Self-Organizing 3D Human Neural Tissue Derived from Induced Pluripotent Stem Cells Recapitulate Alzheimer's Disease Phenotypes.

paper Cited Public

Authors: Raja, Waseem K; Mungenast, Alison E; Lin, Yuan-Ta; Ko, Tak; Abdurrob, Fatema; Seo, Jinsoo; Tsai, Li-Huei
Year: 2016
Journal: PloS one
PMID: 27622770
DOI: 10.1371/journal.pone.0161969
PMCID: PMC5021368

Fig 1

Organoids created from patient-derived iPSCs exhibit robust Alzheimer’s disease (AD)-like pathology.(A) Concentration of Aβ1–40 and Aβ1–42 from supernatant of control (Ctrl; CS-0020-01) and familial AD (fAD; APPDp1-1) organoid cultures, measured by ELISA, as well as the ratio of Aβ1–42 to Aβ1–40 concentrations. Unpaired two-tailed t-test with equal variance: *p = 0.047 (Aβ1–40), unpaired two-tailed t-test with Welch’s correction for unequal variance: **p = 0.004 (Aβ1–42), p = 0.48 (Aβ1-42/Aβ1–40). (B) Tissue sections from fAD (APPDp1-1) and control (Ctrl; CS-0020-01) organoids were processed for immunoreactivity against amyloid β (Aβ) using two antibodies (D54D2: white, 4G8: green), as well as antibodies against the neuronal marker MAP2 (red) and stained with the nuclear dye Hoechst (blue). Insets demonstrate Aβ immunoreactivity that appears both extracellular (i, arrow) and intracellular (ii, arrowhead) based upon MAP2 co-localization. (C) Z-projection of immunolabeled tissue sections from 90 day old Ctrl and fAD organoids showing immunoreactivity for Aβ (D45D2: white) and MAP2 (red). The edge of the tissue section is visible at the left bottom corner of each example. (D) Quantification of Aβ immunoreactivity in fAD and Ctrl organoids following 60d and 90d culture. Particle Counts: one-way ANOVA with post-hoc Fishers Least Significant Difference (LSD) test for multiple comparisons; F (3,28) = 4.385, ***p = 0 0.0008, R2 = 0.32 (i-60 days); F (5,43) = 3.346, *p = 0 0.012, R2 = 0.28 (90 days). Particle Size: Two-tailed Mann Whitney test for non-normal distributions (normality α < 0.05), **p = 0.006 (60 days), ***p = 0.001 (90 days). (E) Tissue sections from fAD (APPDp1-1) and control (Ctrl; CS-0020-01) organoids were processed for immunoreactivity against phosphorylated Tau (pTau, green) at Serine 396 (S396) and MAP2 (red) following 90d culture. Hoechst (blue) labels cell nuclei. (F) Quantification of pTau immunoreactivity for the Ser396 at 60d and 90d, and for the Threonine 181 (Thr181) pTau at 90d. Values are plotted as mean intensity of immunoreactivity as fold change of Ctrl. Unpaired two-tailed t-test with equal variance: p = 0.67 (60 day Ser396), **p = 0.001 (90 day Ser396), *p = 0.03 (90 day Thr181). (G) Sections from fAD (APPDp1-1) and control (Ctrl; CS-0020-01) organoids were processed for immunoreactivity against the early endosome antigen 1 (EEA1, green) and MAP2 (red). The dotted white line outlines the region of higher magnification to show EEA1 detail. (H) Quantification of EEA1 immunoreactivity in fAD and Ctrl organoids following 90d culture. EEA1 Particle Counts: one-way ANOVA with post-hoc Fisher’s LSD test for multiple comparisons; F (3,16) = 4.0, *p = 0.026, R2 = 0.43. EEA1 Particle size: unpaired two-tailed t-test with Welch’s correction: *p = 0.041. (I) Organoids from Ctrl and fAD lines were subjected to the transferrin endocytosis assay to label pools of clathrin-coated early endosomes. (Each data point represent one organoid) Quantification of the average size of transferrin-positive particles: unpaired two-tailed t-test with equal variance, **p = 0.005. Average number (count) of transferrin-positive particles, unpaired two-tailed t-test with equal variance, p = 0.64. On charts: *p < 0.05, **p < 0.01, ***p < 0.001.

Fig 2

Organoids created from different lines of AD patient iPSCs exhibit AD phenotypes.(A) Tissue sections from fAD (APPDp2-3, ND34732, AG068840) and control (Ctrl; CS-0020-01, AG09173) organoids were processed for immunoreactivity against Aβ (D45D2, white), MAP2 (red), and pTau (S396, green) and labeled with the nuclear dye Hoechst. (B) Quantification of Aβ immunoreactivity in fAD and Ctrl organoids following 90 days of culture. Values between the two control lines did not significantly differ. Number of Aβ-positive aggregates in two size classes (Particle Counts): one-way ANOVA with post-hoc Tukey’s multiple comparisons test; F (4,21) = 6.15, **p = 0.0019, R2 = 0.5396 (1–3μm); F (4,21) = 7.95, ***p = 0.0005, R2 = 0.6024 (3–6 μm). (C) Quantification of the average intensity of pTau Ser396 immunoreactivity as a fold change of Ctrl in fAD and Ctrl organoids following 90 days of culture. Values between the two control lines did not significantly differ. (Each data point represent one organoid). One-way ANOVA with post-hoc Tukey’s multiple comparisons test; F (4,20) = 9.629, ***p = 0.0002, R2 = 0.6582. On charts: *p < 0.05, **p < 0.01, ***p < 0.001.

Fig 3

Organoids created from AD patient iPSCs respond to compound treatment.(A) Schematic of beta (BACE-1) and gamma (Comp-E) secretase inhibitor treatment (top). At 30 days of culture, fAD (APPDp1-1) organoids were treated with low dose (BACE-1, 1μM and Comp-E, 3nM) or high dose (BACE-1, 5 μM and Comp-E 6nM) combined compounds, or equivalent DMSO vehicle. Following 30 or 60 days of culture and drug treatment, organoids at 60 and 90 days of culture, respectively, were processed for immunohistochemistry (IHC). Tissue sections from fAD (APPDp1-1) and control (Ctrl; CS-0020-01) organoids were processed for immunoreactivity against Aβ (D45D2, white), pTau (Ser396, green), and MAP2 (red). Examine images are from 90 day organoids. (B) Quantification of Aβ particle number and size in compound treated and fAD organoids following 30 days of administration. Number of Aβ-positive aggregates in two size classes (Particle Counts): one-way ANOVA with Fishers LSD test for multiple comparisons; F (5,24) = 3.58, *p = 0.014, R2 = 0.4296. Particle size: one-way ANOVA with Kruskal-Wallis test for non-normal distribution (α < 0.05), p = 0.475. (C) Quantification of Aβ particle number and size in treated (high dose) and untreated fAD organoids following 60 days of compound administration. Number of Aβ-positive aggregates in three size classes (Particle Counts): one-way ANOVA with Fishers LSD test for multiple comparisons; F (5,19) = 5.02, **p = 0.004, R2 = 0.5691. Particle size: Mann-Whitney two-tailed test for non-normal distribution (α < 0.05), p = 0.09. (D) Quantification of the average intensity of pTau Ser396 immunoreactivity as a fold change of Ctrl in fAD organoids following 30 and 60 days of compound treatment. 30 day treatment. (Each data point represent one organoid). Unpaired two-tailed t-test with equal variance, p = 0.69. 60 day treatment: one-way ANOVA with Tukey’s multiple comparisons test, F (2,13) = 19.82, ***p = 0.0001, R2 = 0.7530. On charts: *p < 0.05, **p < 0.01, ***p < 0.001.

