons, delayed clinical onset and extended life span. [233]
Cholinergic motor neurons Mouse ESCs (Co-culture with MS5) Chemical-defined system SHH, RA and FGF2 ±60%HB9+/TUJ1 NA NA [42]
NA
Cholinergic motor neurons Human ESCs, primate ESCs (Co-culture with MS5) Chemical-defined system SHH, RA

20% HB9+(human)

43% HB9+(primate)

 NA NA [116]
NA
Cholinergic motor neurons Human ESCs (EB) Chemical-defined system FGF2, RA and SHH

>50% ISL1+/TUJ1+/MAP2+

±50% HB9+/ISL1/2+

±21% HB9+

 NA NA [120]
NA
Cholinergic motor neurons Human iPSCs (EB) Chemical-defined system PUR, RA

±60%OLIG2+/SOX3+

±30%ISL1+/TUJ1+

 NA NA [118]
NA
Cholinergic motor neurons Human iPSCs (EB) Chemical-defined system RA, SHH agonist

20%HB9+

>90%ISL1/2+/HB9+

>50%ChAT+/ISL1/2+/HB9+

 NA NA [119]
NA
Cholinergic motor neurons Human ESCs and iPSCs (EB) Chemical-defined system PUR, RA and SAG,

83 ± 1% TUJ1+

30 ± 6% ISL1+

16 ± 5% HB9+

37 ± 2% ISL1+and HB9+

 NA NA [124]
NA
Cholinergic motor neurons

Human ESCs and iPSCs (Dual SMAD

Inhibition with EB)

 Chemical-defined system BIO, PUR and RA 40–50%HB9+ NA NA [122]
NA
Cholinergic motor neurons Human ESCs and iPSCs Chemical-defined system (Dual SMAD inhibition) SAG, RA and CHIR99021 74% HB9+/ISL1+ NA NA [125]
NA
Cholinergic motor neurons Human iPSCs (Dual SMAD inhibition) Chemical-defined system CHIR99021, PUR and RA

90 ± 9% MNX1 +

95 ± 3% ISL1+

91 ± 6%ChAT+/MAP2+

 NA NA [126]
NA
Cholinergic motor neurons Human iPSCs (Dual SMAD inhibition) Transfected by lentivirus NGN2, ISL1, LHX3

88.2 ± 3.5% HB9+

86.5 ± 4.1%ChAT+

 NA NA [121]
NA
Cholinergic motor neurons Human iNSCs (Reprogrammed from PBMNCs) Chemical-defined system RA, SAG1

14.80 ± 0.90% HB9+

14.40 ± 1.29% ISL1+

 NA NA [130]
NA
Cholinergic motor neurons Rat iNSCs (Reprogrammed from astrocytes) Chemical-defined system RA, SHH 34.1% ± 2.9% HB9+ NA NA [131]
NA
oligodendrocytes Human fetal diencephalic/telencephalic tissue Chemical-defined system FGF2, NT3 and PDGF-AA

15–20% O4+

15–20%GalC+

 Lysolecithin MS mice Showed limited myelinating capacity [141]
NA
oligodendrocytes Human fetal brain tissue Chemical-defined system FGF2, NT3 and PDGF-AA

80.5 ± 2.1%A2B5+

85.4 ± 3.9%O4+

90%GalC+

 NA NA [140]
NA
oligodendrocytes Human ESCs (EB) Chemical-defined system RA, SHH, FGF2, NT3, PDGF-AA and IGF1

83.95% PDGFRα+

91.3%NGN2+

 Shiverer MS mice expressed MBP and formed myelin sheaths around nerve fibers [135, 142]
NA
oligodendrocytes Human ESCs (EB) Chemical-defined system RA, PUR/SAG, FGF2, PDGF-AA, T3, low oxygen

Spinal cord

77 ± 13% NGN2+

38.5 ± 9.0%O4+

29.9 ± 5.5%MBP+/O4+

Ventral forebrain

91% ± 7% NGN2+

43% ± 5% O4+

29.9 ± 5.5%MBP+/O4+

 NA NA [143]
NA
oligodendrocytes Human ESCs and iPSCs (Dual SMAD inhibition) Chemical-defined system RA, SAG, NT3, PDGF-AA and T3 44–70% O4 + Shiverer MS mice Achieved mature oligodendrocyte differentiation and formed dense compact myelin. [145]
NA
oligodendrocytes Human iPSCs (Dual SMAD inhibition) Transfected by lentivirus SOX10, OLIG2, NKX6.2

62.1 ± 9.5%-79.0 ± 14.8% O4 +

30.37 ± 7.87% MBP+/O4 +

 Shiverer MS mice myelinated the forebrain, remyelinated the demyelinated spinal cord [146]
oligodendrocytes Human iPSCs (Dual SMAD inhibition) Transfected by lentivirus SOX10 50–65% O4 + Shiverer MS mice myelinated neurons [147, 234]
48.13 ± 4.15%MBP+
oligodendrocytes Human ESCs and iPSCs (Dual SMAD inhibition) Chemical-defined system XAV939, PUR, PDGFRα, IGF-1, cAMP and T3 35% O4+ NA NA [149]
NA
oligodendrocytes Human ESCs Transfected by lentivirus SOX10, OLIG2

