Your search keyword '"Kevan Shah"' showing total 11 results

1. Genetically encoded cell-death indicators (GEDI) to detect an early irreversible commitment to neurodegeneration

Author

Jeremy W. Linsley, Kevan Shah, Nicholas Castello, Michelle Chan, Dominik Haddad, Zak Doric, Shijie Wang, Wiktoria Leks, Jay Mancini, Viral Oza, Ashkan Javaherian, Ken Nakamura, David Kokel, and Steven Finkbeiner

Subjects

Science

Abstract

Cell death is a critical process in health and disease, yet available markers record later stages of cell death once a cell has already begun to decompose. Here the authors show the use of a genetically encoded calcium indicator that demarcates an irreversible stage of cell death earlier than previously possible.

Published

2021

2. A Newly Defined and Xeno-Free Culture Medium Supports Every-Other-Day Medium Replacement in the Generation and Long-Term Cultivation of Human Pluripotent Stem Cells.

Author

Behnam Ahmadian Baghbaderani, Xinghui Tian, Jean Scotty Cadet, Kevan Shah, Amy Walde, Huan Tran, Don Paul Kovarcik, Diana Clarke, and Thomas Fellner

Subjects

Medicine, Science

Abstract

Human pluripotent stem cells (hPSCs) present an unprecedented opportunity to advance human health by offering an alternative and renewable cell resource for cellular therapeutics and regenerative medicine. The present demand for high quality hPSCs for use in both research and clinical studies underscores the need to develop technologies that will simplify the cultivation process and control variability. Here we describe the development of a robust, defined and xeno-free hPSC medium that supports reliable propagation of hPSCs and generation of human induced pluripotent stem cells (hiPSCs) from multiple somatic cell types; long-term serial subculturing of hPSCs with every-other-day (EOD) medium replacement; and banking fully characterized hPSCs. The hPSCs cultured in this medium for over 40 passages are genetically stable, retain high expression levels of the pluripotency markers TRA-1-60, TRA-1-81, Oct-3/4 and SSEA-4, and readily differentiate into ectoderm, mesoderm and endoderm. Importantly, the medium plays an integral role in establishing a cGMP-compliant process for the manufacturing of hiPSCs that can be used for generation of clinically relevant cell types for cell replacement therapy applications.

Published

2016

3. Cell specificity of adeno-associated virus (AAV) serotypes in human cortical organoids

Author

Morgan M. Stanton, Harsh N. Hariani, Jordan Sorokin, Patrick M. Taylor, Sara Modan, Brian G. Rash, Sneha B. Rao, Luigi Enriquez, Daphne Quang, Pei-Ken Hsu, Justin Paek, Dorah Owango, Carlos Castrillo, Justin Nicola, Pavan Ramkumar, Andy Lash, Douglas Flanzer, Kevan Shah, Saul Kato, and Gaia Skibinski

Abstract

Human-derived cortical organoids (hCOs) recapitulate cell diversity and 3D structure found in the human brain and offer a promising model for discovery of new gene therapies targeting neurological disorders. Adeno-associated viruses (AAVs) are the most promising vehicles for non-invasive gene delivery to the central nervous system (CNS), but reliable and reproduciblein vitromodels to assess their clinical potential are lacking. hCOs can take on these issues as they are a physiologically relevant model to assess AAV transduction efficiency, cellular tropism, and biodistribution within the tissue parenchyma, all of which could significantly modulate therapeutic efficacy. Here, we examine a variety of naturally occurring AAV serotypes and measure their ability to transduce neurons and glia in hCOs from multiple donors. We demonstrate cell tropism driven by AAV serotype and hCO donor and quantify fractions of neurons and astrocytes transduced with GFP as well as overall hCO health.

