Abstract
Summary
In the growing diversity of human iPSC-derived models of brain development, we present here a novel method that exhibits 3D cortical layer formation in a highly reproducible topography of minimal dimensions. The resulting adherent cortical organoids develop by self-organization after seeding frontal cortex patterned iPSC-derived neural progenitor cells in 384-well plates during eight weeks of differentiation. The organoids have stereotypical dimensions of 3 × 3 × 0.2 mm, contain multiple neuronal subtypes, astrocytes and oligodendrocyte lineage cells, and are amenable to extended culture for at least 10 months. Longitudinal imaging revealed morphologically mature dendritic spines, axonal myelination, and robust neuronal activity. Moreover, adherent cortical organoids compare favorably to existing brain organoid models on the basis of robust reproducibility in obtaining topographically-standardized singular radial cortical structures and circumvent the internal necrosis that is common in free-floating cortical organoids. The adherent human cortical organoid platform holds considerable potential for high-throughput drug discovery applications, neurotoxicological screening, and mechanistic pathophysiological studies of brain disorders.
Introduction
Using human embryonic or induced pluripotent stem cell (hiPSC) derived models to investigate the developing brain in health and disease has yielded considerable success (Marton and Pașca, 2020). The approaches have been varied, including single cell hiPSC-derived models grown in a monolayer (Sarkar et al., 2018; Zhang et al., 2013), multiple neural cell types in 2D neural networks (Astick and Vanderhaeghen, 2018; Bardy et al., 2015; Gunhanlar et al., 2018; Shi et al., 2012), 3D free-floating regionalized neural organoids (Paşca et al., 2015; Qian et al., 2016a; Xiang et al., 2019; Zhang et al., 2023), and hiPSC-derived free-floating unguided neural organoids (Gomes et al., 2020; Lancaster et al., 2013; Pașca et al., 2022; Pellegrini et al., 2020; Renner et al., 2017; Sawada et al., 2020). Among the consistent findings across models is that increasing cellular and topographical complexity has appeared to come at the cost of increased variability (Eichmüller and Knoblich, 2022; Kelava and Lancaster, 2016). Therefore, a major current technical challenge is to identify hiPSC-derived models that recapitulate higher-order neural complexity with reduced heterogeneity.
Existing 3D models suffer from considerable variability due to the complex and heterogeneous nature of the free-floating structures (Cederquist et al., 2019; Lancaster et al., 2013, 2017; Paşca et al., 2015; Renner et al., 2017; Velasco et al., 2019; Yoon et al., 2019). A further challenge, in particular with free-floating organoids, is the necrotic core that emerges when tissue volumes exceed the limits of oxygen and nutrient diffusion beyond a radius of ∼300-400μm (Lancaster et al., 2017; Qian et al., 2016b). Although recent progress has been made with slicing organoids prior to the emergence of necrosis followed by organotypic air-liquid interface culture (Giandomenico et al., 2019; Qian et al., 2020), even sliced organoids have to be repeatedly re-cut to prevent necrosis (Qian et al., 2020), which is both laborious and risks introducing another potential source of variability. The generation of vascularized organoids would be the ultimate solution to reduce the necrotic core and the inherent stress that is observed in cortical organoids (Bhaduri et al., 2020; Fan et al., 2022). It will be beneficial to have increased diffusion through microfluidics or vascularization (current efforts summarized in Matsui et al., 2021) and further study the mutually beneficial interaction of neural cells and vascular cells (Crouch et al., 2022; Mansour et al., 2018; Wang et al., 2023).
Here we propose a simplified approach to generating long-term hiPSC-derived adherent cortical organoids with reproducible dimensions and the potential for high-throughput screening in a 384-well format. The resulting adherent cortical organoids can be maintained in long-term culture and contain neurons with dendritic spines and robust activity, as well as several classes of glial cells including oligodendrocyte precursor cells, myelinating oligodendrocytes, and morphologically distinct sub-types of astrocytes.
