Differential responses to lithium in hyperexcitable neurons from patients with bipolar disorder.

paper Cited Public

Authors: Mertens, Jerome; Wang, Qiu-Wen; Kim, Yongsung; Yu, Diana X; Pham, Son; Yang, Bo; Zheng, Yi; Diffenderfer, Kenneth E; Zhang, Jian; Soltani, Sheila; Eames, Tameji; Schafer, Simon T; Boyer, Leah; Marchetto, Maria C; Nurnberger, John I; Calabrese, Joseph R; Ødegaard, Ketil J; McCarthy, Michael J; Zandi, Peter P; Alda, Martin; Nievergelt, Caroline M; Pharmacogenomics of Bipolar Disorder Study; Mi, Shuangli; Brennand, Kristen J; Kelsoe, John R; Gage, Fred H; Yao, Jun
Year: 2015
Journal: Nature
PMID: 26524527
DOI: 10.1038/nature15526
PMCID: PMC4742055

Bipolar disorder is a complex neuropsychiatric disorder that is characterized by intermittent episodes of mania and depression; without treatment, 15% of patients commit suicide. Hence, it has been ranked by the World Health Organization as a top disorder of morbidity and lost productivity. Previous neuropathological studies have revealed a series of alterations in the brains of patients with bipolar disorder or animal models, such as reduced glial cell number in the prefrontal cortex of patients, upregulated activities of the protein kinase A and C pathways and changes in neurotransmission. However, the roles and causation of these changes in bipolar disorder have been too complex to exactly determine the pathology of the disease. Furthermore, although some patients show remarkable improvement with lithium treatment for yet unknown reasons, others are refractory to lithium treatment. Therefore, developing an accurate and powerful biological model for bipolar disorder has been a challenge. The introduction of induced pluripotent stem-cell (iPSC) technology has provided a new approach. Here we have developed an iPSC model for human bipolar disorder and investigated the cellular phenotypes of hippocampal dentate gyrus-like neurons derived from iPSCs of patients with bipolar disorder. Guided by RNA sequencing expression profiling, we have detected mitochondrial abnormalities in young neurons from patients with bipolar disorder by using mitochondrial assays; in addition, using both patch-clamp recording and somatic Ca(2+) imaging, we have observed hyperactive action-potential firing. This hyperexcitability phenotype of young neurons in bipolar disorder was selectively reversed by lithium treatment only in neurons derived from patients who also responded to lithium treatment. Therefore, hyperexcitability is one early endophenotype of bipolar disorder, and our model of iPSCs in this disease might be useful in developing new therapies and drugs aimed at its clinical treatment.

Figure 1

Hippocampal DG granule cell-like neurons derived from patients with BD show gene expression and mitochondrial abnormalitiesa, Schematic: generation of DG-like neurons from BD iPSCs.b, Immunostainings of iPSCs for TRA-1–60 and Nanog, neural rosettes and neural progenitor cells for SOX2 and Nestin, and neurons for MAP2 and TUJ1. c, Immunostainings of neurons labelled with VGLUT1, MAP2, Prox1::eGFP and GABA. Scale bars, 50 μm for b and c. d, Quantification of VGLUT1-positive glutamatergic neurons (normal, n = 8; BD, n = 12 lines), Prox1::eGFP-positive DG-like neurons (normal, n = 8; BD, n = 12 lines) and GABAergic neurons (normal, n = 4; BD, n = 12 lines). e, Immunostaining of dendritic glutamatergic synapses and axonal GABAergic synapses. Scale bar, 5μm. f, Quantification of glutamatergic and GABAergic synapse densities (VGLUT1: normal, n = 30 neurons from 8 lines; BD, n = 78 from 12 lines. GABA: normal, n = 30 from 6 lines; BD, n = 88 from 12 lines).g, Heat map of differential gene expression in normal and BD neurons.h, Bar graph summarizing differential expression of mitochondrial genes in BD and normal neurons. i, Schematic rationale of JC-1. j, JC-1 flow cytometry graphs showing that, as a control, CCCP diminishes neuronal MMP and that BD neurons have elevated MMP. k, Quantification of elevated MMP in BD neurons compared with normal (normal, n = 8 lines from 4 subjects; BD, n = 12 lines from 6 subjects). l, m, Neurons expressing DsRed2-mito and Prox1::eGFP. Scale bars, 50 μm (l) and 20 μm (m).n, DsRed2-mito puncta sizes reduced in BD neurons. Identical symbols indicate same subject (normal, n = 29 cells from 8 lines; BD, n = 39 from 12 lines). Student’s t-test, *P < 0.05; **P < 0.001. Bars, mean ± s.e.m.

Extended Data Figure 6

AP firing in the BD NR neurons treated with lamotrigine (LTG)a, Representative traces of APs evoked during 300 ms stepwise depolarization periods in the normal and NR neurons with and without 100 μm lamotrigine treatment. b, c, Bar graphs summarizing the effects of lamotrigine on the total number (b) and maximal amplitude (c) of evoked APs in the normal and BD NR neurons (normal: without lamotrigine, n = 7 neurons; with lamotrigine, n = 8. BD NR: without lamotrigine, n = 5; with lamotrigine, n =6). Student’s t-test, *P <0.05; **P <0.001. Bars, mean ±s.e.m.

Extended Data Figure 7

Effect of Li on the normal neuronsa, Representative traces of Na+/K+ currents in the normal neurons treated with Li at different concentrations. b, Representative traces of APs evoked during 300 ms stepwise depolarization periods in the normal neurons treated with Li at different concentrations. c, d, Bar graphs summarizing the effects of different concentrations of Li on the total number (c) and maximal amplitude (d) of evoked APs in the normal neurons (n = 4 neurons). Student’s t-test. *P < 0.05. Bars, mean ±s.e.m.

Extended Data Figure 8

Reversal of hyperexcitability in old BD neuronsa, b, Sample traces (a) and scatter graph (b) showing that the 8-week-old BD neurons exhibited weaker Na+ currents than the normal neurons (normal, n = 28 neurons from 4 lines; BD, n = 37 from 6 lines). c, d, Sample traces (c) and scatter graph (d) showing that the 8-week-old BD neurons exhibited a lower frequency of Ca2+ transient events than the normal neurons (n =30 videos from 10 patients). e, Scatter graphs showing the MMP of 6- and 8-week-old BD and normal neurons (normal, n = 3 lines; BD, n =3 lines). Student’s t-test, *P <0.05; **P < 0.001. Bars, mean ±s.e.m.

Extended Data Figure 9

The Prox1::eGFP-positive BD cells have similar expression of differentially expressed genes to the whole differentiation culturea, Sorting of cells strongly expressing Prox1::eGFP using flow cytometry. b, Bar graph showing that Prox1::eGFP expression is enriched in the selected cells. c, Enrichment of differentially expressed genes in the Prox1 + DG-like neurons (c) and non-DG cells (d) (n = 6 patients). Bars, mean ± s.e.m.

Extended Data Figure 10

Representative icons of the subjects in the figuresa, Representative icons of the patients with BD and healthy people used in the experiments shown in the figures. Identical symbols indicate the same subject.

Figure 2

Hippocampal neurons derived from patients with BD show hyperexcitabilitya, b, Average expression of representative genes involved in the PKA/PKC and AP firing systems revealed by RNA-seq (a) and qRT–PCR (b) analysis (normal, n = 4; BD, n = 6 lines). c–e, Patch-clamp recording on Prox1::eGFP-expressing DG-like neurons (c) showed spontaneous postsynaptic currents (d) and Na+/K+ currents (e). Scale bar, 20 μm. f, Average peak values of Na+ currents during stepwise depolarization (normal, n = 40 neurons from 8 lines; BD, n = 52 from 12 lines). g, Normalized average Na+ currents at different membrane potentials. h–k, Sample trace (h), average firing threshold (i), average total number (j) and maximal amplitude (k) of APs evoked during 300 ms stepwise depolarization. Identical symbols indicate same subject (for AP threshold: normal, n = 39 neurons from 8 lines; BD, n = 55 from 12 lines; for total AP number: normal, n = 39 from 8 lines; BD, n = 58 from 12 lines; for maximal amplitude: normal, n = 39 from 8 lines; BD, n = 57 from 12 lines). l–n, Sample trace (l), average frequency (m) and mean amplitude (n) of spontaneous APs (for AP frequency: normal, n = 29 neurons from 6 lines; BD, n = 30 from 8 lines). Student’s t-test, *P < 0.05; **P < 0.001. Bars, mean ± s.e.m.