#	Section	Preview
0	Introduction	Alzheimer’s disease (AD) is an age-related neurodegenerative disorder associated with severe…
1	Introduction	Neurological conditions are difficult to study because of the limited accessibility to human brain…
2	Introduction	One concern with the use of in vitro systems to model AD pathology, however, is that phenotypes of…
3	Introduction	While the tissue engineering approaches mentioned above do produce AD-like phenotypes and are highly…
4	Results — Generation of organoids and analysis	To investigate the utility of such a system, we created scaffold free three-dimensional (3D) human…
5	Results — Generation of organoids and analysis	of neuroectoderm and immunolabeling for neuronal MAP2 as well as SOX2-positive neural progenitor…
6	Results — Generation of organoids and analysis	At 60d and 90d of culture, we subjected organoids from a healthy control (Ctrl) and a familial (fAD)…
7	Results — Generation of organoids and analysis	from the surface into the interior of the organoid (S3A Fig). In addition, we incubated sections…
8	Results — Alzheimer’s disease phenotypes in organoids — Amyloid beta	Neurons derived from the APPDp1-1 line had previously exhibited increased levels of secreted Aβ40…
9	Results — Alzheimer’s disease phenotypes in organoids — Amyloid beta	that were immunopositive for both Aβ antibodies (Fig 1B), while 4G8 immunoreactivity appeared…
10	Results — Alzheimer’s disease phenotypes in organoids — Hyperphosphorylated Tau (pTau)	Another hallmark of AD is the abnormal phosphorylation, mislocalization, and aggregation of the tau…
11	Results — Alzheimer’s disease phenotypes in organoids — Endosome abnormalities	Endosome abnormalities are another common cellular phenotype in AD. Enlarged RAB5-positive early…
12	Results — Alzheimer’s disease phenotypes in organoids — Endosome abnormalities	particles in the fAD organoids (Fig 1H). To functionally assess endosome trafficking in the control…
13	Results — Organoids from multiple AD lines recapitulate AD pathology	To ascertain whether the AD phenotypes of Aβ aggregation and Tau hyperphosphorylation are…
14	Results — Attenuation of AD pathology in neural organoids by β- and γ-secretase inhibitor treatment	These data indicate that organoids created from multiple fAD patient iPSC lines demonstrate robust…
15	Results — Attenuation of AD pathology in neural organoids by β- and γ-secretase inhibitor treatment	compared to vehicle treated fAD tissue (Fig 3B). This reduction was particularly evident in the in…
16	Discussion	In diseases such as AD that are characterized by protein aggregation, the presence of a true…
17	Discussion	The ease with which large numbers of these organoids can be created, and their ability to respond to…
18	Discussion	One powerful aspect of the current model is the spontaneous appearance of both [1] amyloid and tau…
19	Discussion	in close agreement with that observed in the scaffolded 3D cultures of Choi et al. 2014; [40].…

Name	Type
1 N sulfuric acid local	drug
2-mercaptoethanol	drug
3,3',5,5'-tetramethylbenzidine local	drug
4G8 local	drug
abnormal endosome morphology local	phenotype
accutase	drug
AD-associated variant local	variant
AD-like phenotype local	phenotype
AD-like phenotypes local	phenotype
AD patient-derived cells local	cohort
AD patient-derived organoid culture models local	cohort
AD patients	cohort
AG09173 local	cohort
aged human brain local	anatomy
age-related AD-like pathology local	phenotype
Age-related neurodegeneration local	phenotype
Alexa Fluor-488 local	drug
Alzheimer's disease	phenotype
Alzheimer’s disease	phenotype
amyloid aggregates local	phenotype
Amyloid aggregates local	phenotype
Amyloid beta	drug
amyloid pathology	phenotype
amyloid phenotype local	phenotype
Amyloid plaque deposition local	phenotype
amyloid plaques	phenotype
amyloid β	drug
animal models	cohort
apoE	gene
apoptotic cells local	phenotype
APP	gene
APPDp1-1 local	cohort
APPDp1-1 line local	cohort
APPDp2-3 local	cohort
APP duplication local	variant
artificial blood-brain barrier technology local	drug
Aβ 1-40 local	drug
Aβ 1-42 local	drug
Aβ40 local	drug
Aβ42 local	drug
Aβ42/40 ratio local	phenotype
Aβ accumulation	phenotype
Aβ aggregates local	phenotype
Aβ aggregation local	phenotype
Aβ oligomers local	phenotype
Aβ production local	drug
B27 supplement	drug
BACE-1 local	drug
BACE-1 local	gene
beta-amyloid	drug
beta-Fibroblast Growth Factor local	drug
CASP3	gene
Chemically Defined Lipid Concentrate local	drug
cleaved caspase 3 local	drug
Cleaved Caspase-3 (Asp175) antibody local	drug
c-myc	gene
cognition	phenotype
cognitive decline	phenotype
compound	drug
compound E	drug
control	cohort
control organoids	cohort
culture medium interface local	drug
Cy2 local	drug
Cy3	drug
Cy5	drug
D54D2 local	drug
D9F4G local	drug
DMEM/F12	drug
DMSO vehicle local	drug
DNA damage	phenotype
dorsomorphin	drug
drug treatment	drug
early-onset familial AD local	cohort
EEA1 local	drug
EEA1 local	gene
EEA1 antibody local	drug
ELISA kit for Aβ (1–40) and Aβ (1–42) local	drug
Endosome abnormalities local	phenotype
ethanol consumption	phenotype
fAD local	cohort
fAD	gene
fAD genes local	gene
fAD organoids local	cohort
fAD organoids local	phenotype
fAD patient iPSC lines local	cohort
fAD patients	cohort
familial Alzheimer’s disease local	phenotype
fetal bovine serum	drug
Fluoromount-G local	drug
frontotemporal dementia	phenotype
gelatin	drug
Glasgow-MEM local	drug
gliosis	phenotype
Glutamax	drug
healthy controls	cohort
heparin	drug
Hoechst 33342	drug
horse serum	drug
HRP-conjugated secondary antibody local	drug
human fibroblasts	cohort
hyperphosphorylated tau	drug
ImageJ	drug
induced pluripotent stem cells	drug
inner tissue region local	anatomy
iPSCs	cohort
Klf4	gene
knockout serum replacement	drug
KSR	drug
Life Technologies Corporation local	cohort
MAP2	gene
Mapt	gene
matrigel	drug
mitochondrial function	phenotype
N2 supplement	drug
nail polish local	drug
NEAA	drug
necrosis	phenotype
neural organoids local	phenotype
Neural organoids local	drug
neural progenitor cells local	phenotype
neurodevelopment	phenotype
neuroectoderm local	anatomy
Neuroectoderm local	anatomy
neurofibrillary tangles	phenotype
neuroinflammation	phenotype
neurological disorders	phenotype
neuronal loss	phenotype
neurons	phenotype
non-essential amino acids	drug
nonspecific antibody binding local	phenotype
OCT	drug
Oct4	gene
organoid local	anatomy
organoid local	cohort
organoids	cohort
organoid system local	phenotype
oxalic acid local	drug
paraformaldehyde	drug
patient iPSC-derived organoids local	cohort
PHF13 local	drug
phosphate-buffered saline	drug
phosphorylated tau	drug
Pluronic acid (F-127) local	drug
potassium metabisulfite local	drug
potassium permanganate local	drug
protein aggregation local	phenotype
PSEN1	gene
PSEN1A264E local	variant
PSEN1M146I local	variant
PSEN2	gene
pTau local	phenotype
pTau immunoreactivity local	phenotype
Rab5	gene
Rock inhibitor	drug
Scaffold-free culture local	drug
scaffold-free three dimensional model local	phenotype
secondary antibody	drug
Sendai virus	drug
Ser396 local	variant
Sodium Pyruvate local	drug
SORL1	gene
Sox2	gene
sucrose	drug
superficial region local	anatomy
synaptic dysfunction	phenotype
tau	phenotype
tau hyperphosphorylation local	phenotype
Tau hyperphosphorylation local	phenotype
tauopathy	phenotype
tau pathology	phenotype
telomere length	phenotype
TGFβ-inhibitor (SB431532) local	drug
thioflavin-S	drug
Thioflavin-S dye local	drug
Thr181 local	variant
three-dimensional neural culture systems local	cohort
tissue necrosis local	phenotype
transferrin	drug
Transgenic rodents local	cohort
TREM2	gene
Triton-X100	drug
U1 tangles local	phenotype