Results
Self-organized topography of iPSC-derived adherent cortical organoids
Adherent cortical organoids reproducibly self-organized into layered radial structures in 384-wells plates within 8 weeks of seeding with hiPSC-derived forebrain-patterned neural progenitor cells (NPCs). Three different hiPSC source cell lines were used in this study, including commercially available NPCs, and NPCs generated using a modified version of our previously described protocol (Gunhanlar et al., 2018) (Figure 1A). NPCs were capable of neural rosette formation and expressed SOX2, Nestin, and the frontal cortical NPC-marker FOXG1 (Figure 1B, C, D, Figure S1A). The initial 4 weeks after seeding the NPCs in Neural Differentiation Medium (ND) were characterized by proliferative expansion of NPCs and the emergence of early neural differentiation markers (Figure 1E, Figure S2). Between 4– and 8-weeks post-seeding, neurons and glial cells emerged with a consistent spatial organization (Figure 1E, F, Figure S1B, Figure S2), in which the central region was densely packed with cell bodies while the periphery contained circumferentially and radially organized processes originating from cells in the centre. Typically, cortical organoids defined as a single radial structure per well were observed in ∼80% of the wells seeded with NPCs after 60 days of differentiation. The structural integrity of single structure organoids remained quite stable and slowly diminished over time to about 50% of intact single structure organoids after 1 year in culture (Figure S1D). Organoid structure formation was highly dependent on the proliferation rate of NPCs, that can differ substantially between differentiation batches and hiPSC clones. Plotting the interaction between proliferation and the amount of NPCs required to be seeded for the successful generation of adherent cortical organoids, showed a significant correlation (r2=0.67) that can be used as a guideline for testing a range of NPC densities (Figure S1C). For each NPC line an optimal seeding density was estimated based on the proliferation rate of that NPC line. Multiple densities were seeded around the estimated optimal density and after 6 weeks it was visually determined which NPC density enabled adherent cortical organoid generation. Typically, too sparse seeding density generated neural networks lacking structure, while excessive densities resulted in overgrowth, leading to reduced structural organisation and compromised long-term survival.
Cell type distribution and layer formation
The spatial organisation that evolved over the first 8 weeks after seeding was paralleled by a shift in cell type distribution. Tau+/MAP2– axons exhibited long extensions in a circular pattern, while MAP2+ dendrites exhibited orthogonally-oriented radial outgrowth (Figure 2A, Figure S3).
Overall, a reduction in progenitor markers (SOX2 day 14: 58.4%, day 56: 18.8% P = <0.001, PAX6 day 14: 34.5%, day 56: 8.0% P = 0.20) and a significant increase in neuronal cortical layer markers (CTIP2 day 14: 0.5%, day 56: 14.0% P = <0.001, CUX1 day 14: 1.3%, day 56: 24.4% P = <0.001) were observed (Figure S2). Cortical layer markers exhibited an inside-out pattern of development in which expression of the deep layer excitatory neuronal marker CTIP2 emerged before the upper layer marker CUX1 (Figure S2, Figure 2C). After 6-8 weeks following seeding, a self-organised rudimentary segregation of deep– and upper layer neurons emerged as shown by a clear macroscopic separation of deep– and upper layer neurons, although some neurons were spatially intermixed and some neurons were double-positive for CTIP2 and CUX1. Segregation was also observed between CUX1 and CUX2 positive cells as CUX2 is typically expressed over a wider range of upper cortical layers than CUX1 and also marks intermediate progenitors (Molyneaux et al., 2007) (Figure 2C, Figure S4). Analogous to the broad distribution of cortical cell subclasses, the majority of the neurons were glutamatergic, while GAD67+ interneurons were also present (Figure 2D), constituting ∼10% of the NeuN-positive neuronal population consistently for all three source hiPSC lines (Figure S5).
Adherent cortical organoids contain multiple glial cell types
Within 8 weeks of seeding, a population of GFAP+/S100β+ astrocytes emerged. Many astrocytes had their soma located in the central region with process outgrowth radially (Figure 2E, Figure S6), while other astrocytes exhibited subtype-specific morphologies including fibrous astrocytes (Figure 2F), protoplasmic-like astrocytes (Figure 2G) and interlaminar astrocytes (Figure 2H). GFAP/PAX6 double-positive radial glia were present at the outskirts of the densely populated centre of the organoid with processes growing radially outwards (Figure 2I). Similar to free-floating organoids, adherent cortical organoids survived for longer periods compared to monolayer neural cultures grown on larger surfaces. The longevity allows for the development of cell types not usually seen in a monolayer culture that can typically be cultured up to a maximum of 2 to 3 months. By 6 weeks after seeding NPCs we observed the emergence of oligodendrocyte precursor cells (OPC), as shown by the expression of NG2 (Figure 3A). NG2+ cells remained present until at least 4 months (Figure 3B/C). Staining for Myelin Basic Protein (MBP) revealed the emergence of MBP+ oligodendrocytes around 4 months after NPC seeding when the organoids were continuously grown in the presence of T3 (2ng/ml) (Figure 3D). At 5 months, the oligodendrocytes showed increasingly mature morphologies (Figure 3E-I) and exhibited MBP co-localization along NF200+ axons (Figure 3F/I).