Figure 3

Li rescues hyperexcitability in hippocampal neurons derived from iPSCs of patients with BDa, Na+/K+ currents recorded from BD LR and NR neurons with and without Li. b, c, Effects of Li on average peaks of Na+ currents (b) and K+ currents (c) in the LR and NR neurons. Identical symbols indicate same subject (LR without Li, n = 26 neurons from 5 lines; with Li, n = 19 from 5 lines). d, Representative traces of APs evoked during 300 ms stepwise depolarization periods. e, Scatter graph showing Li-induced decrease in the average total AP number of the LR neurons (LR without Li treatment, n = 27 neurons from 5 lines; with Li treatment, n = 18 from 5 lines). f, Representative traces of spontaneous APs. g, Spontaneous AP firing frequency in Li-treated LR neurons (LR without Li, n = 11 neurons from 3 lines; with Li, n = 10 from 3 lines). h, i, Heat maps (h) and MA plots (i) showing effects of Li treatment on gene expression in LR and NR neurons. j, k, Effects of Li on the average expression of representative PKA/PKC/AP (j) and mitochondrial genes (k) in the LR neurons (with Li, n = 3; without Li, n = 3 lines). l, m, Sample images of neurons (l) and bar graph (m) showing the effects of Li treatment on mitochondria morphology. Scale bar, 10 μm (n = 19 neurons from 6 lines). n, No effects of Li treatment on MMP of the BD neurons (n = 6 lines for each group). Student’s t-test, *P < 0.05; **P < 0.001. Bars, mean ± s.e.m.

Figure 4

Somatic Ca2+ imaging analysis reveals hyperactivity in the neural network formed by the BD iPSC-derived neuronsa, b, Sample traces (a) and bar graph (b) showing neuronal Ca2+ transients abolished by tetrodotoxin (n =10 images). c, Representative Ca2+ traces in normal, BD LR and NR neurons. d, Effects of Li treatment on the average ratio of neurons exhibiting Ca2+ events. Identical symbols indicate the same subject (n = 23 images from 6 lines). e, Scatter graph (left) and analysis of variance (ANOVA) (right) showing the average Ca2+ event frequencies in normal and BD neurons treated with Li (normal, n = 43 images from 8 lines; LR, n =23 from 6 lines; NR, n = 23 from 6 lines). Student’s t-test (b) and ANOVA (d, e), *P <0.05; **P < 0.001. Bars, mean ±s.e.m.

Extended Data Figure 1

Generation of iPSCs from patients with BD and healthy peoplea, Human fibroblasts generated from punch biopsy. b, The iPSC colonies appeared after fibroblasts were reprogrammed using the Sendai virus. c, Purified iPSC colonies were cultured in Matrigel-coated plate. d, Immunostaining of iPSCs with DAPI and pluripotency markers Nanog and TRA-1-60. e, RT–PCR results showing that the introduced Sendai virus genes were cleared from the generated iPSCs. f, RT–PCR results showing that the generated iPSCs expressed human pluripotency markers NANOG, LIN28, OCT4, TDGF and cMYC. g, Representative karyotyping image of generated iPSCs showing normal chromosomal structure. h–j, Bar graphs of quantitative RT–PCR showing that the iPSCs can randomly differentiate into cells expressing the markers for endoderm, mesoderm and ectoderm. Data are representative for a total of 20 iPS cell lines from 10 patients (2 clones per patient). Scale bar, 50 μm. Bars, mean ±s.e.m.

Extended Data Figure 2

Lentiviral transduction of Prox1::eGFP efficiently labels Prox1-positive DG granule cell-like neuronsa, Sample immunostaining images showing the expression of Prox1 and Prox1::eGFP in the normal and BD neurons. Scale bar, 100 μm. b, Bar graph showing that, both in the normal and in BD groups, more than 90% of Prox1::eGFP-positive neurons express nuclear Prox1 protein. Normal, 92.1 ±2.4%, n = 4 lines; BD, 93.3 ±1.2%, n =12 lines. c, Bar graph showing that, both in the normal and in BD groups, approximately 90% of Prox1-positive DG-like neurons express Prox1::eGFP. Bars, mean ±s.e.m.

Extended Data Figure 3

Bar graphs summarizing the similarity between different cell lines of the same subject and comparison of low and high passage cellsa, b, Bar graph comparing the MMP (n = 20 lines) (a) and mitochondria size (n = 68 images from 20 lines) (b) of different cell lines of one subject. c–f, Electrophysiological recording experiments, including peak Na+ currents (n = 92 neurons from 20 lines) (c), AP threshold (94 neurons from 20 lines) (d), total evoked AP number (n = 97 neurons from 20 lines) (e) and maximal AP amplitude (n = 96 neurons from 20 lines) (f). g, Bar graph comparing the frequency of Ca2+ transient events. Black bar, cell line/clone 1; grey bar, cell line/clone 2 (178 videos from 20 lines). h, Bar graph showing the normalized peak Na+ current in normal (NM) and BD neurons derived from <P5 and >P9 cell lines (P5: normal, n = 40 neurons from 8 lines; BD, n = 52 from 12 lines. P9: normal, n = 11 from 2 lines; BD, n =23 from 5 lines). Student’s t-test, *P < 0.05. Bars, mean ±s.e.m.

Extended Data Figure 4

K+ currents in the BD neuronsa, Average peak values of K+ currents in the BD and normal neurons. b, Normalized average K+ currents at different membrane potentials (normal, n = 35 neurons from 7 lines; BD, n = 41 from 10 lines). Student’s t-test. Bars, mean ±s.e.m.

Extended Data Figure 5

Prox1:eGFP expression in the BD LR and NR neurons and AP amplitude and threshold of BD neuronsa, Sample immunostaining images showing the expression of Prox1::eGFP in the BD LR and NR neurons. Scale bar, 50 μm. b, Quantitative analysis revealed a similar percentage of Prox1::eGFP-positive DG-like neurons in the LR and NR groups (n = 32 images from 4 lines). c, d, Bar graphs showing the Li-induced effects in the maximal amplitude of evoked APs (LR without Li treatment, n = 27 neurons from 5 lines; with Li treatment, n = 18 from 5 lines) (c) and mean amplitude of spontaneous APs (LR without Li, n = 11 neurons from 3 lines; with Li, n = 10 from 3 lines) (d) of the LR neurons. e, Bar graph showing that the threshold of AP firing was not changed by Li (LR without Li, n = 11 neurons from 3 lines; with Li, n = 10 from 3 lines). Bars, mean ±s.e.m.

#	Section	Preview
0	METHODS — Subjects	Patients with type I BD were participants in one of two prospective clinical trials of Li…
1	METHODS — Subjects	Impressions Scale score of 3 or less, reflecting only mild symptoms, were declared responders,…
2	METHODS — iPSC reprogramming and neuron differentiation	BD and normal iPSCs were derived from fibroblasts using a Cyto-Tune Sendai reprogramming kit…
3	METHODS — iPSC reprogramming and neuron differentiation	(Invitrogen), 1 μg ml−1 laminin and 20 ng ml−1 FGF2 (Invitrogen)). To obtain mature neurons,…
4	METHODS — Generation of lentivirus	Lentivirus was packaged in 293T HEK cells grown in DMEM/F12 (Invitrogen) supplemented with 10% FBS…
5	METHODS — Immunocytochemistry	Cells were fixed in 4% paraformaldehyde and then permeabilized with 0.25% Triton-X100 in PBS. Cells…
6	METHODS — Immunocytochemistry	Cruz catalogue number sc-17320), mouse anti-Nestin monoclonal antibody (1:200, Chemicon catalogue…
7	METHODS — RNA extraction, PCR and quantitative RT–PCR	Total cellular RNA was extracted from approximately 5 ×106 cells using the RNA-BEE (Qiagen)…
8	METHODS — Somatic calcium imaging	Three-week-old neurons derived from BD and normal iPSCs were previously infected with a synapsin…
9	METHODS — Electrophysiology	Neurons were previously infected with the Prox1::eGFP lentiviral vector. Whole-cell patch-clamp…
10	METHODS — Mitochondrial assay and flow cytometry	To measure mitochondrial size, Prox1::eGFP and DsRed2-mito were co-expressed in DG-like neurons via…
11	METHODS — Mitochondrial assay and flow cytometry	For MMP, neurons were incubated with JC-1 dye (Molecular Probes) at 37 °C for 15–30 min29. The…
12	METHODS — RNA-seq analysis	RNA was prepared into RNA-Seq libraries using an Illumina TruSeq Stranded Total RNA Sample Prep Kit…
13	METHODS — RNA-seq analysis	described in the edgeR manual. DAVID (http://david.abcc.ncifcrf.gov/) was used to perform the gene…
14	METHODS — Statistical analysis	No statistical methods were used to predetermine sample size. The experiments were not randomized.
15	METHODS — Statistical analysis	For comparisons of Ca2+ imaging results among the normal, LR and NR groups, the difference was…
16	METHODS — Statistical analysis	performed paired comparisons to detect gene expression changes in response to Li treatment. This is…
17	METHODS — Statistical analysis	could not tell the identity of the subject but could tell which two lines belonged to the same…

