Project description:In a concentration-response study, we have employed a human-relevant brain microphysiological system (bMPS), containing human-iPSC derived glutamatergic and GABAergic neurons co-cultured with primary human astrocytes, to monitor and detect the changes in the electrical activity of engineered human iPSC-derived neural networks to increasing concentrations of the sarin surrogate, 4-nitrophenylisopropyl methylphosphonate (NIMP). Transcriptomic analysis was conducted at 6-days post exposure to evaluate gene expression changes that could have contributed to how neurons communicated following NIMP exposure.

Project description:Plaque-associated axonal spheroids (PAAS) are frequently observed around amyloid deposits in Alzheimer's disease (AD) and are known to impair axonal electrical conduction, disrupt neural circuits, and correlate with AD severity. Despite their significance, the mechanisms underlying PAAS formation remain largely unknown. To explore this, we developed a proximity labeling proteomics approach to identify the PAAS proteome in human postmortem brains and mice. Additionally, we established a human iPSC-derived AD model allowing structural, optical electrophysiology, and mechanistic investigation of PAAS pathology. This approach revealed the molecular architecture of PAAS and identified dysregulated biological processes, including protein turnover, cytoskeleton dynamics, and lipid transport. Activated PI3K/AKT/mTOR pathway, which regulates these processes, was expressed in PAAS and strongly correlated with AD severity in humans. Inhibition of mTOR in human iPSC-derived neurons and in mice led to a marked reduction in PAAS. Our study provides a multidisciplinary toolkit for investigating axonal pathology and identifying novel targets for neurodegeneration.

Project description:sample 666823 and 666824 control IgG pulldown in human iPSC derived APPDp neurons sample 666825 and 666826 TERT pulldown in human iPSC derived APPDp neurons

Project description:Gene expression from human iPSC derived motor neurons.

Project description:Gene expression from human iPSC derived motor neurons.

Project description:Direct effects of prolonged TNF-α and IL-6 exposure on neural activity in human iPSC-derived neuron-astrocyte co-cultures

Project description:human iPSC-neurons and human cortex

Project description:Transcriptomic analysis of iPSC tri-culture (microglia, neurons, astrocytes) stimulated with Tnf, Smac, and Zvad (TSZ) to trigger necroptosis pathway activation, in the presence or absence of a Ripk1 inhibitor

Project description:A Human iPSC-derived Microphysiological Blood-Brain Barrier Model for Permeability Screening

Project description:The study of cardiac physiology and disease is hindered by physiological differences between humans and small-animal models. Here, we report the generation of multi-chambered vascularized human cardiac organoids under anisotropic stress, and their applicability to study electro-metabolic coupling in cardiac tissue. The organoids are derived from human induced pluripotent stem cells, and integrate sensors for the simultaneous measurement of oxygen uptake, extracellular field potentials and cardiac contraction at resolutions higher than 10 Hz. The microphysiological system allowed us to find that 1-Hz cardiac respiratory cycles are coupled with electrical activity rather than with mechanical activity, that calcium oscillations drive a mitochondrial respiration cycle, that the pharmaceutical or genetic inhibition of electro-mitochondrial coupling results in arrhythmogenic behaviour, and that the induction of arrythmia by the chemotherapeutic mitoxantrone can be partially reversed by the co-administration of metformin. Microphysiological cardiac systems may further facilitate the study of the mitochondrial dynamics of cardiac rhythms and advance the understanding of cardiac physiology.