Adherent cortical organoids show synaptic connectivity and functional activity
Neurons within adherent cortical organoids exhibited clear evidence of synaptogenesis (Figure 4A-D). Sparse labelling of excitatory neurons with AAV9.CamKII.eGFP revealed the presence of Synapsin-positive (Syn+) mushroom-shaped dendritic spines (Figure 4E). To assess the functional activity of the cortical organoids, we used the genetically-encoded calcium indicator GCaMP6s under the control of the human Synapsin promoter (Figure 4F), allowing cell-type specific quantification of neuronal activity. Calcium imaging revealed robust synchronous network-level bursting (NB) (1.4 ± 0.07 NB/min) in which the vast majority of recorded neurons participated. In addition, substantial desynchronized activity was also observed (3.9 ± 0.5 events/min) during time periods outside of network-level bursting (Figure 4G-J, Figure 4 – Video 1).
Discussion
The study of early human brain development and related diseases has long been hampered by the inherent complexity of the human brain and the inaccessibility of living brain tissue at cellular resolution. Technological advances in induced pluripotent stem cell technology have now facilitated the opportunity to obtain living human neurons derived from specific individuals.
We describe here a platform to model early human frontal cortical development with high reproducibility and simplified organization. While 3D floating organoids, or sliced organoids, nicely recapitulate layered cortex formation, they are subject to variation in the relative contribution of cortical tissue within the organoid, forming multiple cortical patches along the edges and complicating structured analysis (Eichmüller and Knoblich, 2022; Giandomenico et al., 2019; Quadrato et al., 2017). Moreover, 3D floating organoids suffer from necrosis in the core of the organoid due to lack of oxygen and nutrient diffusion. Recently, other protocols have been published starting from rosette formation with a focus on very early development and leading to single structure free floating cortical organoids (Pagliaro et al., 2023; Tidball et al., 2023). Our platform predefines a rosette-forming iPSC-derived cortical NPC population that self-organizes into adherent singular radial structures in a standard 384-well format. Other examples have highlighted the benefits of a multi-well format or systematic individual structure formation (Knight et al., 2018; Medda et al., 2016). Our platform now integrates these features to yield individual adherent layered cortical structures with robust functional synaptic connectivity and neuronal activity and including advanced glial cell types such as myelinating oligodendrocytes and subclasses of astrocytes. The small reproducible format of the organoids in a 384-well format has the distinct advantage of being able to image entire organoids without slicing or clearing and to perform spatiotemporal functional analysis by fluorescence-based calcium imaging. We confirmed the self-organizing potential and reproducibility of adherent cortical organoids across multiple hiPSC lines and using different sources of NPCs, controlling the seeding density for the proliferation rate of the specific NPC batch. Seeding NPCs with frontal cortical identity in the defined geometry of a 384-well plate enabled the development of long-term functional neural networks in a complex radial structure resembling early human cortical development. Future studies aimed at single cell gene expression analysis and advanced image-based analysis solutions in this platform will be interesting in the context of the increasing knowledge on single cell topographical, typological and temporal hierarchies in the developing human cortex (Bhaduri et al., 2021; Nowakowski et al., 2017, 2016; Uzquiano et al., 2022).
These functional adherent cortical organoids in a multi-well format should be amenable to high-throughput screening applications, mechanistic pathophysiological studies of neurodevelopmental and neuropsychiatric disorders, and pharmacological and phenotypic screening of disease phenotypes during early cortical development. Moreover, toxicological studies for novel therapeutic compounds also show an increasing need for testing specific effects in human neuronal models, whereas studies using rodent models have often shown poor predictive power for drug safety and efficacy in human central nervous system disorders (van Esbroeck et al., 2017).