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Exploring mood disorders and treatment options using human stem cells.	Hudock A et al.	—	2024	→
Exploring PDE5A upregulation in bipolar disorder: insights from single-nucleus RNA sequencing of human basal ganglia.	Bai Z et al.	—	2024	→
Focal adhesion is associated with lithium response in bipolar disorder: evidence from a network-based multi-omics analysis.	Niemsiri V et al.	—	2024	→
Granule cells perform frequency-dependent pattern separation in a computational model of the dentate gyrus.	Singh S et al.	—	2024	→
Human stem cell-based models to study synaptic dysfunction and cognition in schizophrenia: A narrative review.	Santarriaga S et al.	—	2024	→
IMPA1 dependent regulation of phosphatidylinositol 4,5-bisphosphate and calcium signalling by lithium.	Saha S et al.	—	2024	→
Impaired mitochondrial function in bipolar disorder and alcohol use disorder: a case study using <sup>18</sup>F-BCPP-EF PET imaging of mitochondrial Complex I.	Wigstrom TP et al.	—	2024	→
Impaired neural stress resistance and loss of REST in bipolar disorder.	Meyer K et al.	—	2024	→
Induced neural progenitor cells and iPS-neurons from major depressive disorder patients show altered bioenergetics and electrophysiological properties.	Triebelhorn J et al.	—	2024	→
Investigating light sensitivity in bipolar disorder (HELIOS-BD).	Roguski A et al.	—	2024	→
Large-scale animal model study uncovers altered brain pH and lactate levels as a transdiagnostic endophenotype of neuropsychiatric disorders involving cognitive impairment.	Hagihara H et al.	—	2024	→
Lithium: Fifteen Years Later.	Rybakowski JK	—	2024	→
Lithium response in bipolar disorder is associated with focal adhesion and PI3K-Akt networks: a multi-omics replication study.	Ou AH et al.	—	2024	→
Mitochondrial dysfunction in psychiatric disorders.	Ni P et al.	—	2024	→
Navigating the Neuroimmunomodulation Frontier: Pioneering Approaches and Promising Horizons-A Comprehensive Review.	Krsek A et al.	—	2024	→
New Advances in the Pharmacology and Toxicology of Lithium: A Neurobiologically Oriented Overview.	Bortolozzi A et al.	—	2024	→
Pharmacogenomics and response to lithium in bipolar disorder.	Paribello P et al.	—	2024	→
Phenotypic clustering of bipolar disorder supports stratification by lithium responsiveness over diagnostic subtypes.	Scott K et al.	—	2024	→
Physiological aging and inflammation-induced cellular senescence may contribute to oligodendroglial dysfunction in MS.	Windener F et al.	—	2024	→
Possible Role of Correlation Coefficients and Network Analysis of Multiple Intracellular Proteins in Blood Cells of Patients with Bipolar Disorder in Studying the Mechanism of Lithium Responsiveness: A Proof-Concept Study.	Gao K et al.	—	2024	→
Progress and trends of research on mineral elements for depression.	Gao B et al.	—	2024	→
Protocol for transplantation of cells derived from human midbrain organoids into a Parkinson's disease mouse model to restore motor function.	Fu CL et al.	—	2024	→
Schwann cell-secreted PGE<sub>2</sub> promotes sensory neuron excitability during development.	Kantarci H et al.	—	2024	→
Sleep, mood disorders, and the ketogenic diet: potential therapeutic targets for bipolar disorder and schizophrenia.	Choi J et al.	—	2024	→
The impact of adult neurogenesis on affective functions: of mice and men.	Alonso M et al.	—	2024	→
The Potential Role of the Ketogenic Diet in Serious Mental Illness: Current Evidence, Safety, and Practical Advice.	Rog J et al.	—	2024	→
The risk of Alzheimer's disease and cognitive impairment characteristics in eight mental disorders: A UK Biobank observational study and Mendelian randomization analysis.	Liu Y et al.	—	2024	→
Translational bioinformatics and data science for biomarker discovery in mental health: an analytical review.	Bhuvaneshwar K et al.	—	2024	→
Treadmill Running Regulates Adult Neurogenesis, Spatial and Non-spatial Learning, Parvalbumin Neuron Activity by ErbB4 Signaling.	Yi Y et al.	—	2024	→
Zika virus NS5 protein inhibits type I interferon signaling via CRL3 E3 ubiquitin ligase-mediated degradation of STAT2.	Ren W et al.	—	2024	→
Advances and Applications of Brain Organoids.	Li Y et al.	—	2023	→
Advancing preclinical models of psychiatric disorders with human brain organoid cultures.	Dixon TA et al.	—	2023	→
A genetics-first approach to understanding autism and schizophrenia spectrum disorders: the 22q11.2 deletion syndrome.	Fiksinski AM et al.	—	2023	→
Alpha-linolenic acid enhances the facilitation of GABAergic neurotransmission in the BLA and CA1.	Pidoplichko VI et al.	—	2023	→
Bipolar Disorder.	Scott MR et al.	—	2023	→
Bipolar disorder-iPSC derived neural progenitor cells exhibit dysregulation of store-operated Ca<sup>2+</sup> entry and accelerated differentiation.	Hewitt T et al.	—	2023	→
Building causal knowledge in behavior genetics without racial/ethnic diversity will result in weak causal knowledge.	Syed M	—	2023	→
CaMKK2 as an emerging treatment target for bipolar disorder.	Kaiser J et al.	—	2023	→
Cellular Genome-wide Association Study Identifies Common Genetic Variation Influencing Lithium-Induced Neural Progenitor Proliferation.	Wolter JM et al.	—	2023	→
Contributions of circadian clock genes to cell survival in fibroblast models of lithium-responsive bipolar disorder.	Mishra HK et al.	—	2023	→
Depressive patient-derived GABA interneurons reveal abnormal neural activity associated with HTR2C.	Lu K et al.	—	2023	→
Divergent Directionality of Immune Cell-Specific Protein Expression between Bipolar Lithium Responders and Non-Responders Revealed by Enhanced Flow Cytometry.	Gao K et al.	—	2023	→
Emerging metallenes: synthesis strategies, biological effects and biomedical applications.	Lu C et al.	—	2023	→
Endo-Lysosomal and Autophagy Pathway and Ubiquitin-Proteasome System in Mood Disorders: A Review Article.	Matutino Santos P et al.	—	2023	→
Gm527 deficiency in dentate gyrus improves memory through upregulating dopamine D1 receptor pathway.	Jia J et al.	—	2023	→
Highly Selective Transmembrane Transport of Exogenous Lithium Ions through Rationally Designed Supramolecular Channels.	Zhang L et al.	—	2023	→
Identification of Neurotransmission and Synaptic Biological Processes Disrupted in Autism Spectrum Disorder Using Interaction Networks and Community Detection Analysis.	Vilela J et al.	—	2023	→
iPSCs-Derived Neurons and Brain Organoids from Patients.	Zhu W et al.	—	2023	→
Ketogenic-Mimicking Diet as a Therapeutic Modality for Bipolar Disorder: Biomechanistic Rationale and Protocol for a Pilot Clinical Trial.	Bohnen JLB et al.	—	2023	→
Mechanisms of Sustained Increases in <i>γ</i> Power Post-Ketamine in a Computational Model of the Hippocampal CA3: Implications for Ketamine's Antidepressant Mechanism of Action.	Petzi M et al.	—	2023	→
Mitochondria dysfunction and bipolar disorder: From pathology to therapy.	Lam XJ et al.	—	2023	→
Modeling placental development and disease using human pluripotent stem cells.	Morey R et al.	—	2023	→
Neural progenitor cells derived from lithium responsive and non-responsive bipolar disorder patients exhibit distinct sensitivity to cell death following methamphetamine.	Mishra HK et al.	—	2023	→
Neurite outgrowth deficits caused by rare PLXNB1 mutation in pediatric bipolar disorder.	Yang G et al.	—	2023	→
Non-canonical pathways in the pathophysiology and therapeutics of bipolar disorder.	Machado-Vieira R et al.	—	2023	→
On the utilization of the induced pluripotent stem cell (iPSC) model to study substance use disorders: A scoping review protocol.	Niemis W et al.	—	2023	→