Published

2023

4. Neuroimmune cortical organoids overexpressing C4A exhibit multiple schizophrenia endophenotypes

Author

Morgan M. Stanton, Sara Modan, Patrick M. Taylor, Harsh N. Hariani, Jordan Sorokin, Brian G. Rash, Sneha B. Rao, Alejandro López-Tobón, Luigi Enriquez, Brenda Dang, Dorah Owango, Shannon O’Neill, Carlos Castrillo, Justin Nicola, Kathy Ye, Robert M. Blattner, Federico Gonzalez, Dexter Antonio, Pavan Ramkumar, Andy Lash, Douglas Flanzer, Sophia Bardehle, Stefka Gyoneva, Kevan Shah, Saul Kato, and Gaia Skibinski

Abstract

Elevated expression of the complement component 4A (C4A) protein has been linked to an increased risk of schizophrenia (SCZ). However, there are few human models available to study the mechanisms by which C4A contributes to the development of SCZ. In this study, we established a C4A overexpressing neuroimmune cortical organoid (NICO) model, which includes mature neuronal cells, astrocytes, and functional microglia. The C4A NICO model recapitulated several neuroimmune endophenotypes observed in SCZ patients, including modulation of inflammatory genes and increased cytokine secretion. C4A expression also increased microglia-mediated synaptic uptake in the NICO model, supporting the hypothesis that synapse and brain volume loss in SCZ patients may be due to excessive microglial pruning. Our results highlight the role of C4A in the immunogenetic risk factors for SCZ and provide a human model for phenotypic discovery and validation of immunomodulating therapies.

Published

2023

5. Superhuman cell death detection with biomarker-optimized neural networks

Author

Jeremy W. Linsley, Drew A. Linsley, Josh Lamstein, Gennadi Ryan, Kevan Shah, Nicholas A. Castello, Viral Oza, Jaslin Kalra, Shijie Wang, Zachary Tokuno, Ashkan Javaherian, Thomas Serre, and Steven Finkbeiner

Subjects

Multidisciplinary, SciAdv r-articles, Research Article, Neuroscience

Abstract

Description, High-throughput microscopy has outpaced analysis; biomarker-optimized CNNs are a generalizable, fast, and interpretable solution., Cellular events underlying neurodegenerative disease may be captured by longitudinal live microscopy of neurons. While the advent of robot-assisted microscopy has helped scale such efforts to high-throughput regimes with the statistical power to detect transient events, time-intensive human annotation is required. We addressed this fundamental limitation with biomarker-optimized convolutional neural networks (BO-CNNs): interpretable computer vision models trained directly on biosensor activity. We demonstrate the ability of BO-CNNs to detect cell death, which is typically measured by trained annotators. BO-CNNs detected cell death with superhuman accuracy and speed by learning to identify subcellular morphology associated with cell vitality, despite receiving no explicit supervision to rely on these features. These models also revealed an intranuclear morphology signal that is difficult to spot by eye and had not previously been linked to cell death, but that reliably indicates death. BO-CNNs are broadly useful for analyzing live microscopy and essential for interpreting high-throughput experiments.

Published

2021

6. Demuxalot: scaled up genetic demultiplexing for single-cell sequencing

Author

Alex Rogozhnikov, Pavan Ramkumar, Kevan Shah, Rishi Bedi, Saul Kato, and G. Sean Escola

Subjects

Single cell sequencing, Computer science, Small number, Genotype, Probabilistic logic, RNA, Inference, Computational biology, Allele, Multiplexing

Abstract

Demultiplexing methods have facilitated the widespread use of single-cell RNA sequencing (scRNAseq) experiments by lowering costs and reducing technical variations. Here, we present demuxalot: a method for probabilistic genotype inference from aligned reads, with no assumptions about allele ratios and efficient incorporation of prior genotype information from historical experiments in a multi-batch setting. Our method efficiently incorporates additional information across reads originating from the same transcript, enabling up to 3x more calls per read relative to naive approaches. We also propose a novel and highly performant tradeoff between methods that rely on reference genotypes and methods that learn variants from the data, by selecting a small number of highly informative variants that maximize the marginal information with respect to reference single nucleotide variants (SNVs). Our resulting improved SNV-based demultiplex method is up to 3x faster, 3x more data efficient, and achieves significantly more accurate doublet discrimination than previously published methods. This approach renders scRNAseq feasible for the kind of large multi-batch, multi-donor studies that are required to prosecute diseases with heterogeneous genetic backgrounds.