Wnt-inhibitor (IWRe1) local	drug
Y-27632 dihydrochloride local	drug
β-amyloid	drug
β-secretase inhibitor	drug
β-Secretase Inhibitor IV local	drug
γ-secretase	drug
γ-secretase inhibitor	drug

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In this knowledge base

Title	Year	PMID
Genetics of Alcohol Use Disorder: A Role for Induced Pluripotent Stem Cells?	2018	29897633

External

Title	Authors	Journal	Year	Link
Advances in 3D Organoids and Organ-on-a-Chip Systems for Biomedical Research.	Sakthivel V et al.	—	2026	→
Advances in hiPSC-Derived Brain Organoids as a Model to Study Neuroinflammation in Alzheimer's Disease.	Maciel EMA et al.	—	2026	→
Advances in the pathophysiological study of brain development: application of cerebral organoid combined with Spatial omics technology.	Wang J et al.	—	2026	→
AI and organoid platforms for brain-targeted theranostics.	Ye R et al.	—	2026	→
A multi-target therapeutic framework for Alzheimer's disease: an integrative mechanistic review.	Bajinka O et al.	—	2026	→
Establishment of a human inner ear model reveals that gentamicin C2b is substantially less ototoxic than clinical gentamicin.	Jeong M et al.	—	2026	→
Experimental and translational models of Alzheimer's disease: From neurodegeneration to novel therapeutic insights.	Khan N et al.	—	2026	→
Human cerebral organoids: Complex, versatile, and human-relevant models of neural development and brain diseases.	Coronel R et al.	—	2026	→
Human organoids as 3D in vitro platforms for drug discovery: opportunities and challenges.	Wang D et al.	—	2026	→
Mapping the Cerebral Organoid Landscape: A Systematic Review of Preclinical 3D Models in Neuroscience.	Wolfram A et al.	—	2026	→
Proteomic profiling of brain organoids and extracellular vesicles identifies early Alzheimer's disease biomarkers and drug response heterogeneity.	Boyd RJ et al.	—	2026	→
Advanced Cellular Models for Neurodegenerative Diseases and PFAS-Related Environmental Risks.	Rotondo D et al.	—	2025	→
Advanced neural activity mapping in brain organoids via field potential imaging with ultra-high-density CMOS microelectrode arrays.	Yokoi R et al.	—	2025	→
Advancement in modeling of Alzheimer's disease: a comprehensive review of preclinical screening platforms.	Adak S et al.	—	2025	→
Advances in the Development and Application of Human Organoids: Techniques, Applications, and Future Perspectives.	Zhu Z et al.	—	2025	→
Alternative splicing in Alzheimer's disease: Mechanisms, therapeutic implications, and 3D modeling approaches.	Pasteris M et al.	—	2025	→
Alzheimer's disease patient brain extracts induce multiple pathologies in novel vascularized neuroimmune organoids for disease modeling and drug discovery.	Ji Y et al.	—	2025	→
Amyloid-β Seeds in Alzheimer's Disease: Research Challenges and Implications.	Beschorner N et al.	—	2025	→
A neuroimmune cerebral assembloid model to study the pathophysiology of familial Alzheimer's disease.	Becerra-Calixto A et al.	—	2025	→
[Application of neural organoids containing microglia to neurodegenerative disease research].	Harada K et al.	—	2025	→
Astrocyte priming enhances microglial Aβ clearance and is compromised by APOE4.	Lee SI et al.	—	2025	→
Bioelectronic Interfaces and Sensors for Neural Organoids.	Wang Q et al.	—	2025	→
Brain Organoid Research in a Post-Dobbs World.	Coughlin CN et al.	—	2025	→
Cryopreserving 3D cell culture models of Alzheimer's disease in hydrogel microbeads.	Kim JJ et al.	—	2025	→
Current Development of iPSC-Based Modeling in Neurodegenerative Diseases.	Guo X et al.	—	2025	→
Emerging brain organoids: 3D models to decipher, identify and revolutionize brain.	Zhao Y et al.	—	2025	→
Emerging Insights into Brain Inflammation: Stem-Cell-Based Approaches for Regenerative Medicine.	Karam M et al.	—	2025	→
Enhanced differentiation of neural progenitor cells in Alzheimer's disease into vulnerable immature neurons.	Cho J et al.	—	2025	→
Exploring neuronal circuitry in neurodegenerative diseases: from traditional models to cutting-edge techniques.	Ausilio C et al.	—	2025	→
Generation of Neural Organoids and Their Application in Disease Modeling and Regenerative Medicine.	Huang R et al.	—	2025	→
Genetic Manipulation in Organoid Models and Their Applications in Central Nervous System Pathologies.	Rustamov A et al.	—	2025	→
Human brain organoids: an innovative model for neurological disorder research and therapy.	Li H et al.	—	2025	→
Immunosenescence and organoids: pathophysiology and therapeutic opportunities.	Kamroo A et al.	—	2025	→
iPSC-derived neural organoids in dementia research: Recent advances and future directions.	Shima S et al.	—	2025	→
Microglial Drivers of Alzheimer's Disease Pathology: An Evolution of Diverse Participating States.	Kuhn MK et al.	—	2025	→
Modeling Alzheimer's Disease: A Review of Gene-Modified and Induced Animal Models, Complex Cell Culture Models, and Computational Modeling.	Timofeeva AM et al.	—	2025	→
Modeling neurodegenerative diseases with brain organoids: from development to disease applications.	Larriba-González T et al.	—	2025	→
Modeling Sporadic Progressive Supranuclear Palsy in 3D Midbrain Organoids: Recapitulating Disease Features for In Vitro Diagnosis and Drug Discovery.	Parrotta EI et al.	—	2025	→
Non-Invasive Quality Control of Organoid Cultures Using Mesofluidic CSTR Bioreactors and High-Content Imaging.	Charles S et al.	—	2025	→
Patient-Derived Cortical Organoids Reveal Senescence of Neural Progenitor Cells in Hutchinson-Gilford Progeria Syndrome.	Jeon S et al.	—	2025	→
Pelota-mediated ribosome-associated quality control counteracts aging and age-associated pathologies across species.	Lee J et al.	—	2025	→
Polygenic risk score of Alzheimer's disease is associated with cognitive trajectories and phenotypes of cerebral organoids.	Chun MY et al.	—	2025	→
Recent advances in 3D bioprinted neural models: A systematic review on the applications to drug discovery.	Orr A et al.	—	2025	→
Reviewing the possible connection between cerebral amyloid angiopathy and blood-brain barrier integrity in Down syndrome.	Valay L et al.	—	2025	→
Senolytics rejuvenate aging cardiomyopathy in human cardiac organoids.	Scalise M et al.	—	2025	→
Targeting RPSA to modulate endosomal trafficking and amyloidogenesis in genetic Alzheimer's disease.	Limone A et al.	—	2025	→
The pathophysiology of mixed Alzheimer's disease and vascular dementia.	Sarhan M et al.	—	2025	→
The translational power of Alzheimer's-based organoid models in personalized medicine: an integrated biological and digital approach embodying patient clinical history.	Dolciotti C et al.	—	2025	→
Transformative advances in modeling brain aging and longevity: Success, challenges and future directions.	Pai V et al.	—	2025	→
WITHDRAWN: GeneTerrain-GMM Unmasks a Coordinated Neuroinflammatory and Cell Death Network Perturbed by Dasatinib in a Human Neuronal Model of Alzheimer’s Disease	Song KM et al.	—	2025	—
A framework for translating tauopathy therapeutics: Drug discovery to clinical trials.	Feldman HH et al.	—	2024	→
Aging phenotype in AD brain organoids: Track to success and challenges.	Hossain MK et al.	—	2024	→
Alzheimer's disease and its treatment-yesterday, today, and tomorrow.	Kim AY et al.	—	2024	→
Alzheimer's Disease from Modeling to Mechanism Research.	Sun X et al.	—	2024	→
Applications of multiphoton microscopy in imaging cerebral and retinal organoids.	Lacin ME et al.	—	2024	→
Brain organoid protocols and limitations.	Zhao HH et al.	—	2024	→
Brain Organoids: A Game-Changer for Drug Testing.	Giorgi C et al.	—	2024	→
Brain organoids: A revolutionary tool for modeling neurological disorders and development of therapeutics.	Acharya P et al.	—	2024	→