Opportunities and limitations for studying neuropsychiatric disorders using patient-derived induced pluripotent stem cells.	Hong Y et al.	—	2023	→
Prenatal dexamethasone exposure induces anxiety- and depressive-like behavior of male offspring rats through intrauterine programming of the activation of NRG1-ErbB4 signaling in hippocampal PV interneurons.	Zhang S et al.	—	2023	→
RNA Biomarkers in Bipolar Disorder and Response to Mood Stabilizers.	Pisanu C et al.	—	2023	→
Role of microtubule actin crosslinking factor 1 (MACF1) in bipolar disorder pathophysiology and potential in lithium therapeutic mechanism.	Salem D et al.	—	2023	→
Shedding light on latent pathogenesis and pathophysiology of mental disorders: The potential of iPS cell technology.	Arioka Y et al.	—	2023	→
Stem Cell Models for Context-Specific Modeling in Psychiatric Disorders.	Seah C et al.	—	2023	→
The conundrum of antidepressant use in bipolar disorder.	Scaini G et al.	—	2023	→
The gene expression patterns as surrogate indices of pH in the brain.	Hagihara H et al.	—	2023	→
The Mood Stabilizer Lithium Slows Down Synaptic Vesicle Cycling at Glutamatergic Synapses.	Tang W et al.	—	2023	→
Transcriptional and functional effects of lithium in bipolar disorder iPSC-derived cortical spheroids.	Osete JR et al.	—	2023	→
Abnormalities in the migration of neural precursor cells in familial bipolar disorder.	Sukumaran SK et al.	—	2022	→
Analysis of hyperforin (St. John's wort) action at TRPC6 channel leads to the development of a new class of antidepressant drugs.	El Hamdaoui Y et al.	—	2022	→
Bipolar Disorder: From Pathophysiology to Treatment.	Kato T	—	2022	→
Building causal knowledge in behavior genetics.	Madole JW et al.	—	2022	→
CADPS functional mutations in patients with bipolar disorder increase the sensitivity to stress.	Sitbon J et al.	—	2022	→
Conserved age-related increases in hippocampal PDE11A4 cause unexpected proteinopathies and cognitive decline of social associative memories.	Pilarzyk K et al.	—	2022	→
CRISPR/Cas-Based Approaches to Study Schizophrenia and Other Neurodevelopmental Disorders.	Kurishev AO et al.	—	2022	→
Dysregulation of mitochondrial dynamics, mitophagy and apoptosis in major depressive disorder: Does inflammation play a role?	Scaini G et al.	—	2022	→
Genetics in psychiatry: Methods, clinical applications and future perspectives.	Fabbri C	—	2022	→
High-throughput CRISPRi and CRISPRa technologies in 3D genome regulation for neuropsychiatric diseases.	Jones IR et al.	—	2022	→
Human-Induced Pluripotent Stem Cell Technology: Toward the Future of Personalized Psychiatry.	Alciati A et al.	—	2022	→
In vivo hippocampal subfield volumes in bipolar disorder-A mega-analysis from The Enhancing Neuro Imaging Genetics through Meta-Analysis Bipolar Disorder Working Group.	Haukvik UK et al.	—	2022	→
Lessons from ecology for understanding the heterogeneity of bipolar disorder.	Nunes A et al.	—	2022	→
Leveraging a translational research approach to drive diagnostic and treatment advances for autism.	Parker KJ	—	2022	→
Lithium Enhances Hippocampal Glucose Metabolism in an In Vitro Mice Model of Alzheimer's Disease.	Gherardelli C et al.	—	2022	→
Lithium response in bipolar disorder: Genetics, genomics, and beyond.	Papiol S et al.	—	2022	→
Mechanisms of action of anti-bipolar drugs.	Kato T	—	2022	→
Metabolomics analysis of cerebrospinal fluid suggests citric acid cycle aberrations in bipolar disorder.	Smedler E et al.	—	2022	→
MicroRNAs, Stem Cells in Bipolar Disorder, and Lithium Therapeutic Approach.	Coradduzza D et al.	—	2022	→
Mitochondria DNA copy number, mitochondria DNA total somatic deletions, Complex I activity, synapse number, and synaptic mitochondria number are altered in schizophrenia and bipolar disorder.	Das SC et al.	—	2022	→
Modeling gene × environment interactions in PTSD using human neurons reveals diagnosis-specific glucocorticoid-induced gene expression.	Seah C et al.	—	2022	→
NMDA receptor inhibition prevents intracellular sodium elevations in human olfactory neuroepithelial precursors derived from bipolar patients.	Gao Y et al.	—	2022	→
Peripheral lymphocyte signaling pathway deficiencies predict treatment response in first-onset drug-naïve schizophrenia.	Lago SG et al.	—	2022	→
Perspectives of future lung toxicology studies using human pluripotent stem cells.	Masui A et al.	—	2022	→
Protein Biomarkers in Monocytes and CD4<sup>+</sup> Lymphocytes for Predicting Lithium Treatment Response of Bipolar Disorder: a Feasibility Study with Tyramine-Based Signal-Amplified Flow Cytometry.	Gao K et al.	—	2022	→
Reaching into the toolbox: Stem cell models to study neuropsychiatric disorders.	Whiteley JT et al.	—	2022	→
Research models of neurodevelopmental disorders: The right model in the right place.	Damianidou E et al.	—	2022	→
Schwann cells promote sensory neuron excitability during development	Kantarci H et al.	—	2022	—
Slitrk2 deficiency causes hyperactivity with altered vestibular function and serotonergic dysregulation.	Katayama KI et al.	—	2022	→
Transcriptional biomarkers of response to pharmacological treatments in severe mental disorders: A systematic review.	Pisanu C et al.	—	2022	→
Trends in big data analyses by multicenter collaborative translational research in psychiatry.	Onitsuka T et al.	—	2022	→
Using Stem Cell Models to Explore the Genetics Underlying Psychiatric Disorders: Linking Risk Variants, Genes, and Biology in Brain Disease.	Brennand KJ	—	2022	→
What is the Role of Lithium in Epilepsy?	Bojja SL et al.	—	2022	→
Advances in development and application of human organoids.	Shankaran A et al.	—	2021	→
Advances toward precision medicine for bipolar disorder: mechanisms & molecules.	Haggarty SJ et al.	—	2021	→
Advancing models of neural development with biomaterials.	Roth JG et al.	—	2021	→
Age-dependent instability of mature neuronal fate in induced neurons from Alzheimer's patients.	Mertens J et al.	—	2021	→
All-Optical Electrophysiology in hiPSC-Derived Neurons With Synthetic Voltage Sensors.	Puppo F et al.	—	2021	→
Altered Neuronal Support and Inflammatory Response in Bipolar Disorder Patient-Derived Astrocytes.	Vadodaria KC et al.	—	2021	→
An epilepsy-associated ACTL6B variant captures neuronal hyperexcitability in a human induced pluripotent stem cell model.	Ahn LY et al.	—	2021	→
Beneficial effects of Dendrobium nobile Lindl. Alkaloids (DNLA) on anxiety and depression induced by chronic unpredictable stress in rats.	Xiong TW et al.	—	2021	→
Biological Pathways Associated with Neuroprogression in Bipolar Disorder.	Wollenhaupt-Aguiar B et al.	—	2021	→
Catatonia associated with late-life psychosis successfully treated with lithium: a case report.	Sugawara H et al.	—	2021	→
Cellular calcium in bipolar disorder: systematic review and meta-analysis.	Harrison PJ et al.	—	2021	→
Characterisation of Neurospheres-Derived Cells from Human Olfactory Epithelium.	Zelenova EA et al.	—	2021	→
Chronic cortisol differentially impacts stem cell-derived astrocytes from major depressive disorder patients.	Heard KJ et al.	—	2021	→
Chronic lithium treatment alters the excitatory/ inhibitory balance of synaptic networks and reduces mGluR5-PKC signalling in mouse cortical neurons.	Khayachi A et al.	—	2021	→
Circadian rhythms in bipolar disorder patient-derived neurons predict lithium response: preliminary studies.	Mishra HK et al.	—	2021	→
Conditionally Reprogrammed Cells and Robotic High-Throughput Screening for Precision Cancer Therapy.	Alkhilaiwi F	—	2021	→