Adherent cortical organoids also have some limitations, as the current iteration of adherent cortical organoids exhibits limited cortical layering and regional specification, that seem to be more advanced in floating whole brain organoids. However, these drawbacks are offset by significantly enhanced ease and higher-throughput possibilities of downstream analysis applications.
Taken together, we present a novel platform for cellular-level human brain modeling using adherent cortical organoids that exhibit high reproducibility and robust neuronal activity. The ability to reliably generate human cortical organoids in multi-well plates combined with neural network functionality offers a unique potential for brain disease modeling and therapeutic screening applications.
Materials and Methods
Generation of Neural Progenitor Cells
NPCs from 3 different source hiPSC lines were used. NPC-line 1: in house generated NPCs from human iPSC line WTC11 (Provided by Bruce R. Conklin, The Gladstone Institutes and UCSF, #GM25256, RRID:CVCL_Y803, Miyaoka et al.,2014). NPC-line 2: commercially available hNPCs from Axol Biosciences (ax0015). NPC-line 3: NPCs derived using the protocol of Shi et al., (Shi et al., 2012) from hiPSC line IPSC0028 (Sigma-Aldrich, RRID:CVCL_EE38). Line 1 NPCs were generated as previously described from hiPSCs grown on a mouse embryonic fibroblast (MEF) feeder layer (Gunhanlar et al., 2018). After passage 3, NPC cultures were purified using fluorescence-activated cell sorting (FACS). NPCs were detached from the culture plate using Accutase (Stem Cell Technologies) and CD184+/CD44-/CD271-/CD24+ cells (Yuan et al., 2011) were collected on a FACSAria III Cell Sorter (BD Bioscience) and expanded in NPC medium consisting of: DMEM/F12, 1% N2 supplement, 2% B27-RA supplement (Thermo Fisher Scientific), 1 μg/ml laminin (L2020, Sigma-Aldrich), 20 ng/ml basic fibroblast growth factor (Merck-Millipore, Darmstadt, Germany) and 1% penicillin/streptomycin (Thermo Fisher Scientific). NPCs were differentiated to adherent cortical organoids between passage 3 and 7 after sorting.
Neural differentiation
384-well plates (M1937-32EA. Life Technologies) were coated with 50 µg/ml laminin in dH20 (Sigma, L2020) for 30 minutes at 37 °C. The NPCs in NPC medium were dissociated with Accutase (Stem Cell Technologies), live cells were counted with Trypan Blue (Stem Cell Technologies) in a Burker counting chamber. The NPCs were seeded in the wells of a 384-well plate at defined densities for each cell line. Specifically, the optimal seeding density was determined by visual inspection of the organoids between 28 to 42 days after seeding a range of cell densities in the 384-well plate wells. NPCs were seeded and differentiated in Neural Differentiation Medium: Neurobasal medium (Thermo Fisher Scientific), 1% N2 supplement (Thermo Fisher Scientific), 2% B27-RA supplement (Thermo Fisher Scientific), 1% minimum essential medium/non-essential amino acid (Stem Cell Technologies), 20 ng/ml brain-derived neurotrophic factor (ProSpec Bio), 20 ng/ml glial cell-derived neurotrophic factor (ProSpec Bio), 1 μM dibutyryl cyclic adenosine monophosphate (Sigma-Aldrich), 200 μM ascorbic acid (Sigma-Aldrich), 2 μg/ml laminin (Sigma-Aldrich) and 1% penicillin/streptomycin (Thermo Fisher Scientific). For oligodendrocyte maturation the cells were grown in the presence of 2 ng/ml T3 (Sigma-Aldrich). Cells were refreshed every 2-3 days.