Development of Midbrain Dopaminergic Neurons and the Advantage of Using hiPSCs as a Model System to Study Parkinson's Disease.	Samson JS et al.	—	2024	→
Differential effects of <i>SORL1</i> deficiency on the endo-lysosomal network in human neurons and microglia.	Mishra S et al.	—	2024	→
Dynamic culture of cerebral organoids using a pillar/perfusion plate for the assessment of developmental neurotoxicity.	Acharya P et al.	—	2024	→
Human brain organoids containing microglia that have arisen innately adapt to a β-amyloid challenge better than those in which microglia are integrated by co-culture.	Wenzel TJ et al.	—	2024	→
Human brain organoid: trends, evolution, and remaining challenges.	Li M et al.	—	2024	→
Human iPSC-derived retinal organoids develop robust Alzheimer's disease neuropathology.	James E et al.	—	2024	→
Human Neural Stem Cell Expansion in Natural Polymer Scaffolds Under Chemically Defined Condition.	Chang FC et al.	—	2024	→
Human stem cell transplantation models of Alzheimer's disease.	Ifediora N et al.	—	2024	→
Hydrogen peroxide is not generated intracellularly in human neural spheroids during ischemia-reperfusion.	Usatova VS et al.	—	2024	→
Induced pluripotent stem cell models as a tool to investigate and test fluid biomarkers in Alzheimer's disease and frontotemporal dementia.	McInvale JJ et al.	—	2024	→
Induced Pluripotent Stem Cells and Organoids in Advancing Neuropathology Research and Therapies.	Pazzin DB et al.	—	2024	→
Induced Pluripotent Stem Cells in Drug Discovery and Neurodegenerative Disease Modelling.	Beghini DG et al.	—	2024	→
In Vitro Models for Peripheral Nerve Regeneration.	Tusnim J et al.	—	2024	→
Microphysiological systems for human aging research.	Park S et al.	—	2024	→
Modeling Alzheimer's disease using human cell derived brain organoids and 3D models.	Fernandes S et al.	—	2024	→
Modeling late-onset Alzheimer's disease neuropathology via direct neuronal reprogramming.	Sun Z et al.	—	2024	→
Morphogenetic Designs, and Disease Models in Central Nervous System Organoids.	Bock M et al.	—	2024	→
Neuropathogenesis-on-chips for neurodegenerative diseases.	Amartumur S et al.	—	2024	→
Non-invasive label-free imaging analysis pipeline for in situ characterization of 3D brain organoids.	Serafini CE et al.	—	2024	→
Nucleoporin 153 deficiency in adult neural stem cells defines a pathological protein-network signature and defective neurogenesis in a mouse model of AD.	Colussi C et al.	—	2024	→
Optogenetic and chemogenetic approaches for modeling neurological disorders in vivo.	Krut' VG et al.	—	2024	→
Organoids and chimeras: the hopeful fusion transforming traumatic brain injury research.	Bellotti C et al.	—	2024	→
Organoids as preclinical models of human disease: progress and applications.	Chen B et al.	—	2024	→
Pros and Cons of Human Brain Organoids to Study Alzheimer's Disease.	Sainz A et al.	—	2024	→
Recent advances and applications of human brain models.	Nishimura K et al.	—	2024	→
Simple modeling of familial Alzheimer's disease using human pluripotent stem cell-derived cerebral organoid technology.	Choe MS et al.	—	2024	→
Strategies for modeling aging and age-related diseases.	Jothi D et al.	—	2024	→
Tackling neurodegeneration <i>in vitro</i> with omics: a path towards new targets and drugs.	Carraro C et al.	—	2024	→
TERT activation targets DNA methylation and multiple aging hallmarks.	Shim HS et al.	—	2024	→
Therapeutic Transplantation of Human Central Nervous System Organoids for Neural Reconstruction.	Hong SJ et al.	—	2024	→
Updates in Alzheimer's disease: from basic research to diagnosis and therapies.	Liu E et al.	—	2024	→
3D bioprinting patient-derived induced pluripotent stem cell models of Alzheimer's disease using a smart bioink.	Benwood C et al.	—	2023	→
A beginner's guide on the use of brain organoids for neuroscientists: a systematic review.	Mulder LA et al.	—	2023	→
Advances in current <i>in vitro</i> models on neurodegenerative diseases.	Pereira I et al.	—	2023	→
Alzheimer's disease and synapse Loss: What can we learn from induced pluripotent stem Cells?	Rodriguez-Jimenez FJ et al.	—	2023	→
Amyloid β-based therapy for Alzheimer's disease: challenges, successes and future.	Zhang Y et al.	—	2023	→
An AI-based segmentation and analysis pipeline for high-field MR monitoring of cerebral organoids.	Deininger L et al.	—	2023	→
Analysis of Aβ-induced neurotoxicity and microglial responses in simple two- and three-dimensional human iPSC-derived cortical culture systems.	Takata M et al.	—	2023	→
Application of Human Brain Organoids-Opportunities and Challenges in Modeling Human Brain Development and Neurodevelopmental Diseases.	Kim SH et al.	—	2023	→
Applications of Induced Pluripotent Stem Cell-Derived Glia in Brain Disease Research and Treatment.	Yang Z et al.	—	2023	→
BACE2: A Promising Neuroprotective Candidate for Alzheimer's Disease.	Yeap YJ et al.	—	2023	→
Bibliometric analysis of cerebral organoids and diseases in the last 10 years.	Luo BY et al.	—	2023	→
Cerebral Organoid Arrays for Batch Phenotypic Analysis in Sections and Three Dimensions.	Chen J et al.	—	2023	→
Cerebral organoids derived from patients with Alzheimer's disease with PSEN1/2 mutations have defective tissue patterning and altered development.	Vanova T et al.	—	2023	→
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Complexity of Sex Differences and Their Impact on Alzheimer's Disease.	Kadlecova M et al.	—	2023	→
Comprehensive Bibliometric Analysis of Stem Cell Research in Alzheimer's Disease from 2004 to 2022.	Wang R et al.	—	2023	→
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Development and Application of Brain Region-Specific Organoids for Investigating Psychiatric Disorders.	Zhang Z et al.	—	2023	→
Development of brain organoid technology derived from iPSC for the neurodegenerative disease modelling: a glance through.	Jusop AS et al.	—	2023	→
Experimental Models of In Vitro Blood-Brain Barrier for CNS Drug Delivery: An Evolutionary Perspective.	Chaulagain B et al.	—	2023	→
Exploring the Pathophysiology of Delirium: An Overview of Biomarker Studies, Animal Models, and Tissue-Engineered Models.	McKay TB et al.	—	2023	→
Functional bioengineered tissue models of neurodegenerative diseases.	Mullis AS et al.	—	2023	→
Generation of advanced cerebellar organoids for neurogenesis and neuronal network development.	Chen Y et al.	—	2023	→
How Organ-on-a-Chip Technology Can Assist in Studying the Role of the Glymphatic System in Neurodegenerative Diseases.	Spitz S et al.	—	2023	→
Human 3D brain organoids: steering the demolecularization of brain and neurological diseases.	Adlakha YK	—	2023	→
Human-Induced Pluripotent Stem Cell (hiPSC)-Derived Neurons and Glia for the Elucidation of Pathogenic Mechanisms in Alzheimer's Disease.	Young JE et al.	—	2023	→
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In Vitro 3D Modeling of Neurodegenerative Diseases.	Louit A et al.	—	2023	→
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Modeling early human cortical development and evaluating neurotoxicity with a forebrain organoid system.	Cao Y et al.	—	2023	→
Molecular Insights into Cell Type-specific Roles in Alzheimer's Disease: Human Induced Pluripotent Stem Cell-based Disease Modelling.	Qu W et al.	—	2023	→
Multi-omics data integration methods and their applications in psychiatric disorders.	Sathyanarayanan A et al.	—	2023	→
Neural cortical organoids from self-assembling human iPSC as a model to investigate neurotoxicity in brain ischemia.	De Paola M et al.	—	2023	→
Neural lineage differentiation of human pluripotent stem cells: Advances in disease modeling.	Yan YW et al.	—	2023	→