Contribution of Human Pluripotent Stem Cell-Based Models to Drug Discovery for Neurological Disorders.	Benchoua A et al.	—	2021	→
Deficient LEF1 expression is associated with lithium resistance and hyperexcitability in neurons derived from bipolar disorder patients.	Santos R et al.	—	2021	→
Depression patient-derived cortical neurons reveal potential biomarkers for antidepressant response.	Avior Y et al.	—	2021	→
Differential acute impact of therapeutically effective and overdose concentrations of lithium on human neuronal single cell and network function.	Izsak J et al.	—	2021	→
DNA methylation signature as a biomarker of major neuropsychiatric disorders.	Shirvani-Farsani Z et al.	—	2021	→
DNAzyme-Based Lithium-Selective Imaging Reveals Higher Lithium Accumulation in Bipolar Disorder Patient-Derived Neurons.	McGhee CE et al.	—	2021	→
Elevated Brain Glutamate Levels in Bipolar Disorder and Pyruvate Carboxylase-Mediated Anaplerosis.	Shen J et al.	—	2021	→
Exemplar scoring identifies genetically separable phenotypes of lithium responsive bipolar disorder.	Nunes A et al.	—	2021	→
Functional patient-derived cellular models for neuropsychiatric drug discovery.	Lago SG et al.	—	2021	→
Genomic perspectives on the circadian clock hypothesis of psychiatric disorders.	von Schantz M et al.	—	2021	→
Increased hippocampal excitability in miR-324-null mice.	Hayman DJ et al.	—	2021	→
Induced Pluripotent Stem Cells in Psychiatry: An Overview and Critical Perspective.	De Los Angeles A et al.	—	2021	→
Induced Pluripotent Stem Cells (iPSCs) Technology: Potential Targets for Depression.	Colpo GD et al.	—	2021	→
Inflammatory signaling mechanisms in bipolar disorder.	Jones GH et al.	—	2021	→
Intracellular Signaling Cascades in Bipolar Disorder.	Jones GH et al.	—	2021	→
Investigation of genetic loci shared between bipolar disorder and risk-taking propensity: potential implications for pharmacological interventions.	Pisanu C et al.	—	2021	→
Lithium increases mitochondrial respiration in iPSC-derived neural precursor cells from lithium responders.	Osete JR et al.	—	2021	→
Lithium treatment and human hippocampal neurogenesis.	Palmos AB et al.	—	2021	→
Lithium treatment in the era of personalized medicine.	Rybakowski JK	—	2021	→
Metabolism navigates neural cell fate in development, aging and neurodegeneration.	Traxler L et al.	—	2021	→
Mitochondrial Alterations in Fibroblasts of Early Stage Bipolar Disorder Patients.	Marques AP et al.	—	2021	→
Mitochondrial dysfunction as a critical event in the pathophysiology of bipolar disorder.	Scaini G et al.	—	2021	→
Mood Stabilizers in Psychiatric Disorders and Mechanisms Learnt from In Vitro Model Systems.	Nayak R et al.	—	2021	→
Ouabain inhibitor rostafuroxin attenuates dextromethorphan-induced manic potential.	Shin EJ et al.	—	2021	→
Plasma circulating cell-free mitochondrial DNA in depressive disorders.	Fernström J et al.	—	2021	→
Posttranslational modifications & lithium's therapeutic effect-Potential biomarkers for clinical responses in psychiatric & neurodegenerative disorders.	Khayachi A et al.	—	2021	→
Synaptotagmin-7-mediated activation of spontaneous NMDAR currents is disrupted in bipolar disorder susceptibility variants.	Wang QW et al.	—	2021	→
Systematic analysis of exonic germline and postzygotic de novo mutations in bipolar disorder.	Nishioka M et al.	—	2021	→
Targeting Mitochondrial Dysfunction for Bipolar Disorder.	Kuperberg M et al.	—	2021	→
Targeting neurotransmitter-mediated inflammatory mechanisms of psychiatric drugs to mitigate the double burden of multimorbidity and polypharmacy.	Matt SM	—	2021	→
Tau reduction affects excitatory and inhibitory neurons differently, reduces excitation/inhibition ratios, and counteracts network hypersynchrony.	Chang CW et al.	—	2021	→
The Neurometabolic Basis of Mood Instability: The Parvalbumin Interneuron Link-A Systematic Review and Meta-Analysis.	Pinna A et al.	—	2021	→
The Role of Genetics in Bipolar Disorder.	Fabbri C	—	2021	→
The Role of Mitochondria in Mood Disorders: From Physiology to Pathophysiology and to Treatment.	Giménez-Palomo A et al.	—	2021	→
The Role of Mitonuclear Incompatibility in Bipolar Disorder Susceptibility and Resilience Against Environmental Stressors.	Gonzalez S	—	2021	→
Translational evidence for lithium-induced brain plasticity and neuroprotection in the treatment of neuropsychiatric disorders.	Puglisi-Allegra S et al.	—	2021	→
Translational genomics and beyond in bipolar disorder.	Zhang C et al.	—	2021	→
Using iPSC Models to Understand the Role of Estrogen in Neuron-Glia Interactions in Schizophrenia and Bipolar Disorder.	Reis de Assis D et al.	—	2021	→
Valproate reverses mania-like behaviors in mice via preferential targeting of HDAC2.	Logan RW et al.	—	2021	→
Addressing variability in iPSC-derived models of human disease: guidelines to promote reproducibility.	Volpato V et al.	—	2020	→
A Physiological Instability Displayed in Hippocampal Neurons Derived From Lithium-Nonresponsive Bipolar Disorder Patients.	Stern S et al.	—	2020	→
A psychiatric disease-related circular RNA controls synaptic gene expression and cognition.	Zimmerman AJ et al.	—	2020	→
Brain Organoids: A Promising Living Biobank Resource for Neuroscience Research.	Li S et al.	—	2020	→
Developmental excitation-inhibition imbalance underlying psychoses revealed by single-cell analyses of discordant twins-derived cerebral organoids.	Sawada T et al.	—	2020	→
Exploring the neuropsychiatric spectrum using high-content functional analysis of single-cell signaling networks.	Lago SG et al.	—	2020	→
Human induced pluripotent stem cells technology in treatment resistant depression: novel strategies and opportunities to unravel ketamine's fast-acting antidepressant mechanisms.	Marcatili M et al.	—	2020	→
Human in vitro models for understanding mechanisms of autism spectrum disorder.	Gordon A et al.	—	2020	→
Human pluripotent stem cell-derived models and drug screening in CNS precision medicine.	Silva MC et al.	—	2020	→
Integrating CRISPR Engineering and hiPSC-Derived 2D Disease Modeling Systems.	Rehbach K et al.	—	2020	→
Lithium and the Interplay Between Telomeres and Mitochondria in Bipolar Disorder.	Lundberg M et al.	—	2020	→
Lithium response in bipolar disorder correlates with improved cell viability of patient derived cell lines.	Paul P et al.	—	2020	→
Mechanisms Underlying the Hyperexcitability of CA3 and Dentate Gyrus Hippocampal Neurons Derived From Patients With Bipolar Disorder.	Stern S et al.	—	2020	→
Mental health dished up-the use of iPSC models in neuropsychiatric research.	McNeill RV et al.	—	2020	→
Mitochondria, endoplasmic reticulum and innate immune dysfunction in mood disorders: Do Mitochondria-Associated Membranes (MAMs) play a role?	Resende R et al.	—	2020	→
Mitochondrial Dysfunction in Schizophrenia.	Ni P et al.	—	2020	→
Mitochondria under the spotlight: On the implications of mitochondrial dysfunction and its connectivity to neuropsychiatric disorders.	Zilocchi M et al.	—	2020	→
Modeling Brain Disorders Using Induced Pluripotent Stem Cells.	Vadodaria KC et al.	—	2020	→
Modeling neuropsychiatric disorders using human induced pluripotent stem cells.	Wang M et al.	—	2020	→
Modeling Psychiatric Disorder Biology with Stem Cells.	Das D et al.	—	2020	→
Modeling the complex genetic architectures of brain disease.	Fernando MB et al.	—	2020	→
Molecular Correlates of Topiramate and GRIK1 rs2832407 Genotype in Pluripotent Stem Cell-Derived Neural Cultures.	Lieberman R et al.	—	2020	→