Immunocytochemistry
For live-dead staining, living cultures were incubated with LIVE/DEAD™ Viability/Cytotoxicity Kit according to manufacturer’s instructions (Thermo Fisher Scientific). For immunocytochemistry adherent cortical organoids were fixed for 20-30 minutes using 4% formaldehyde in phosphate-buffered saline (PBS), washed with PBS and blocked for 1 hour by pre-incubation in staining buffer containing 0.05 M Tris, 0.9% NaCl, 0.25% gelatin and 0.5% Triton-X-100 (pH 7.4). Primary antibodies were incubated for 48-72h at 4 °C in staining buffer, washed with PBS and incubated with the secondary antibodies in staining buffer for 2h at room temperature. The cultures were embedded in Mowiol 4-88 (Sigma-Aldrich), after which confocal imaging was performed with a Zeiss LSM700 and Zeiss LSM800 confocal microscope using ZEN software (Zeiss, Oberkochen, Germany). The following primary antibodies were used: SOX2 (Merck-Millipore AB5603, 1:200); Nestin (Merck-Millipore MAB5326, 1:200); MAP2 (Synaptic Systems 188004, 1:100); NeuN (Merck ABN78, 1:200); GFAP (Merck-Millipore AB5804, 1:300); FOXG1 (Abcam AB18259, 1:200); CUX1 (Abcam AB54583, 1:200); CTIP2 (Abcam AB18465, 1:100); Synapsin 1/2 (Synaptic Systems 106003, 1:200); and PSD95 (Thermo Fisher Scientific MA1-046, 1:100); Tau (Cell Signaling Technology 4019, 1:200); S100ß (Sigma-Aldrich S2532, 1:200); Pax6 (Santa Cruz sc-81649, 1:100); NG2 (Gift from W. Stallcup Lab, 1:100); NF200 (Sigma-Aldrich 083M4833 1:200); MBP (Abcam AB7349, 1:100); GFP (Abcam ab13970, 1:100); GAD67 (Merck-Millipore MAB5406, 1:100) DAPI (Thermo Fisher Scientific D1306). The following secondary antibodies were used 1:200: Alexa-488, Alexa-555, Alexa-647 (Jackson ImmunoResearch, West Grove, PA, USA).
Sparse labelling of excitatory neurons
pENN.AAV9.CamKII.4.eGFP.WPRE.rBG (Addgene viral prep # 105541-AAV9) was added to the cortical organoids at day 278 (1.68×108 GC/well). The transduced cortical organoids were fixed and stained at day 310.
Calcium imaging
For calcium imaging the genetically encoded calcium indicator AAV1.Syn.GCaMP6s.WPRE.SV40 (Penn Vector Core, 100843-AAV1) was added to the organoids at day 42 of differentiation (1.5×108 GC/well). Recordings were performed at day 60 on a Zeiss LSM800 confocal microscope using ZEN software (Zeiss, Oberkochen, Germany). The recordings were made with a 20x/0.8NA Ph2 Plan-Apochromat objective, with a field of view of 150 × 100 µm and a pixel size of 0,3 µm. The acquisition rates of the recordings were between 4-5 f.p.s. 24 hours before the recordings, the medium was switched to BrainPhys Neural Differentiation Medium. BrainPhys Neuronal Media (Stem Cell Technologies), 1% N2 supplement (Thermo Fisher Scientific), 2% B27-RA supplement (Thermo Fisher Scientific), 1% minimum essential medium/non-essential amino acid (Stem Cell Technologies), 1% penicillin/streptomycin (Thermo Fisher Scientific), 20 ng/ml brain-derived neurotrophic factor (ProSpec Bio), 20 ng/ml glial cell-derived neurotrophic factor (ProSpec Bio), 1 μM dibutyryl cyclic adenosine monophosphate (Sigma-Aldrich), 200 μM ascorbic acid (Sigma-Aldrich) and 2 μg/ml laminin (Sigma-Aldrich). The calcium imaging recordings were processed using CNMF-E (Pnevmatikakis et al., 2016). Calcium traces were then analysed using a custom script for event and network burst detection using an algorithm written in Python (v3.8.2) (code accessibility can be requested via Github).
Cyquant Proliferation Assay
CyQUANT™ Direct Cell Proliferation Assay, C35011 (Thermo Fisher Scientific) was used according to manufacturer specifications. For each time point and each of the 3 NPC lines 10-12 wells of a 96-well plate were seeded with NPCs (2500 NPCs per well). In addition, NPC lines generated from 2 different clones from IPS line MH0159020 (Rutgers University Cell and DNA Repository) were added to increase the dynamic range of the proliferation curve. At 24h and 96h NPCs were frozen at –80℃. All NPC lines and timepoints were thawed, lysed and measured together. Doubling time was calculated between 24h and 96h. None of the wells was confluent at 96h.
Statistical analysis
All data represent mean ± SEM. When comparing developmental markers in Figure S2 we used one-way ANOVA followed by Tukey-Kramer’s multiple correction test. n=3-6 images taken over two wells, for each time point.