Organoids for modeling prion diseases.	Walters RO et al.	—	2023	→
Recent Advances in Brain Organoid Technology for Human Brain Research.	Jeong E et al.	—	2023	→
Recent Development of Brain Organoids for Biomedical Application.	Kim H et al.	—	2023	→
The Breakthroughs and Caveats of Using Human Pluripotent Stem Cells in Modeling Alzheimer's Disease.	Sahlgren Bendtsen KM et al.	—	2023	→
The Impact of the Cellular Environment and Aging on Modeling Alzheimer's Disease in 3D Cell Culture Models.	Hebisch M et al.	—	2023	→
Tools for studying human microglia: In vitro and in vivo strategies.	Warden AS et al.	—	2023	→
Two-step method fabricating a 3D nerve cell model with brain-like mechanical properties and tunable porosity vascular structures via coaxial printing.	Wang Z et al.	—	2023	→
Use of <i>in vitro</i> derived human neuronal models to study host-parasite interactions of <i>Toxoplasma gondii</i> in neurons and neuropathogenesis of chronic toxoplasmosis.	Halonen SK	—	2023	→
3D Cell Cultures: Evolution of an Ancient Tool for New Applications.	Cacciamali A et al.	—	2022	→
A 3D-induced pluripotent stem cell-derived human neural culture model to study certain molecular and biochemical aspects of Alzheimer's disease.	Prasannan P et al.	—	2022	→
Accelerated neuronal aging <i>in vitro</i> ∼melting watch ∼.	Inagaki E et al.	—	2022	→
A Comprehensive Update of Cerebral Organoids between Applications and Challenges.	Li X et al.	—	2022	→
Advanced human developmental toxicity and teratogenicity assessment using human organoid models.	Li M et al.	—	2022	→
Advances in Recapitulating Alzheimer's Disease Phenotypes Using Human Induced Pluripotent Stem Cell-Based In Vitro Models.	Hasan MF et al.	—	2022	→
Amyloid beta accumulations and enhanced neuronal differentiation in cerebral organoids of Dutch-type cerebral amyloid angiopathy patients.	Daoutsali E et al.	—	2022	→
A next-generation iPSC-derived forebrain organoid model of tauopathy with tau fibrils by AAV-mediated gene transfer.	Shimada H et al.	—	2022	→
An insight into the iPSCs-derived two-dimensional culture and three-dimensional organoid models for neurodegenerative disorders.	Bhargava A et al.	—	2022	→
An in vitro workflow of neuron-laden agarose-laminin hydrogel for studying small molecule-induced amyloidogenic condition.	Namchaiw P et al.	—	2022	→
Brain and Retinal Organoids for Disease Modeling: The Importance of In Vitro Blood-Brain and Retinal Barriers Studies.	Martinelli I et al.	—	2022	→
Brain physiome: A concept bridging <i>in vitro</i> 3D brain models and <i>in silico</i> models for predicting drug toxicity in the brain.	Seo Y et al.	—	2022	→
Building in vitro models of the brain to understand the role of <i>APOE</i> in Alzheimer's disease.	Pinals RL et al.	—	2022	→
Cell models for Down syndrome-Alzheimer's disease research.	Wu Y et al.	—	2022	→
Cellular Reprogramming and Its Potential Application in Alzheimer's Disease.	Zhou C et al.	—	2022	→
Central nervous system organoids for modeling neurodegenerative diseases.	Hou PS et al.	—	2022	→
Culture Variabilities of Human iPSC-Derived Cerebral Organoids Are a Major Issue for the Modelling of Phenotypes Observed in Alzheimer's Disease.	Hernández D et al.	—	2022	→
Deepening the understanding of CNVs on chromosome 15q11-13 by using hiPSCs: An overview.	Giovenale AMG et al.	—	2022	→
Down-syndrome-induced senescence disrupts the nuclear architecture of neural progenitors.	Meharena HS et al.	—	2022	→
Dysfunction of vesicular storage in young-onset Parkinson's patient-derived dopaminergic neurons and organoids revealed by single cell electrochemical cytometry.	Zhu W et al.	—	2022	→
Early Signs of Molecular Defects in iPSC-Derived Neural Stems Cells from Patients with Familial Parkinson's Disease.	Akrioti E et al.	—	2022	→
Endosomal structure and APP biology are not altered in a preclinical mouse cellular model of Down syndrome.	Cannavo C et al.	—	2022	→
Endosomal trafficking and related genetic underpinnings as a hub in Alzheimer's disease.	Limone A et al.	—	2022	→
Functional genomics and the future of iPSCs in disease modeling.	Brooks IR et al.	—	2022	→
Generation of iPSC-Derived Brain Organoids for Drug Testing and Toxicological Evaluation.	Nguyen HN	—	2022	→
Harnessing cerebral organoids for Alzheimer's disease research.	Bubnys A et al.	—	2022	→
Human Brain Organoid: A Versatile Tool for Modeling Neurodegeneration Diseases and for Drug Screening.	Ma C et al.	—	2022	→
Human Brain Organoids-on-Chip: Advances, Challenges, and Perspectives for Preclinical Applications.	Castiglione H et al.	—	2022	→
Human cerebral organoids - a new tool for clinical neurology research.	Eichmüller OL et al.	—	2022	→
Human-Induced Pluripotent Stem Cell-Based Models for Studying Sex-Specific Differences in Neurodegenerative Diseases.	Kiris E	—	2022	→
Human iPSC-Derived Neural Models for Studying Alzheimer's Disease: from Neural Stem Cells to Cerebral Organoids.	Barak M et al.	—	2022	→
Human tau mutations in cerebral organoids induce a progressive dyshomeostasis of cholesterol.	Glasauer SMK et al.	—	2022	→
Induced pluripotent stem cell-based organ-on-a-chip as personalized drug screening tools: A focus on neurodegenerative disorders.	Fanizza F et al.	—	2022	→
Induced Pluripotent Stem Cells for Treatment of Alzheimer's and Parkinson's Diseases.	Yefroyev DA et al.	—	2022	→
In-vitro engineered human cerebral tissues mimic pathological circuit disturbances in 3D.	Saberi A et al.	—	2022	→
Lysosomal dysfunction in neurodegeneration: emerging concepts and methods.	Udayar V et al.	—	2022	→
Microfabricated disk technology: Rapid scale up in midbrain organoid generation.	Mohamed NV et al.	—	2022	→
Modeling and Targeting Neuroglial Interactions with Human Pluripotent Stem Cell Models.	Bigarreau J et al.	—	2022	→
Modeling neurodegenerative diseases with cerebral organoids and other three-dimensional culture systems: focus on Alzheimer's disease.	Venkataraman L et al.	—	2022	→
Modeling the Human Brain With <i>ex vivo</i> Slices and <i>in vitro</i> Organoids for Translational Neuroscience.	Nogueira GO et al.	—	2022	→
Modifier pathways in polyglutamine (PolyQ) diseases: from genetic screens to drug targets.	Costa MD et al.	—	2022	→
Motor neuron-derived induced pluripotent stem cells as a drug screening platform for amyotrophic lateral sclerosis.	Amorós MA et al.	—	2022	→
Neural Organoids, a Versatile Model for Neuroscience.	Lee JH et al.	—	2022	→
Organotypic and Microphysiological Human Tissue Models for Drug Discovery and Development-Current State-of-the-Art and Future Perspectives.	Youhanna S et al.	—	2022	→
Patient-derived three-dimensional cortical neurospheres to model Parkinson's disease.	Raja WK et al.	—	2022	→
Patient-Specific iPSCs-Based Models of Neurodegenerative Diseases: Focus on Aberrant Calcium Signaling.	Grekhnev DA et al.	—	2022	→
Presenilin mutations and their impact on neuronal differentiation in Alzheimer's disease.	Hernandez-Sapiens MA et al.	—	2022	→
Present Application and Perspectives of Organoid Imaging Technology.	Fei K et al.	—	2022	→
Promising Strategies for the Development of Advanced In Vitro Models with High Predictive Power in Ischaemic Stroke Research.	Van Breedam E et al.	—	2022	→
Protective Effect of Human-Neural-Crest-Derived Nasal Turbinate Stem Cells against Amyloid-β Neurotoxicity through Inhibition of Osteopontin in a Human Cerebral Organoid Model of Alzheimer's Disease.	Lim JY et al.	—	2022	→
Redox modulation of stress resilience by Crocus sativus L. for potential neuroprotective and anti-neuroinflammatory applications in brain disorders: From molecular basis to therapy.	Scuto M et al.	—	2022	→