Na<sup>+</sup>/K<sup>+</sup>-ATPase and lipid peroxidation in forebrain cortex and hippocampus of sleep-deprived rats treated with therapeutic lithium concentration for different periods of time.	Vosahlikova M et al.	—	2020	→
Neuronal Differentiation of Induced Pluripotent Stem Cells from Schizophrenia Patients in Two-Dimensional and in Three-Dimensional Cultures Reveals Increased Expression of the Kv4.2 Subunit DPP6 That Contributes to Decreased Neuronal Activity.	Naujock M et al.	—	2020	→
New era of personalised epilepsy management.	Chen Z et al.	—	2020	→
Patient-Derived Midbrain Organoids to Explore the Molecular Basis of Parkinson's Disease.	Galet B et al.	—	2020	→
Potential pharmacogenomic targets in bipolar disorder: considerations for current testing and the development of decision support tools to individualize treatment selection.	Cuéllar-Barboza AB et al.	—	2020	→
Prediction of lithium response using clinical data.	Nunes A et al.	—	2020	→
Profiling gene expression in the human dentate gyrus granule cell layer reveals insights into schizophrenia and its genetic risk.	Jaffe AE et al.	—	2020	→
Quantitative Systems Pharmacology for Neuroscience Drug Discovery and Development: Current Status, Opportunities, and Challenges.	Geerts H et al.	—	2020	→
Regulation of Inositol Biosynthesis: Balancing Health and Pathophysiology.	Case KC et al.	—	2020	→
Synaptotagmin-7 deficiency induces mania-like behavioral abnormalities through attenuating GluN2B activity.	Wang QW et al.	—	2020	→
Synaptotagmin-7 is a key factor for bipolar-like behavioral abnormalities in mice.	Shen W et al.	—	2020	→
Targeting Homeostatic Synaptic Plasticity for Treatment of Mood Disorders.	Kavalali ET et al.	—	2020	→
The application of human pluripotent stem cells to model the neuronal and glial components of neurodevelopmental disorders.	Lee KM et al.	—	2020	→
The genetics of bipolar disorder.	Gordovez FJA et al.	—	2020	→
The Relationship Between Food Craving, Appetite-Related Hormones and Clinical Parameters in Bipolar Disorder.	Platzer M et al.	—	2020	→
Unprecedented Potential for Neural Drug Discovery Based on Self-Organizing hiPSC Platforms.	Cota-Coronado A et al.	—	2020	→
Using Two- and Three-Dimensional Human iPSC Culture Systems to Model Psychiatric Disorders.	Christian KM et al.	—	2020	→
What is bipolar disorder? A disease model of dysregulated energy expenditure.	Mansur RB et al.	—	2020	→
Whole blood transcriptome analysis in bipolar disorder reveals strong lithium effect.	Krebs CE et al.	—	2020	→
Altered serotonergic circuitry in SSRI-resistant major depressive disorder patient-derived neurons.	Vadodaria KC et al.	—	2019	→
A Single-Cell Model for Synaptic Transmission and Plasticity in Human iPSC-Derived Neurons.	Meijer M et al.	—	2019	→
Assessing Neuronal Excitability on a Fluorometric Imaging Plate Reader (FLIPR) Following a Defined Electrostimulation Paradigm.	Kizner V et al.	—	2019	→
Calcium Channel Subunit α2δ4 Is Regulated by Early Growth Response 1 and Facilitates Epileptogenesis.	van Loo KMJ et al.	—	2019	→
Cell Fate Engineering Tools for iPSC Disease Modeling.	Lo EKW et al.	—	2019	→
Current understanding of bipolar disorder: Toward integration of biological basis and treatment strategies.	Kato T	—	2019	→
Diverse pathophysiological processes converge on network disruption in mania.	Lee I et al.	—	2019	→
Drug discovery in psychopharmacology: from 2D models to cerebral organoids .	Rossetti AC et al.	—	2019	→
Entrainment of Circadian Rhythms to Temperature Reveals Amplitude Deficits in Fibroblasts from Patients with Bipolar Disorder and Possible Links to Calcium Channels.	Nudell V et al.	—	2019	→
Ethanol normalizes glutamate-induced elevation of intracellular sodium in olfactory neuroepithelial progenitors from subjects with bipolar illness but not nonbipolar controls: Biologic evidence for the self-medication hypothesis.	Gao Y et al.	—	2019	→
Genome-wide association study identifies 30 loci associated with bipolar disorder.	Stahl EA et al.	—	2019	→
Genomics of Lithium Action and Response.	Pickard BS	—	2019	→
Induced pluripotent stem cells for neural drug discovery.	Farkhondeh A et al.	—	2019	→
Integrative Analysis of DiseaseLand Omics Database for Disease Signatures and Treatments: A Bipolar Case Study.	Wu C et al.	—	2019	→
iPSCs-Based Neural 3D Systems: A Multidimensional Approach for Disease Modeling and Drug Discovery.	Costamagna G et al.	—	2019	→
Lithium alters expression of RNAs in a type-specific manner in differentiated human neuroblastoma neuronal cultures, including specific genes involved in Alzheimer's disease.	Maloney B et al.	—	2019	→
Mapping cis-regulatory chromatin contacts in neural cells links neuropsychiatric disorder risk variants to target genes.	Song M et al.	—	2019	→
Metabolomics Analyses of 14 Classical Neurotransmitters by GC-TOF with LC-MS Illustrates Secretion of 9 Cell-Cell Signaling Molecules from Sympathoadrenal Chromaffin Cells in the Presence of Lithium.	Hook V et al.	—	2019	→
Mitochondria, Metabolism, and Redox Mechanisms in Psychiatric Disorders.	Kim Y et al.	—	2019	→
Modeling Psychiatric Diseases with Induced Pluripotent Stem Cells.	van Hugte E et al.	—	2019	→
Molecular Mechanisms Linking ALS/FTD and Psychiatric Disorders, the Potential Effects of Lithium.	Limanaqi F et al.	—	2019	→
Neuronal migration in the CNS during development and disease: insights from <i>in vivo</i> and <i>in vitro</i> models.	Buchsbaum IY et al.	—	2019	→
New considerations for hiPSC-based models of neuropsychiatric disorders.	Hoffman GE et al.	—	2019	→
Next-generation disease modeling with direct conversion: a new path to old neurons.	Traxler L et al.	—	2019	→
Novel Complex Interactions between Mitochondrial and Nuclear DNA in Schizophrenia and Bipolar Disorder.	Schulmann A et al.	—	2019	→
Peripheral blood metabolome predicts mood change-related activity in mouse model of bipolar disorder.	Hagihara H et al.	—	2019	→
Phosphoinositides: Regulators of Nervous System Function in Health and Disease.	Raghu P et al.	—	2019	→
Prediction of Response to Drug Therapy in Psychiatric Disorders.	Stern S et al.	—	2019	→
Research Domain Criteria: Strengths, Weaknesses, and Potential Alternatives for Future Psychiatric Research.	Ross CA et al.	—	2019	→
RNA sequencing of bipolar disorder lymphoblastoid cell lines implicates the neurotrophic factor HRP-3 in lithium's clinical efficacy.	Milanesi E et al.	—	2019	→
Robust Generation of Person-Specific, Synchronously Active Neuronal Networks Using Purely Isogenic Human iPSC-3D Neural Aggregate Cultures.	Izsak J et al.	—	2019	→
Scalable Measurements of Intrinsic Excitability in Human iPS Cell-Derived Excitatory Neurons Using All-Optical Electrophysiology.	Williams LA et al.	—	2019	→
Serotonin-induced hyperactivity in SSRI-resistant major depressive disorder patient-derived neurons.	Vadodaria KC et al.	—	2019	→
Single-cell multimodal transcriptomics to study neuronal diversity in human stem cell-derived brain tissue and organoid models.	van den Hurk M et al.	—	2019	→
Sodium valproate rescues expression of TRANK1 in iPSC-derived neural cells that carry a genetic variant associated with serious mental illness.	Jiang X 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	→
Study of 45 candidate genes suggests CACNG2 may be associated with lithium response in bipolar disorder.	Miranda A et al.	—	2019	→
The Emergent Course of Bipolar Disorder: Observations Over Two Decades From the Canadian High-Risk Offspring Cohort.	Duffy A et al.	—	2019	→
The Emerging Neurobiology of Bipolar Disorder.	Harrison PJ et al.	—	2019	→