Acknowledgements
This work was supported by the Netherlands Organ-on-Chip Initiative, an NWO Gravitation project funded by the Ministry of Education, Culture and Science of the government of the Netherlands (024.003.001) to SAK, Hersenstichting Fellowship (F2012(1)-39) to FMSdV, an Erasmus MC Human Disease Model Award to FMSdV and a Dutch ZonMw MKMD Create2Solve grant (114025201) to SAK and FMSdV.
Declaration of interests
The authors declare no competing interests.
Supplementary figures
References
- 1.From Human Pluripotent Stem Cells to Cortical CircuitsCurr Top Dev Biol 129:67–98https://doi.org/10.1016/bs.ctdb.2018.02.011
- 2.Neuronal medium that supports basic synaptic functions and activity of human neurons in vitroProc Natl Acad Sci U S A 112https://doi.org/10.1073/pnas.1504393112
- 3.Cell stress in cortical organoids impairs molecular subtype specificationNature :1–7https://doi.org/10.1038/s41586-020-1962-0
- 4.An atlas of cortical arealization identifies dynamic molecular signaturesNature 598:200–204https://doi.org/10.1038/s41586-021-03910-8
- 5.Specification of positional identity in forebrain organoidsNat Biotechnol 37:436–444https://doi.org/10.1038/s41587-019-0085-3
- 6.Ensembles of endothelial and mural cells promote angiogenesis in prenatal human brainCell 185:3753–3769https://doi.org/10.1016/j.cell.2022.09.004
- 7.Human cerebral organoids — a new tool for clinical neurology researchNat Rev Neurol 18:661–680https://doi.org/10.1038/s41582-022-00723-9
- 8.Applications of Brain Organoids for Infectious DiseasesJ Mol Biol 434https://doi.org/10.1016/j.jmb.2021.167243
- 9.Cerebral organoids at the air–liquid interface generate diverse nerve tracts with functional outputNat Neurosci 22:669–679https://doi.org/10.1038/s41593-019-0350-2
- 10.Modeling Rett Syndrome With Human Patient-Specific Forebrain OrganoidsFront Cell Dev Biol 8:1–18https://doi.org/10.3389/fcell.2020.610427
- 11.A simplified protocol for differentiation of electrophysiologically mature neuronal networks from human induced pluripotent stem cellsMol Psychiatry 23:1336–1344https://doi.org/10.1038/mp.2017.56
- 12.Stem Cell Models of Human Brain DevelopmentCell Stem Cell 18:736–748https://doi.org/10.1016/j.stem.2016.05.022
- 13.Engineering induction of singular neural rosette emergence within hPSC-derived tissuesElife 7https://doi.org/10.7554/eLife.37549
- 14.Cerebral organoids model human brain development and microcephalyNature 501:373–379https://doi.org/10.1038/nature12517
- 15.Guided self-organization and cortical plate formation in human brain organoidsNat Biotechnol 35:659–666https://doi.org/10.1038/nbt.3906
- 16.An in vivo model of functional and vascularized human brain organoidsNat Biotechnol 36:432–441https://doi.org/10.1038/nbt.4127
- 17.Organoid and Assembloid Technologies for Investigating Cellular Crosstalk in Human Brain Development and DiseaseTrends Cell Biol https://doi.org/10.1016/j.tcb.2019.11.004
- 18.Vascularization of human brain organoidsStem Cells 39:1017–1024https://doi.org/10.1002/stem.3368
- 19.Development of a Scalable, High-Throughput-Compatible Assay to Detect Tau Aggregates Using iPSC-Derived Cortical Neurons Maintained in a Three-Dimensional Culture FormatJ Biomol Screen https://doi.org/10.1177/1087057116638029
- 20.Neuronal subtype specification in the cerebral cortexNat Rev Neurosci 8:427–37https://doi.org/10.1038/nrn2151
- 21.Spatiotemporal gene expression trajectories reveal developmental hierarchies of the human cortexScience 358https://doi.org/10.1126/science.aap8809
- 22.Transformation of the Radial Glia Scaffold Demarcates Two Stages of Human Cerebral Cortex DevelopmentNeuron 91https://doi.org/10.1016/j.neuron.2016.09.005
- 23.Temporal morphogen gradient-driven neural induction shapes single expanded neuroepithelium brain organoids with enhanced cortical identityNat Commun 14https://doi.org/10.1038/s41467-023-43141-1