Region Specific Brain Organoids to Study Neurodevelopmental Disorders.	Susaimanickam PJ et al.	—	2022	→
Single cell transcriptomic profiling of a neuron-astrocyte assembloid tauopathy model.	Rickner HD et al.	—	2022	→
Surface functionalization of poly(dimethylsiloxane) substrates facilitates culture of pre-implantation mouse embryos by blocking non-selective adsorption.	Hawkins J et al.	—	2022	→
Synthetic scaffolds for 3D cell cultures and organoids: applications in regenerative medicine.	Marchini A et al.	—	2022	→
Towards a Mechanistic Model of Tau-Mediated Pathology in Tauopathies: What Can We Learn from Cell-Based In Vitro Assays?	Sala-Jarque J et al.	—	2022	→
3D-printed microplate inserts for long term high-resolution imaging of live brain organoids.	Oksdath Mansilla M et al.	—	2021	→
5-hydroxymethylcytosine is dynamically regulated during forebrain organoid development and aberrantly altered in Alzheimer's disease.	Kuehner JN et al.	—	2021	→
Advances in Central Nervous System Organoids: A Focus on Organoid-Based Models for Motor Neuron Disease.	Vieira de Sá R et al.	—	2021	→
Advances in development and application of human organoids.	Shankaran A et al.	—	2021	→
A human forebrain organoid model of fragile X syndrome exhibits altered neurogenesis and highlights new treatment strategies.	Kang Y et al.	—	2021	→
A logical network-based drug-screening platform for Alzheimer's disease representing pathological features of human brain organoids.	Park JC et al.	—	2021	→
Alzheimer's Disease: Current Perspectives and Advances in Physiological Modeling.	Josephine Boder E et al.	—	2021	→
Application of Induced Pluripotent Stem Cells for Disease Modeling and 3D Model Construction: Focus on Osteoarthritis.	Hwang JJ et al.	—	2021	→
Biologia Futura: the importance of 3D organoids-a new approach for research on neurological and rare diseases.	Akbaba TH et al.	—	2021	→
Biology and Models of the Blood-Brain Barrier.	Hajal C et al.	—	2021	→
Brain organoid: a 3D technology for investigating cellular composition and interactions in human neurological development and disease models in vitro.	Agboola OS et al.	—	2021	→
Brain organoid formation on decellularized porcine brain ECM hydrogels.	Simsa R et al.	—	2021	→
Brain organoids: an ensemble of bioassays to investigate human neurodevelopment and disease.	Sidhaye J et al.	—	2021	→
Brain Organoids: Filling the Need for a Human Model of Neurological Disorder.	Jalink P et al.	—	2021	→
Brain Organoids: Studying Human Brain Development and Diseases in a Dish.	Xu J et al.	—	2021	→
Brain Organoids: Tiny Mirrors of Human Neurodevelopment and Neurological Disorders.	Yadav A et al.	—	2021	→
Building the brain from scratch: Engineering region-specific brain organoids from human stem cells to study neural development and disease.	Jacob F et al.	—	2021	→
Current Status and Challenges of Stem Cell Treatment for Alzheimer's Disease.	Pacheco-Herrero M et al.	—	2021	→
Deconstructing Alzheimer's Disease: How to Bridge the Gap between Experimental Models and the Human Pathology?	Vignon A et al.	—	2021	→
Differentiation of Human Pluripotent Stem Cells Into Specific Neural Lineages.	Chang CY et al.	—	2021	→
Dissecting Alzheimer's disease pathogenesis in human 2D and 3D models.	Cenini G et al.	—	2021	→
Emerging Brain-Pathophysiology-Mimetic Platforms for Studying Neurodegenerative Diseases: Brain Organoids and Brains-on-a-Chip.	Bang S et al.	—	2021	→
Emerging genetic complexity and rare genetic variants in neurodegenerative brain diseases.	Perrone F et al.	—	2021	→
Engineering organoids.	Hofer M et al.	—	2021	→
From Brain Organoids to Networking Assembloids: Implications for Neuroendocrinology and Stress Medicine.	Makrygianni EA et al.	—	2021	→
Halofuginone Sensitizes Lung Cancer Organoids to Cisplatin <i>via</i> Suppressing PI3K/AKT and MAPK Signaling Pathways.	Li H et al.	—	2021	→
Human iPSC-Based Modeling of Central Nerve System Disorders for Drug Discovery.	Qian L et al.	—	2021	→
Human mini-brain models.	Tan HY et al.	—	2021	→
Hypothesis and Theory: Characterizing Abnormalities of Energy Metabolism Using a Cellular Platform as a Personalized Medicine Approach for Alzheimer's Disease.	Ryu WI et al.	—	2021	→
Increased maturation of iPSC-derived neurons in a hydrogel-based 3D culture.	de Leeuw SM et al.	—	2021	→
Klotho inhibits neuronal senescence in human brain organoids.	Shaker MR et al.	—	2021	→
Mass spectrometry analysis of tau and amyloid-beta in iPSC-derived models of Alzheimer's disease and dementia.	Arber C et al.	—	2021	→
Modeling Neurological Disorders in 3D Organoids Using Human-Derived Pluripotent Stem Cells.	Bose R et al.	—	2021	→
Modeling neurological disorders using brain organoids.	Zhang DY et al.	—	2021	→
Modeling SARS-CoV-2 infection in individuals with opioid use disorder with brain organoids.	Willner MJ et al.	—	2021	→
Modeling Sporadic Alzheimer's Disease in Human Brain Organoids under Serum Exposure.	Chen X et al.	—	2021	→
Modeling Traumatic Brain Injury in Human Cerebral Organoids.	Ramirez S et al.	—	2021	→
Modelling neurodegenerative disease using brain organoids.	Wray S	—	2021	→
NEUBOrg: Artificially Induced Pluripotent Stem Cell-Derived Brain Organoid to Model and Study Genetics of Alzheimer's Disease Progression.	Esmail S et al.	—	2021	→
Novel Approaches Used to Examine and Control Neurogenesis in Parkinson's Disease.	Salmina AB et al.	—	2021	→
Optimization of cerebral organoids: a more qualified model for Alzheimer's disease research.	Bi FC et al.	—	2021	→
Organoid Model in Idiopathic Pulmonary Fibrosis.	Lee J et al.	—	2021	→
Organoids: a novel modality in disease modeling.	Heydari Z et al.	—	2021	→
Recent Trends and Perspectives in Cerebral Organoids Imaging and Analysis.	Brémond Martin C et al.	—	2021	→
Stem cell-derived three-dimensional (organoid) models of Alzheimer's disease: a precision medicine approach.	Kim SJ et al.	—	2021	→
Telomerase Reverse Transcriptase Preserves Neuron Survival and Cognition in Alzheimer's Disease Models.	Shim HS et al.	—	2021	→
The Age of Brain Organoids: Tailoring Cell Identity and Functionality for Normal Brain Development and Disease Modeling.	Porciúncula LO et al.	—	2021	→
The application of in vitro-derived human neurons in neurodegenerative disease modeling.	D'Souza GX et al.	—	2021	→
The cellular machinery of post-endocytic APP trafficking in Alzheimer's disease: A future target for therapeutic intervention?	Goldstein LSB et al.	—	2021	→
The complexity of Alzheimer's disease: an evolving puzzle.	Ferrari C et al.	—	2021	→
The Potential of Induced Pluripotent Stem Cells to Treat and Model Alzheimer's Disease.	Schulz JM	—	2021	→
The Use of Stem Cell-Derived Organoids in Disease Modeling: An Update.	Azar J et al.	—	2021	→
Towards Advanced iPSC-based Drug Development for Neurodegenerative Disease.	Pasteuning-Vuhman S et al.	—	2021	→
Toward Studying Cognition in a Dish.	Rouleau N et al.	—	2021	→
Utilising Induced Pluripotent Stem Cells in Neurodegenerative Disease Research: Focus on Glia.	Albert K et al.	—	2021	→
A brief history of organoids.	Corrò C et al.	—	2020	→
A microfiber scaffold-based 3D in vitro human neuronal culture model of Alzheimer's disease.	Ranjan VD et al.	—	2020	→
APOE4 exacerbates synapse loss and neurodegeneration in Alzheimer's disease patient iPSC-derived cerebral organoids.	Zhao J et al.	—	2020	→
A Primer on Human Brain Organoids for the Neurosurgeon.	Blue R et al.	—	2020	→
A Three-Dimensional Alzheimer's Disease Cell Culture Model Using iPSC-Derived Neurons Carrying A246E Mutation in PSEN1.	Hernández-Sapiéns MA et al.	—	2020	→
CNS organoids: an innovative tool for neurological disease modeling and drug neurotoxicity screening.	Chhibber T et al.	—	2020	→
