An Electrophysiological and Pharmacological Study of the Properties of Human iPSC-Derived Neurons for Drug Discovery

Halliwell, Robert F.; Salmanzadeh, Hamed; Coyne, Leanne; Cao, William S.

doi:10.3390/cells10081953

Cited by 9 publications

(7 citation statements)

References 44 publications

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“…We then compared the input resistance and found no significant difference between the control and L1342P neurons (control: 2.0 6 0.2 pF, n = 18; L1342P: 1.6 6 0.2 pF, n = 23; p = 0.16, Student's t test). While a potassium chloride-based solution (we used herein) is widely used to study neurons (Parker et al, 2018;Mis et al, 2019;Halliwell et al, 2021), it may depolarize the cell membrane. To address the potential issue that the potassium chloride in the internal solution may change the firing property, we performed an additional experiment by using a potassium acetate-based solution.…”

Section: Nav12-l1342p Channel Displays Complex Biophysical Propertiesmentioning

confidence: 99%

Hyperexcitability and Pharmacological Responsiveness of Cortical Neurons Derived from Human iPSCs Carrying Epilepsy-Associated Sodium Channel Nav1.2-L1342P Genetic Variant

et al. 2021

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With the wide adoption of genomic sequencing in children having seizures, an increasing number of SCN2A genetic variants have been revealed as genetic causes of epilepsy. Voltage-gated sodium channel Nav1.2, encoded by gene SCN2A, is predominantly expressed in the pyramidal excitatory neurons and supports action potential (AP) firing. One recurrent SCN2A genetic variant is L1342P, which was identified in multiple patients with epileptic encephalopathy and intractable seizures. However, the mechanism underlying L1342P-mediated seizures and the pharmacogenetics of this variant in human neurons remain unknown. To understand the core phenotypes of the L1342P variant in human neurons, we took advantage of a reference human-induced pluripotent stem cell (hiPSC) line from a male donor, in which L1342P was introduced by CRISPR/ Cas9-mediated genome editing. Using patch-clamping and microelectrode array (MEA) recordings, we revealed that cortical neurons derived from hiPSCs carrying heterozygous L1342P variant have significantly increased intrinsic excitability, higher sodium current density, and enhanced bursting and synchronous network firing, suggesting hyperexcitability phenotypes. Interestingly, L1342P neuronal culture displayed a degree of resistance to the anticonvulsant medication phenytoin, which recapitulated aspects of clinical observation of patients carrying the L1342P variant. In contrast, phrixotoxin-3 (PTx3), a Nav1.2 isoform-specific blocker, can potently alleviate spontaneous and chemically-induced hyperexcitability of neurons carrying the L1342P variant. Our results reveal a possible pathogenic underpinning of Nav1.2-L1342P mediated epileptic seizures and demonstrate the utility of genome-edited hiPSCs as an in vitro platform to advance personalized phenotyping and drug discovery.

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Section: Nav12-l1342p Channel Displays Complex Biophysical Propertiesmentioning

confidence: 99%

Hyperexcitability and Pharmacological Responsiveness of Cortical Neurons Derived from Human iPSCs Carrying Epilepsy-Associated Sodium Channel Nav1.2-L1342P Genetic Variant

et al. 2021

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“…Multi-electrode array (MEA) is the most common assay used to assess neuronal functionality by measuring the electrical activity in the test system. Traditional MEA plates were designed for monolayer cultures and are broadly used in neuroscience ( Halliwell et al, 2021 ; Taga et al, 2021 ; Tukker and Westerink, 2021 ). Furthermore, MEA has been applied to assess neurotoxicity and DNT in high throughput manner ( Strickland et al, 2018 ; Shafer et al, 2019 ).…”

Section: Challenges and Opportunities For 3d Brain Modelsmentioning

confidence: 99%

The Future of 3D Brain Cultures in Developmental Neurotoxicity Testing

Högberg

Smirnova

2022

Front. Toxicol.