Published

2021

7. Optimization and scaling of patient-derived brain organoids uncovers deep phenotypes of disease

Author

Spencer Brown, Daniel Chao, Zhixiang Tong, Rishi Bedi, Justin Nicola, Anthony Batarse, Jordan M. Sorokin, Julia Bergamaschi, Kelly Li, Arden Piepho, Shiron Drusinsky, David Grayson, Austin McKay, Brenda Dang, Oliver Wueseke, Brian G. Rash, Matthew Schultz, Geffen Treiman, Carlos Castrillo, Alex Rogozhnikov, Pei-Ken Hsu, Andy Lash, Juliana Hilliard, Noah Young, Deborah Pascoe, Elliot Mount, Luigi Enriquez, Morgan M. Stanton, Patrick A. Taylor, G. Sean Escola, Saul Kato, Pavan Ramkumar, Ismael Oumzil, Cagsar Apaydin, Doug Flanzer, Kevan Shah, Jessica Sims, Robert Blattner, Gaia Skibinski, Justin Paek, Sean Poust, Alex Pollen, Daphne Quang, Ryan Jones, Chia-Yao Lee, Chili Johnson, and Anthony Bosshardt

Subjects

medicine.anatomical_structure, Human disease, Forebrain, Organoid, Clone (cell biology), medicine, Disease, Computational biology, Human brain, Biology, Phenotype

Abstract

Cerebral organoids provide unparalleled access to human brain development in vitro. However, variability induced by current culture methodologies precludes using organoids as robust disease models. To address this, we developed an automated Organoid Culture and Assay (ORCA) system to support longitudinal unbiased phenotyping of organoids at scale across multiple patient lines. We then characterized organoid variability using novel machine learning methods and found that the contribution of donor, clone, and batch is significant and remarkably consistent over gene expression, morphology, and cell-type composition. Next, we performed multi-factorial protocol optimization, producing a directed forebrain protocol compatible with 96-well culture that exhibits low variability while preserving tissue complexity. Finally, we used ORCA to study tuberous sclerosis, a disease with known genetics but poorly representative animal models. For the first time, we report highly reproducible early morphological and molecular signatures of disease in heterozygous TSC+/− forebrain organoids, demonstrating the benefit of a scaled organoid system for phenotype discovery in human disease models.

Published

2020

8. Super-human cell death detection with biomarker-optimized neural networks

Author

Jeremy W. Linsley, Ashkan Javaherian, Josh Lamstein, Viral Oza, Steven Finkbeiner, Gennadi Ryan, Zachary Tokuno, Drew Linsley, Shijie Wang, Thomas Serre, Kevan Shah, Jaslin Kalra, and Nicholas A. Castello

Subjects

Artificial neural network, Process (engineering), business.industry, Scale (chemistry), Artificial intelligence, Human cell, Machine learning, computer.software_genre, business, Convolutional neural network, computer, Imaging modalities, Biomarker (cell)

Abstract

Cell death is an essential process in biology that must be accounted for in live microscopy experiments. Nevertheless, cell death is difficult to detect without perturbing experiments with stains, dyes or biosensors that can bias experimental outcomes, lead to inconsistent results, and reduce the number of processes that can be simultaneously labelled. These additional steps also make live microscopy difficult to scale for high-throughput screening because of the cost, labor, and analysis they entail. We address this fundamental limitation of live microscopy with biomarker-optimized convolutional neural networks (BO-CNN): computer vision models trained with a ground truth biosensor that detect live cells with superhuman, 96% accuracy more than 100 times faster than previous methods. Our models learn to identify important morphological characteristics associated with cell vitality without human input or additional perturbations, and to generalize to other imaging modalities and cell types for which they have no specialized training. We demonstrate that we can interpret decisions from BO-CNN models to gain biological insight into the patterns they use to achieve superhuman accuracy. The BO-CNN approach is broadly useful for live microscopy, and affords a powerful new paradigm for advancing the state of high-throughput imaging in a variety of contexts.

Published

2020

9. Genetically encoded cell-death indicators (GEDI) to detect an early irreversible commitment to neurodegeneration

Author

Jeremy W. Linsley, Kevan Shah, Nicholas Castello, Michelle Chan, Dominic Haddad, Jay Mancini, Viral Oza, Shijie Wang, Ashkan Javaherian, David Kokel, and Steven Finkbeiner

Subjects

0303 health sciences, Programmed cell death, Neurodegeneration, Cell, Disease, Biology, medicine.disease, Death Indicator, Cell biology, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, Cell Death Process, medicine, Zebrafish larvae, 030217 neurology & neurosurgery, Intracellular, 030304 developmental biology