Depletion of the AD Risk Gene SORL1 Selectively Impairs Neuronal Endosomal Traffic Independent of Amyloidogenic APP Processing.	Knupp A et al.	—	2020	→
Electrophysiological Analysis of Brain Organoids: Current Approaches and Advancements.	Passaro AP et al.	—	2020	→
Engineering Human Brain Organoids: From Basic Research to Tissue Regeneration.	Jeong HJ et al.	—	2020	→
Exposure to phthalates impaired neurodevelopment through estrogenic effects and induced DNA damage in neurons.	Xu S et al.	—	2020	→
Familial Alzheimer's disease patient-derived neurons reveal distinct mutation-specific effects on amyloid beta.	Arber C et al.	—	2020	→
Focusing on cellular biomarkers: The endo-lysosomal pathway in Down syndrome.	Botté A et al.	—	2020	→
From cell lines to pluripotent stem cells for modelling Parkinson's Disease.	Ferrari E et al.	—	2020	→
From in vitro to in vivo reprogramming for neural transdifferentiation: An approach for CNS tissue remodeling using stem cell technology.	Egawa N et al.	—	2020	→
Harnessing the Potential of Stem Cells for Disease Modeling: Progress and Promises.	Argentati C et al.	—	2020	→
Human iNSC-derived brain organoid model of lysosomal storage disorder in Niemann-Pick disease type C.	Lee SE et al.	—	2020	→
Human iPSC-Derived Blood-Brain Barrier Models: Valuable Tools for Preclinical Drug Discovery and Development?	Appelt-Menzel A et al.	—	2020	→
Human iPSC-derived microglia: A growing toolset to study the brain's innate immune cells.	Hasselmann J et al.	—	2020	→
Human organoids to model the developing human neocortex in health and disease.	Khakipoor S et al.	—	2020	→
Human pluripotent stem cell-derived models and drug screening in CNS precision medicine.	Silva MC et al.	—	2020	→
Human Pluripotent Stem Cell-Derived Neural Cells as a Relevant Platform for Drug Screening in Alzheimer's Disease.	Garcia-Leon JA et al.	—	2020	→
Human Pluripotent Stem Cells in Neurodegenerative Diseases: Potentials, Advances and Limitations.	Kolagar TA et al.	—	2020	→
If Human Brain Organoids Are the Answer to Understanding Dementia, What Are the Questions?	Ooi L et al.	—	2020	→
<i>In vitro</i> Models of Neurodegenerative Diseases.	Slanzi A et al.	—	2020	→
Induced Pluripotent Stem Cell (iPSC)-Based Neurodegenerative Disease Models for Phenotype Recapitulation and Drug Screening.	Chang CY et al.	—	2020	→
Innovations in 3-Dimensional Tissue Models of Human Brain Physiology and Diseases.	Lovett ML et al.	—	2020	→
Innovative Therapies and Nanomedicine Applications for the Treatment of Alzheimer's Disease: A State-of-the-Art (2017-2020).	Binda A et al.	—	2020	→
Long Term Gene Expression in Human Induced Pluripotent Stem Cells and Cerebral Organoids to Model a Neurodegenerative Disease.	Nassor F et al.	—	2020	→
Midbrain Organoids: A New Tool to Investigate Parkinson's Disease.	Smits LM et al.	—	2020	→
Modeling Alzheimer's disease with iPSC-derived brain cells.	Penney J et al.	—	2020	→
Modeling and Targeting Alzheimer's Disease With Organoids.	Papaspyropoulos A et al.	—	2020	→
Modeling Down syndrome in cells: From stem cells to organoids.	Gough G et al.	—	2020	→
Modeling Emergent Properties in the Brain Using Tissue Models to Investigate Neurodegenerative Disease.	Harris AR et al.	—	2020	→
Modelling frontotemporal dementia using patient-derived induced pluripotent stem cells.	Lines G et al.	—	2020	→
Modelling neurodegenerative diseases with 3D brain organoids.	Chang Y et al.	—	2020	→
Neurodegeneration in a dish: advancing human stem-cell-based models of Alzheimer's disease.	Klimmt J et al.	—	2020	→
Patient-Derived Midbrain Organoids to Explore the Molecular Basis of Parkinson's Disease.	Galet B et al.	—	2020	→
Recent Overview of the Use of iPSCs Huntington's Disease Modeling and Therapy.	Csobonyeiova M et al.	—	2020	→
Recent progress in translational engineered in vitro models of the central nervous system.	Nikolakopoulou P et al.	—	2020	→
Retinal and Brain Organoids: Bridging the Gap Between <i>in vivo</i> Physiology and <i>in vitro</i> Micro-Physiology for the Study of Alzheimer's Diseases.	Brighi C et al.	—	2020	→
Review of functional in vitro models of the blood-cerebrospinal fluid barrier in leukaemia research.	Erb U et al.	—	2020	→
Simplified Brain Organoids for Rapid and Robust Modeling of Brain Disease.	Ha J et al.	—	2020	→
Stem cell therapy for Alzheimer's disease.	Liu XY et al.	—	2020	→
Studying Human Neurodevelopment and Diseases Using 3D Brain Organoids.	Tian A et al.	—	2020	→
Tau and other proteins found in Alzheimer's disease spinal fluid are linked to retromer-mediated endosomal traffic in mice and humans.	Simoes S et al.	—	2020	→
The Application of Brain Organoids: From Neuronal Development to Neurological Diseases.	Shou Y et al.	—	2020	→
The iNs and Outs of Direct Reprogramming to Induced Neurons.	Carter JL et al.	—	2020	→
Three-dimensional modeling of human neurodegeneration: brain organoids coming of age.	Grenier K et al.	—	2020	→
Translating insights from neuropsychiatric genetics and genomics for precision psychiatry.	Rees E et al.	—	2020	→
Using brain organoids to study human neurodevelopment, evolution and disease.	Kyrousi C et al.	—	2020	→
Using induced pluripotent stem cell neuronal models to study neurodegenerative diseases.	Zhang X et al.	—	2020	→
A Human Embryonic Stem Cell Model of Aβ-Dependent Chronic Progressive Neurodegeneration.	Ubina T et al.	—	2019	→
A Large Panel of Isogenic APP and PSEN1 Mutant Human iPSC Neurons Reveals Shared Endosomal Abnormalities Mediated by APP β-CTFs, Not Aβ.	Kwart D et al.	—	2019	→
All Together Now: Modeling the Interaction of Neural With Non-neural Systems Using Organoid Models.	Chukwurah E et al.	—	2019	→
Alzheimer's in a dish - induced pluripotent stem cell-based disease modeling.	de Leeuw S et al.	—	2019	→
Analysis of Synapses in Cerebral Organoids.	Yakoub AM et al.	—	2019	→
Assessing drug response in engineered brain microenvironments.	Tate KM et al.	—	2019	→
Assessing the therapeutic potential of Graptopetalum paraguayense on Alzheimer's disease using patient iPSC-derived neurons.	Wu PC et al.	—	2019	→
Biomaterials and Advanced Biofabrication Techniques in hiPSCs Based Neuromyopathic Disease Modeling.	Sun J et al.	—	2019	→
Brain organoids: advances, applications and challenges.	Qian X et al.	—	2019	→
Brain Organoids: A New, Transformative Investigational Tool for Neuroscience Research.	Vaez Ghaemi R et al.	—	2019	→
Brain organoids: a next step for humanized Alzheimer's disease models?	Gerakis Y et al.	—	2019	→
Engineering tissue-specific blood vessels.	Herron LA et al.	—	2019	→
Human Cerebral Organoids and Fetal Brain Tissue Share Proteomic Similarities.	Nascimento JM et al.	—	2019	→
Human iPSC application in Alzheimer's disease and Tau-related neurodegenerative diseases.	Tcw J	—	2019	→
Induced Pluripotent Stem Cell-Derived Astroglia: A New Tool for Research Towards the Treatment of Alzheimer's Disease.	Atkinson-Dell R et al.	—	2019	→
Induced pluripotent stem cells for neural drug discovery.	Farkhondeh A et al.	—	2019	→
iPSCs-Based Neural 3D Systems: A Multidimensional Approach for Disease Modeling and Drug Discovery.	Costamagna G et al.	—	2019	→
Modeling Alzheimer's disease with human iPS cells: advancements, lessons, and applications.	Essayan-Perez S et al.	—	2019	→
Modeling G2019S-LRRK2 Sporadic Parkinson's Disease in 3D Midbrain Organoids.	Kim H et al.	—	2019	→
Modelling mitochondrial dysfunction in Alzheimer's disease using human induced pluripotent stem cells.	Hawkins KE et al.	—	2019	→
Neural Lineage Differentiation From Pluripotent Stem Cells to Mimic Human Brain Tissues.	Hong YJ et al.	—	2019	→