19.24 ± 3.18% O4+

81.58 ± 3.94% FOXG1+/O4+

 [148]
Cortical glutamatergic neurons Human ESCs and iPSCs (Monolayer) Chemical-defined system Noggin

<65% TUJ1+

±60% VGLUT1+/TUJ1+

<75% TBR1+/TUJ1+

<72% CTIP2+/TUJ1+

<18% CTIP2+/TBR1+/TUJ1+

 NA NA [155]
NA
Cortical glutamatergic neurons Human ESCs and iPSCs (Dual SMAD inhibition with monolayer) Chemical-defined system FGF2, Vitamin A

22–29% TBR1+

25–30% CTIP2+

28–36% BRN2+

 NA NA [164, 165]
NA
Cortical glutamatergic neurons Human iPSCs (EB) Chemical-defined system BMP4, WNT3A and cyclopamine

62.2 ± 2.1% TBR1+

±80% VGLUT1+/TUJ1+

 MCAO rats Alleviated sensorimotor deficits, differentiated to glutamatergic neurons and form excitatory, glutamatergic synapses [166, 168, 169]
2.5 ± 0.3% TBR1+
Cortical glutamatergic neurons Human ESCs and iPSCs (EB) Chemical-defined system (3D) None

30-40% TBR1+

±30% CTIP2+

±10%SATB2

 NA NA [170]
NA

The phenotypes of neural lineages, sources of neural stem cells, differentiation protocols, drivers of differentiation, representative phenotypic markers (in vitro) for evaluating the differentiation efficiency and culture homogeneity, expression of representative phenotypic markers after transplantation into corresponding neurological disease model, and improvement of functional outcomes after transplantation are broadly reviewed.

+ represents the percentage of cells stained positive for a specific marker in the differentiation system (in vitro) or in the transplanted population.

AA ascorbic acid, BDNF brain derived neurotrophic factor, BIO GSK3β inhibitor 6-bromoindirubin-3′-oxime, BMP5 bone morphogenic protein 5, BMP7 bone morphogenic protein 7, BRN2 brain-specific homeobox/POU domain protein 2 (POU3F2), Brn4 brain-specific homeobox/POU domain protein 4, CALB1 calbindin 1, Ca-PKA constitutively active protein kinase A, CHAT choline acetyltransferase, CHIR99021 GSK3β inhibitor, CTIP2 b-cell CLL/lymphoma 11b(BCL11B)/COUP-TF-interacting protein 2 (COUP-TFII), 3D three-dimensional, DA dopamine, DARPP-32 dopamine and cAMP-regulated neuronal phosphoprotein 32, DAT dopamine transporter, DKK1 dickkopf-1, DLX2 distal-less homeobox 2, ESCs embryonic stem cells, EB embryoid body, EGF epidermal growth factor, FGF2 fibroblast growth factor 2/basic fibroblast growth factor (bFGF), FGF8 fibroblast growth factor 8, FGF8b fibroblast growth factor 8 isoform b, FOXA2 forkhead box protein A2, FOXG1 forkhead box protein G1, GABA γ-aminobutyric acid, GalC Galactocerebrosides, GIRK2 G protein-activated inward rectifier potassium channel 2 (KCNJ6), HB9 homeobox HB9/motor neuron and pancrease homeobox 1 (MNX1), HD Huntington’s disease, hN human nucleus, IGF-1 insulin-like growth factor 1, iNSC induced neural stem cells, iPSCs induced pluripotent stem cells, IWR1 a tankyrase/Wnt inhibitor, ISL1 ISL LIM homeobox 1, ISL1/2 ISL LIM homeobox 1/2, LHX3 LIM homeobox 3, MAP2 microtubule-associated protein 2, MBP myelin basic protein, MPTP 1-methyl-4-phenyl-1236-tetrahydropyridine, MS multiple sclerosis, MS-5 stromal cell line derived from irradiated murine bone marrow cultures, NGN2 neurogenin 2, NKX6-2 NK6 homeobox 2, NSCs neural stem cells, NURR1 nuclear receptor related 1 protein, NT3 neurotrophin-3, 6-OHDA 6-hydroxydopamine, OLIG2 oligodendrocyte transcription factor 2, PA6 stromal cell line derived from newborn calvaria tissue of the C57BL/6 mice, PBMNCs peripheral blood mononuclear cells, PD Parkinson’s disease, PGDF-AA platelet-derived growth factor AA, PGDFα platelet-derived growth factor -alpha receptor, PUR purmorphamine, PITX3 paired-like homeodomain 3, QA quinolinic acid, RA retinoic acid, SAG smoothened agonist, SATB2 special AT-rich sequence-binding protein 2, SHH sonic hedgehog, SHH-C24II recombinant human SHH, SHH-C25II recombinant mouse SHH, SMAD transcription factor and member of the BMP and TGF-β signaling pathways, T3 triiodothyronine, TBR1 T-box brain 1, SOX3 SRY box 3, SOX10 SRY box 10, TH tyrosine hydroxylase, TUJ1 neuron-specific class III beta-tubulin (TUBB3), VGLUT vesicular glutamate transporter, VM ventral midbrain, VPA valproic acid, VMAT2 vesicular monoamine transporter 2, WNT5 wingless-type MMTV integration site family 5, WNT5a wingless-type MMTV integration site family 5a, XAV939 WNT/β-catenin inhibitor.