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Human brain is undoubtedly the most complex organ in the body. Thus, it is difficult to develop adequate and at the same time human relevant test systems and models to cover the aspects of brain homeostasis and even more challenging to address brain development. Animal tests for Developmental Neurotoxicity (DNT) have been devised, but because of complex underlying mechanisms of neural development, and interspecies differences, there are many limitations of animal-based approaches. The high costs, high number of animals used per test and technical difficulties of these tests are prohibitive for routine DNT chemical screening. Therefore, many potential DNT chemicals remain unidentified. New approach methodologies (NAMs) are needed to change this. Experts in the field have recommended the use of a battery of human in vitro tests to be used for the initial prioritization of high-risk environmental chemicals for DNT testing. Microphysiological systems (MPS) of the brain mimic the in vivo counterpart in terms of cellular composition, recapitulation of regional architecture and functionality. These systems amendable to use in a DNT test battery with promising features such as (i) complexity, (ii) closer recapitulation of in vivo response and (iii) possibility to multiplex many assays in one test system, which can increase throughput and predictivity for human health. The resent progress in 3D brain MPS research, advantages, limitations and future perspectives are discussed in this review.

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“…Recently, brain-on-a-chip (BOC) platforms, which often integrate cell cultures with a multi-electrode arrays (MEA), have emerged as a powerful technology to non-invasively record extracellular action potentials from primary rodent or human induced Pluripotent Stem Cell (iPSC)-derived neurons cultured on these systems ( Kamioka et al, 1996 ; Chiappalone et al, 2003 ; Halliwell et al, 2021 ). The ability to monitor the functional dynamics of neural and network activity have been useful in evaluating pharmacological and toxicological effects of compounds on network activity ( Chiappalone et al, 2003 ; Johnstone et al, 2010 ), and better understand how cellular and molecular changes affect the functional properties of neurons and their networks in vitro .…”

Section: Introductionmentioning

confidence: 99%

Dose-dependent consequences of sub-chronic fentanyl exposure on neuron and glial co-cultures

et al. 2022

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Fentanyl is one of the most common opioid analgesics administered to patients undergoing surgery or for chronic pain management. While the side effects of chronic fentanyl abuse are recognized (e.g., addiction, tolerance, impairment of cognitive functions, and inhibit nociception, arousal, and respiration), it remains poorly understood what and how changes in brain activity from chronic fentanyl use influences the respective behavioral outcome. Here, we examined the functional and molecular changes to cortical neural network activity following sub-chronic exposure to two fentanyl concentrations, a low (0.01 μM) and high (10 μM) dose. Primary rat co-cultures, containing cortical neurons, astrocytes, and oligodendrocyte precursor cells, were seeded in wells on either a 6-well multi-electrode array (MEA, for electrophysiology) or a 96-well tissue culture plate (for serial endpoint bulk RNA sequencing analysis). Once networks matured (at 28 days in vitro), co-cultures were treated with 0.01 or 10 μM of fentanyl for 4 days and monitored daily. Only high dose exposure to fentanyl resulted in a decline in features of spiking and bursting activity as early as 30 min post-exposure and sustained for 4 days in cultures. Transcriptomic analysis of the complex cultures after 4 days of fentanyl exposure revealed that both the low and high dose induced gene expression changes involved in synaptic transmission, inflammation, and organization of the extracellular matrix. Collectively, the findings of this in vitro study suggest that while neuroadaptive changes to neural network activity at a systems level was detected only at the high dose of fentanyl, transcriptomic changes were also detected at the low dose conditions, suggesting that fentanyl rapidly elicits changes in plasticity.

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An Electrophysiological and Pharmacological Study of the Properties of Human iPSC-Derived Neurons for Drug Discovery

Cited by 9 publications

References 44 publications

Hyperexcitability and Pharmacological Responsiveness of Cortical Neurons Derived from Human iPSCs Carrying Epilepsy-Associated Sodium Channel Nav1.2-L1342P Genetic Variant

Hyperexcitability and Pharmacological Responsiveness of Cortical Neurons Derived from Human iPSCs Carrying Epilepsy-Associated Sodium Channel Nav1.2-L1342P Genetic Variant

The Future of 3D Brain Cultures in Developmental Neurotoxicity Testing

Dose-dependent consequences of sub-chronic fentanyl exposure on neuron and glial co-cultures

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