One Step Into the Future: New iPSC Tools to Advance Research in Parkinson's Disease and Neurological Disorders.	Mohamed NV et al.	—	2019	→
Opportunities and challenges for the use of induced pluripotent stem cells in modelling neurodegenerative disease.	Wu YY et al.	—	2019	→
Optogenetics in the Era of Cerebral Organoids.	Shiri Z et al.	—	2019	→
Organs to Cells and Cells to Organoids: The Evolution of <i>in vitro</i> Central Nervous System Modelling.	Pacitti D et al.	—	2019	→
Past, Present, and Future of Brain Organoid Technology.	Koo B et al.	—	2019	→
Stem Cell-Derived Neurons as Cellular Models of Sporadic Alzheimer's Disease.	Foveau B et al.	—	2019	→
Studying Human Neurological Disorders Using Induced Pluripotent Stem Cells: From 2D Monolayer to 3D Organoid and Blood Brain Barrier Models.	Logan S et al.	—	2019	→
Targeting the ensemble of heterogeneous tau oligomers in cells: A novel small molecule screening platform for tauopathies.	Lo CH et al.	—	2019	→
The complexity of tau in Alzheimer's disease.	Naseri NN et al.	—	2019	→
The Use of Pluripotent Stem Cell-Derived Organoids to Study Extracellular Matrix Development during Neural Degeneration.	Yan Y et al.	—	2019	→
Use of human pluripotent stem cell-derived cells for neurodegenerative disease modeling and drug screening platform.	Garcia-Leon JA et al.	—	2019	→
2D versus 3D human induced pluripotent stem cell-derived cultures for neurodegenerative disease modelling.	Centeno EGZ et al.	—	2018	→
3D human brain cell models: New frontiers in disease understanding and drug discovery for neurodegenerative diseases.	Korhonen P et al.	—	2018	→
APOE4 Causes Widespread Molecular and Cellular Alterations Associated with Alzheimer's Disease Phenotypes in Human iPSC-Derived Brain Cell Types.	Lin YT et al.	—	2018	→
Brain Organoids: Expanding Our Understanding of Human Development and Disease.	Chuye LB et al.	—	2018	→
Cerebral organoids derived from Sandhoff disease-induced pluripotent stem cells exhibit impaired neurodifferentiation.	Allende ML et al.	—	2018	→
Combining Optical Approaches with Human Inducible Pluripotent Stem Cells in G Protein-Coupled Receptor Drug Screening and Development.	Bourque K et al.	—	2018	→
Common proteomic profiles of induced pluripotent stem cell-derived three-dimensional neurons and brain tissue from Alzheimer patients.	Chen M et al.	—	2018	→
Disease Modeling Using 3D Organoids Derived from Human Induced Pluripotent Stem Cells.	Ho BX et al.	—	2018	→
From Neuronal Differentiation of iPSCs to 3D Neuro-Organoids: Modelling and Therapy of Neurodegenerative Diseases.	Bordoni M et al.	—	2018	→
Genetics of Alcohol Use Disorder: A Role for Induced Pluripotent Stem Cells?	Prytkova I et al.	—	2018	→
Genome engineering for CNS injury and disease.	Pardieck J et al.	—	2018	→
Genomics: New Light on Alzheimer's Disease Research.	Jung YJ et al.	—	2018	→
Human fibroblast and stem cell resource from the Dominantly Inherited Alzheimer Network.	Karch CM et al.	—	2018	→
Human Neurospheroid Arrays for In Vitro Studies of Alzheimer's Disease.	Jorfi M et al.	—	2018	→
Human stem cell modeling in neurofibromatosis type 1 (NF1).	Wegscheid ML et al.	—	2018	→
Induced Pluripotent Stem Cells: A Powerful Neurodegenerative Disease Modeling Tool for Mechanism Study and Drug Discovery.	Chang CY et al.	—	2018	→
Induced pluripotent stem cells (iPSCs) as model to study inherited defects of neurotransmission in inborn errors of metabolism.	Jung-Klawitter S et al.	—	2018	→
Materials for Neural Differentiation, Trans-Differentiation, and Modeling of Neurological Disease.	Gong L et al.	—	2018	→
Modeling amyloid beta and tau pathology in human cerebral organoids.	Gonzalez C et al.	—	2018	→
Modeling Neurodegenerative Microenvironment Using Cortical Organoids Derived from Human Stem Cells.	Yan Y et al.	—	2018	→
Modeling Neurological Diseases With Human Brain Organoids.	Wang H	—	2018	→
Modelling Alzheimer's disease: Insights from in vivo to in vitro three-dimensional culture platforms.	Ranjan VD et al.	—	2018	→
Modelling Sporadic Alzheimer's Disease Using Induced Pluripotent Stem Cells.	Rowland HA et al.	—	2018	→
Neural Stem Cell Dysfunction in Human Brain Disorders.	Liszewska E et al.	—	2018	→
Neuroprotective Activities of Heparin, Heparinase III, and Hyaluronic Acid on the A<i>β</i>42-Treated Forebrain Spheroids Derived from Human Stem Cells.	Bejoy J et al.	—	2018	→
Opportunities for organoids as new models of aging.	Hu JL et al.	—	2018	→
Proteostasis in Huntington's disease: disease mechanisms and therapeutic opportunities.	Harding RJ et al.	—	2018	→
Recent Advances: Decoding Alzheimer's Disease With Stem Cells.	Fang Y et al.	—	2018	→
Representing Diversity in the Dish: Using Patient-Derived <i>in Vitro</i> Models to Recreate the Heterogeneity of Neurological Disease.	Ghaffari LT et al.	—	2018	→
Review: Synthetic scaffolds to control the biochemical, mechanical, and geometrical environment of stem cell-derived brain organoids.	Oksdath M et al.	—	2018	→
Small-molecule induction of Aβ-42 peptide production in human cerebral organoids to model Alzheimer's disease associated phenotypes.	Pavoni S et al.	—	2018	→
Stabilizing the Retromer Complex in a Human Stem Cell Model of Alzheimer's Disease Reduces TAU Phosphorylation Independently of Amyloid Precursor Protein.	Young JE et al.	—	2018	→
Stem Cells, Genome Editing, and the Path to Translational Medicine.	Soldner F et al.	—	2018	→
Studying the Brain in a Dish: 3D Cell Culture Models of Human Brain Development and Disease.	Brown J et al.	—	2018	→
Synaptic dysfunction in neurodegenerative and neurodevelopmental diseases: an overview of induced pluripotent stem-cell-based disease models.	Taoufik E et al.	—	2018	→
The interplay of peptide affinity and scaffold stiffness on neuronal differentiation of neural stem cells.	Stukel JM et al.	—	2018	→
Translational potential of human brain organoids.	Sun AX et al.	—	2018	→
3D brain Organoids derived from pluripotent stem cells: promising experimental models for brain development and neurodegenerative disorders.	Lee CT et al.	—	2017	→
Alzheimer's disease: experimental models and reality.	Drummond E et al.	—	2017	→
Bioengineered 3D Glial Cell Culture Systems and Applications for Neurodegeneration and Neuroinflammation.	Watson PMD et al.	—	2017	→
Deciphering Cell Intrinsic Properties: A Key Issue for Robust Organoid Production.	Picollet-D'hahan N et al.	—	2017	→
Drug discovery for remyelination and treatment of MS.	Cole KLH et al.	—	2017	→
Endosomal Traffic Jams Represent a Pathogenic Hub and Therapeutic Target in Alzheimer's Disease.	Small SA et al.	—	2017	→
Generating CNS organoids from human induced pluripotent stem cells for modeling neurological disorders.	Brawner AT et al.	—	2017	→
Inhibition of p25/Cdk5 Attenuates Tauopathy in Mouse and iPSC Models of Frontotemporal Dementia.	Seo J et al.	—	2017	→
Minibrain Storm : Cerebral Organoids Aren't Real Brains?But They Provide a Powerful Platform for Modeling Brain Diseases Like Zika Infection, Alzheimer's, and Even Autism.	Fischer S	—	2017	→
Modeling neurodegenerative diseases with patient-derived induced pluripotent cells: Possibilities and challenges.	Poon A et al.	—	2017	→
Modeling tau pathology in human stem cell derived neurons.	Wray S	—	2017	→
Modelling APOE ɛ3/4 allele-associated sporadic Alzheimer's disease in an induced neuron.	Kim H et al.	—	2017	→
Stem cell models of Alzheimer's disease: progress and challenges.	Arber C et al.	—	2017	→
The use of brain organoids to investigate neural development and disease.	Di Lullo E et al.	—	2017	→
3D culture models of Alzheimer's disease: a road map to a "cure-in-a-dish".	Choi SH et al.	—	2016	→