Therapeutic Potential of Exogenous Ketone Supplement Induced Ketosis in the Treatment of Psychiatric Disorders: Review of Current Literature.	Kovács Z et al.	—	2019	→
Therapeutic targeting of 3',5'-cyclic nucleotide phosphodiesterases: inhibition and beyond.	Baillie GS et al.	—	2019	→
Transcriptome Changes in Relation to Manic Episode.	Lee YC et al.	—	2019	→
Transcriptomic immaturity inducible by neural hyperexcitation is shared by multiple neuropsychiatric disorders.	Murano T et al.	—	2019	→
Using human stem cells as a model system to understand the neural mechanisms of alcohol use disorders: Current status and outlook.	Scarnati MS et al.	—	2019	→
A gene co-expression module implicating the mitochondrial electron transport chain is associated with long-term response to lithium treatment in bipolar affective disorder.	Stacey D et al.	—	2018	→
A Genome-Wide Search for Bipolar Disorder Risk Loci Modified by Mitochondrial Genome Variation.	Ryu E et al.	—	2018	→
Association of Polygenic Score for Schizophrenia and HLA Antigen and Inflammation Genes With Response to Lithium in Bipolar Affective Disorder: A Genome-Wide Association Study.	International Consortium on Lithium Genetics (ConLi+Gen) et al.	—	2018	→
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Building Models of Brain Disorders with Three-Dimensional Organoids.	Amin ND et al.	—	2018	→
Canadian Network for Mood and Anxiety Treatments (CANMAT) and International Society for Bipolar Disorders (ISBD) 2018 guidelines for the management of patients with bipolar disorder.	Yatham LN et al.	—	2018	→
Can lithium salts prevent depressive episodes in the real world?	González-Pinto A et al.	—	2018	→
Derivation of Cortical Spheroids from Human Induced Pluripotent Stem Cells in a Suspension Bioreactor.	Yan Y et al.	—	2018	→
Discovery biology of neuropsychiatric syndromes (DBNS): a center for integrating clinical medicine and basic science.	Viswanath B et al.	—	2018	→
Dynamic Changes of the Mitochondria in Psychiatric Illnesses: New Mechanistic Insights From Human Neuronal Models.	Srivastava R et al.	—	2018	→
Excitatory and inhibitory synaptic dysfunction in mania: an emerging hypothesis from animal model studies.	Lee Y et al.	—	2018	→
From the Psychiatrist's Couch to Induced Pluripotent Stem Cells: Bipolar Disease in a Dish.	Hoffmann A et al.	—	2018	→
Genetics of Alcohol Use Disorder: A Role for Induced Pluripotent Stem Cells?	Prytkova I et al.	—	2018	→
High-fructose corn syrup consumption in adolescent rats causes bipolar-like behavioural phenotype with hyperexcitability in hippocampal CA3-CA1 synapses.	Alten B 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	→
Investigating pediatric disorders with induced pluripotent stem cells.	Durbin MD et al.	—	2018	→
iPlasticity: Induced juvenile-like plasticity in the adult brain as a mechanism of antidepressants.	Umemori J et al.	—	2018	→
Lithium-associated transcriptional regulation of CRMP1 in patient-derived olfactory neurons and symptom changes in bipolar disorder.	McLean CK et al.	—	2018	→
Lithium: The silver lining to clouded thinking?	Malhi GS et al.	—	2018	→
Mitochondrial Complex I Deficiency in Schizophrenia and Bipolar Disorder and Medication Influence.	Rollins BL et al.	—	2018	→
Neurons derived from patients with bipolar disorder divide into intrinsically different sub-populations of neurons, predicting the patients' responsiveness to lithium.	Stern S et al.	—	2018	→
Patch-Seq Protocol to Analyze the Electrophysiology, Morphology and Transcriptome of Whole Single Neurons Derived From Human Pluripotent Stem Cells.	van den Hurk M et al.	—	2018	→
Pluripotent Stem Cells for Uncovering the Role of Mitochondria in Human Brain Function and Dysfunction.	Zink A et al.	—	2018	→
Potential Use of Stem Cells in Mood Disorders.	Colpo GD et al.	—	2018	→
Prediction of response to drug therapy in psychiatric disorders.	Stern S et al.	—	2018	→
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Serotonin depletion causes valproate-responsive manic-like condition and increased hippocampal neuroplasticity that are reversed by stress.	Maddaloni G et al.	—	2018	→
Serotonin in psychiatry: in vitro disease modeling using patient-derived neurons.	Vadodaria KC et al.	—	2018	→
Studying the Brain in a Dish: 3D Cell Culture Models of Human Brain Development and Disease.	Brown J et al.	—	2018	→
The Emerging Neurobiology of Bipolar Disorder.	Harrison PJ et al.	—	2018	→
Toward a Reasoned Classification of Diseases Using Physico-Chemical Based Phenotypes.	Schwartz L et al.	—	2018	→
Trait and state biomarkers for psychiatric disorders: Importance of infrastructure to bridge the gap between basic and clinical research and industry.	Lema YY et al.	—	2018	→
Uncovering True Cellular Phenotypes: Using Induced Pluripotent Stem Cell-Derived Neurons to Study Early Insults in Neurodevelopmental Disorders.	Fink JJ et al.	—	2018	→
What Should a Psychiatrist Know About Genetics? Review and Recommendations From the Residency Education Committee of the International Society of Psychiatric Genetics.	Nurnberger JI et al.	—	2018	→
Advanced Photoacoustic Imaging Applications of Near-Infrared Absorbing Organic Nanoparticles.	Jiang Y et al.	—	2017	→
A genome wide association study suggests the association of muskelin with early onset bipolar disorder: Implications for a GABAergic epileptogenic neurogenesis model.	Nassan M et al.	—	2017	→
All-Optical Electrophysiology for Disease Modeling and Pharmacological Characterization of Neurons.	Werley CA et al.	—	2017	→
Antidepressant and anxiolytic-like behavioral effects of erucamide, a bioactive fatty acid amide, involving the hypothalamus-pituitary-adrenal axis in mice.	Li MM et al.	—	2017	→
Application of CRISPR/Cas9 to the study of brain development and neuropsychiatric disease.	Powell SK et al.	—	2017	→
Application of induced pluripotent stem cells to understand neurobiological basis of bipolar disorder and schizophrenia.	Liu YN et al.	—	2017	→
Are reprogrammed cells a useful tool for studying dopamine dysfunction in psychotic disorders? A review of the current evidence.	Sauerzopf U et al.	—	2017	→
A Role for Phosphodiesterase 11A (PDE11A) in the Formation of Social Memories and the Stabilization of Mood.	Kelly MP	—	2017	→
Assessment of engineered cells using CellNet and RNA-seq.	Radley AH et al.	—	2017	→
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Chronic lithium treatment elicits its antimanic effects via BDNF-TrkB dependent synaptic downscaling.	Gideons ES et al.	—	2017	→
Concise Review: Induced Pluripotent Stem Cell Models for Neuropsychiatric Diseases.	Adegbola A et al.	—	2017	→
CRISPR/Cas9-mediated heterozygous knockout of the autism gene CHD8 and characterization of its transcriptional networks in cerebral organoids derived from iPS cells.	Wang P et al.	—	2017	→
Default Patterning Produces Pan-cortical Glutamatergic and CGE/LGE-like GABAergic Neurons from Human Pluripotent Stem Cells.	Floruta CM et al.	—	2017	→
Differentiation of Inflammation-Responsive Astrocytes from Glial Progenitors Generated from Human Induced Pluripotent Stem Cells.	Santos R et al.	—	2017	→
Direct Neuronal Reprogramming for Disease Modeling Studies Using Patient-Derived Neurons: What Have We Learned?	Drouin-Ouellet J et al.	—	2017	→
Distinct lithium-induced gene expression effects in lymphoblastoid cell lines from patients with bipolar disorder.	Fries GR et al.	—	2017	→
Do the Trajectories of Bipolar Disorder and Schizophrenia Follow a Universal Staging Model?	Duffy A et al.	—	2017	→