- 24.Functional cortical neurons and astrocytes from human pluripotent stem cells in 3D cultureNat Methods https://doi.org/10.1038/nmeth.3415
- 25.A nomenclature consensus for nervous system organoids and assembloidsNature 609:907–910https://doi.org/10.1038/s41586-022-05219-6
- 26.Human CNS barrier-forming organoids with cerebrospinal fluid productionScience 369https://doi.org/10.1126/science.aaz5626
- 27.Brain-Region-Specific Organoids Using Mini-bioreactors for Modeling ZIKV ExposureCell 165:1238–1254https://doi.org/10.1016/j.cell.2016.04.032
- 28.Sliced Human Cortical Organoids for Modeling Distinct Cortical Layer FormationCell Stem Cell 26:766–781https://doi.org/10.1016/j.stem.2020.02.002
- 29.Brain-Region-Specific Organoids Using Mini-bioreactors for Modeling ZIKV ExposureCell 165:1238–1254https://doi.org/10.1016/j.cell.2016.04.032
- 30.Cell diversity and network dynamics in photosensitive human brain organoidsNature 545:48–53https://doi.org/10.1038/nature22047
- 31.Self-organized developmental patterning and differentiation in cerebral organoidsEMBO J 36:1316–1329https://doi.org/10.15252/embj.201694700
- 32.Efficient Generation of CA3 Neurons from Human Pluripotent Stem Cells Enables Modeling of Hippocampal Connectivity In VitroCell Stem Cell 22:684–697https://doi.org/10.1016/j.stem.2018.04.009
- 33.Developmental excitation-inhibition imbalance underlying psychoses revealed by single-cell analyses of discordant twins-derived cerebral organoidsMol Psychiatry 25:2695–2711https://doi.org/10.1038/s41380-020-0844-z
- 34.Human cerebral cortex development from pluripotent stem cells to functional excitatory synapsesNat Neurosci 15:477–86https://doi.org/10.1038/nn.3041
- 35.Deriving early single-rosette brain organoids from human pluripotent stem cellsStem Cell Reports 18:2498–2514https://doi.org/10.1016/j.stemcr.2023.10.020
- 36.Proper acquisition of cell class identity in organoids allows definition of fate specification programs of the human cerebral cortexCell 185:3770–3788https://doi.org/10.1016/j.cell.2022.09.010
- 37.Activity-based protein profiling reveals off-target proteins of the FAAH inhibitor BIA 10-2474Science 356:1084–1087https://doi.org/10.1126/science.aaf7497
- 38.Individual brain organoids reproducibly form cell diversity of the human cerebral cortexNature 1https://doi.org/10.1038/s41586-019-1289-x
- 39.Transplantation Strategies to Enhance Maturity and Cellular Complexity in Brain OrganoidsBiol Psychiatry 93:616–621https://doi.org/10.1016/j.biopsych.2023.01.004
- 40.hESC-Derived Thalamic Organoids Form Reciprocal Projections When Fused with Cortical OrganoidsCell Stem Cell 24:487–497https://doi.org/10.1016/J.STEM.2018.12.015
- 41.Reliability of human cortical organoid generationNat Methods 16:75–78https://doi.org/10.1038/s41592-018-0255-0
- 42.Cell-Surface Marker Signatures for the Isolation of Neural Stem Cells, Glia and Neurons Derived from Human Pluripotent Stem CellsPLoS One 6https://doi.org/10.1371/journal.pone.0017540
- 43.Rapid Single-Step Induction of Functional Neurons from Human Pluripotent Stem CellsNeuron 78:785–798https://doi.org/10.1016/j.neuron.2013.05.029
- 44.Development and Application of Brain Region–Specific Organoids for Investigating Psychiatric DisordersBiol Psychiatry 93:594–605https://doi.org/10.1016/j.biopsych.2022.12.015
Article and author information
Author information
Version history
- Sent for peer review:
- Preprint posted:
- Reviewed Preprint version 1:
Copyright
© 2024, van der Kroeg et al.
This article is distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use and redistribution provided that the original author and source are credited.
Metrics
- views
- 564
- downloads
- 19
- citations
- 0
Views, downloads and citations are aggregated across all versions of this paper published by eLife.