Examining FKBP5 mRNA expression in human iPSC-derived neural cells.	Lieberman R et al.	—	2017	→
From direct to indirect lithium targets: a comprehensive review of omics data.	Roux M et al.	—	2017	→
Genomics of Lithium Action and Response.	Pickard BS	—	2017	→
High-Throughput and Cost-Effective Characterization of Induced Pluripotent Stem Cells.	D'Antonio M et al.	—	2017	→
Human induced pluripotent stem cells for modelling neurodevelopmental disorders.	Ardhanareeswaran K et al.	—	2017	→
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Integrated Genomic Medicine: A Paradigm for Rare Diseases and Beyond.	Schork NJ et al.	—	2017	→
In Vitro Human Umbilical Vein Endothelial Cells Response to Ionic Dissolution Products from Lithium-Containing 45S5 Bioactive Glass.	Haro Durand LA et al.	—	2017	→
Modeling neurodevelopmental and psychiatric diseases with human iPSCs.	Wen Z	—	2017	→
Molecular Mechanisms of Bipolar Disorder: Progress Made and Future Challenges.	Kim Y et al.	—	2017	→
Mouse models and induced pluripotent stem cells in researching psychiatric disorders.	Deng B	—	2017	→
Neurobiological basis of bipolar disorder: Mitochondrial dysfunction hypothesis and beyond.	Kato T	—	2017	→
Olfactory Neuroepithelial Neural Progenitor Cells from Subjects with Bipolar I Disorder.	Gao Y et al.	—	2017	→
PDE11A negatively regulates lithium responsivity.	Pathak G et al.	—	2017	→
Pluripotent stem cells in neuropsychiatric disorders.	Soliman MA et al.	—	2017	→
Probing the lithium-response pathway in hiPSCs implicates the phosphoregulatory set-point for a cytoskeletal modulator in bipolar pathogenesis.	Tobe BTD et al.	—	2017	→
Recent advances in the understanding and management of bipolar disorder in adults.	Rybakowski JK	—	2017	→
Stem cell-derived neurons in the development of targeted treatment for schizophrenia and bipolar disorder.	Watmuff B et al.	—	2017	→
The use of brain organoids to investigate neural development and disease.	Di Lullo E et al.	—	2017	→
Understanding neurodevelopmental disorders using human pluripotent stem cell-derived neurons.	Tamburini C et al.	—	2017	→
Unraveling the biology of bipolar disorder using induced pluripotent stem-derived neurons.	Miller ND et al.	—	2017	→
Who are excellent lithium responders and why do they matter?	Alda M	—	2017	→
Adult Neurogenesis in the Hippocampus: From Stem Cells to Behavior.	Gonçalves JT et al.	—	2016	→
Advancing drug discovery for neuropsychiatric disorders using patient-specific stem cell models.	Haggarty SJ et al.	—	2016	→
A systematic review of calcium channel antagonists in bipolar disorder and some considerations for their future development.	Cipriani A et al.	—	2016	→
Chronic LiCl pretreatment suppresses thrombin-stimulated intracellular calcium mobilization through TRPC3 in astroglioma cells.	Uemura T et al.	—	2016	→
Circadian Gene Circuitry Predicts Hyperactive Behavior in a Mood Disorder Mouse Model.	Hagihara H et al.	—	2016	→
Circadian genes and lithium response in bipolar disorders: associations with PPARGC1A (PGC-1α) and RORA.	Geoffroy PA et al.	—	2016	→
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Concise Review: Progress and Challenges in Using Human Stem Cells for Biological and Therapeutics Discovery: Neuropsychiatric Disorders.	Panchision DM	—	2016	→
Disease signatures for schizophrenia and bipolar disorder using patient-derived induced pluripotent stem cells.	Watmuff B et al.	—	2016	→
Erratum: Differential responses to lithium in hyperexcitable neurons from patients with bipolar disorder.	Mertens J et al.	—	2016	→
Evaluating cell reprogramming, differentiation and conversion technologies in neuroscience.	Mertens J et al.	—	2016	→
Functional Characterization of Acetylcholine Receptors Expressed in Human Neurons Differentiated from Hippocampal Neural Stem/Progenitor Cells.	Fukushima K et al.	—	2016	→
Functional Properties of Human Stem Cell-Derived Neurons in Health and Disease.	Weick JP	—	2016	→
Genetics of Bipolar Disorder: Recent Update and Future Directions.	Goes FS	—	2016	→
Gsk3 Signalling and Redox Status in Bipolar Disorder: Evidence from Lithium Efficacy.	Luca A et al.	—	2016	→
Human iPSC-derived neurons and lymphoblastoid cells for personalized medicine research in neuropsychiatric disorders.	Gurwitz D	—	2016	→
Immaturity of brain as an endophenotype of neuropsychiatric disorders.	Hagihara H et al.	—	2016	→
Impedimetric real-time monitoring of neural pluripotent stem cell differentiation process on microelectrode arrays.	Seidel D et al.	—	2016	→
Increased nicotine response in iPSC-derived human neurons carrying the CHRNA5 N398 allele.	Oni EN et al.	—	2016	→
Innovative approaches to bipolar disorder and its treatment.	Harrison PJ et al.	—	2016	→
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Lithium-Responsive Seizure-Like Hyperexcitability Is Caused by a Mutation in the <i>Drosophila</i> Voltage-Gated Sodium Channel Gene <i>paralytic</i>.	Kaas GA et al.	—	2016	→
Modeling psychiatric disorders: from genomic findings to cellular phenotypes.	Falk A et al.	—	2016	→
Modeling psychiatric disorders with patient-derived iPSCs.	Wen Z et al.	—	2016	→
Neural patterning of human induced pluripotent stem cells in 3-D cultures for studying biomolecule-directed differential cellular responses.	Yan Y et al.	—	2016	→
Neurodevelopmental origins of bipolar disorder: iPSC models.	O'Shea KS et al.	—	2016	→
News Feature: Better models for brain disease.	Shen HH	—	2016	→
Opportunities for translational research in the epigenetics of mood disorders: a comment to the review by Robert M. Post.	Malhi GS et al.	—	2016	→
Patient-derived induced pluripotent stem cells in cancer research and precision oncology.	Papapetrou EP	—	2016	→
PDE11A regulates social behaviors and is a key mechanism by which social experience sculpts the brain.	Hegde S et al.	—	2016	→
Pharmacologic Activation of Wnt Signaling by Lithium Normalizes Retinal Vasculature in a Murine Model of Familial Exudative Vitreoretinopathy.	Wang Z et al.	—	2016	→
Phosphodiesterase 11A (PDE11A), Enriched in Ventral Hippocampus Neurons, is Required for Consolidation of Social but not Nonsocial Memories in Mice.	Hegde S et al.	—	2016	→
Regulation of persistent sodium currents by glycogen synthase kinase 3 encodes daily rhythms of neuronal excitability.	Paul JR et al.	—	2016	→
Serotonergic neurons derived from induced pluripotent stem cells (iPSCs): a new pathway for research on the biology and pharmacology of major depression.	Licinio J et al.	—	2016	→
The Inositol Trisphosphate/Calcium Signaling Pathway in Health and Disease.	Berridge MJ	—	2016	→
The potential of genetic and gene expression analysis in the diagnosis of neuropsychiatric disorders.	van de Leemput J et al.	—	2016	→
The promises and challenges of human brain organoids as models of neuropsychiatric disease.	Quadrato G et al.	—	2016	→
Therapeutic Mechanisms of Lithium in Bipolar Disorder: Recent Advances and Current Understanding.	Malhi GS et al.	—	2016	→
Translational Prospects and Challenges in Human Induced Pluripotent Stem Cell Research in Drug Discovery.	Hosoya M et al.	—	2016	→
Update on bipolar disorder biomarker candidates.	Teixeira AL et al.	—	2016	→
Using Induced Pluripotent Stem Cells to Investigate Complex Genetic Psychiatric Disorders.	Temme SJ et al.	—	2016	→
Voltage-gated calcium channels and their auxiliary subunits: physiology and pathophysiology and pharmacology.	Dolphin AC	—	2016	→
Psychiatric disorders: Modelling lithium responsiveness in a dish.	Whalley K	—	2015	→