Abstract

Cell death is a critical process that occurs normally in health and disease. However, its study is limited due to available technologies that only detect very late stages in the process or specific death mechanisms. Here, we report the development of a new fluorescent biosensor called genetically encoded death indicator (GEDI). GEDI specifically detects an intracellular Ca2+ level that cells achieve early in the cell death process and marks a stage at which cells are irreversibly committed to die. The time-resolved nature of GEDI delineates a binary demarcation of cell life and death in real time, reformulating the definition of cell death. We demonstrate that GEDI acutely and accurately reports death of rodent and human neurons in vitro, and show GEDI enables a novel automated imaging platform for single cell detection of neuronal death in vivo in zebrafish larvae. With a quantitative pseudo-ratiometric signal, GEDI facilitates high-throughput analysis of cell death in time lapse imaging analysis, providing the necessary resolution and scale to identify early factors leading to cell death in studies of neurodegeneration.

Published

2019

10. Defining Long-Term Maintenance Conditions of Human Embryonic Stem Cells With Arrayed Cellular Microenvironment Technology

Author

David A. Brafman, Karl Willert, Shu Chien, Kevan Shah, and Thomas Fellner

Subjects

Cell signaling, Time Factors, Cell Culture Techniques, Biology, Cell Line, Extracellular matrix, Cellular Microenvironment, Humans, Embryonic Stem Cells, reproductive and urinary physiology, Cell Proliferation, Oligonucleotide Array Sequence Analysis, Extracellular Matrix Proteins, business.industry, Cell Differentiation, Long term maintenance, Cell Biology, Hematology, equipment and supplies, Embryonic stem cell, Biotechnology, Cell biology, Chemically defined medium, embryonic structures, biological phenomena, cell phenomena, and immunity, business, Developmental Biology

Abstract

The optimization of defined growth conditions is necessary for the development of clinical application of human embryonic stem cells (hESCs). Current research has focused on developing defined media formulations for long-term culture of hESCs with little attention on the establishment of defined substrates for hESC proliferation and self-renewal. Presently available technologies are insufficient to address the full complement of factors that may regulate hESC proliferation and maintenance of pluripotency. Here, we report the application of a multifactorial array technology to identify fully defined and optimized culture conditions for the proliferation of hESCs. Through the systematic screening of extracellular matrix proteins (ECMPs) and other signaling molecules, we developed and characterized a completely defined culture system for the long-term self-renewal of three independent hESC lines. In the future, the novel array platform and analysis procedure presented here will be applied toward the directed differentiation of hESCs and maintenance of other stem and progenitor cell populations.

Published

2009

11. Investigating the role of the extracellular environment in modulating hepatic stellate cell biology with arrayed combinatorial microenvironments

Author

Ekihiro Seki, Samuele De Minicis, Dayu Teng, David A. Brafman, Shu Chien, Kevan Shah, Karl Willert, and David A. Brenner

Subjects

Liver Cirrhosis, Extracellular Matrix Proteins, Mice, Inbred BALB C, Cell signaling, Microscopy, Confocal, Liver cytology, Protein Array Analysis, Biophysics, Wnt signaling pathway, Mice, Transgenic, Biology, Biochemistry, Cell biology, Wnt Proteins, Mice, Crosstalk (biology), Liver, Hepatic Stellate Cells, Extracellular, Hepatic stellate cell, Animals, Cellular microarray, Signal transduction, Signal Transduction

Abstract

Hepatic stellate cells (HSCs) are a major cell type of the liver that are involved in liver homeostasis. Upon liver damage, HSCs exit their normally quiescent state and become activated, leading to an increase of their proliferation, production of abnormal extracellular matrix proteins (ECMPs) and inflammatory mediators, and eventually liver fibrosis and cirrhosis. Current in vitro approaches to identify components that influence HSC biology typically investigate one factor at a time and generally ignore the complex crosstalk among the myriad of components that comprise the microenvironments of quiescent or activated HSCs. Here we describe a high throughput screening (HTS) approach to identify factors that affect HSC biology. Specifically, we integrated the use of ECMPs and signaling molecules into a combinatorial cellular microarray technology platform, thereby creating comprehensive "microenvironments". Using this technology, we performed real-time simultaneous screening of the effects of hundreds of unique microenvironments composed of ECMPs and signaling molecules on HSC proliferation and activation. From these screens, we identified combinations of microenvironment components that differentially modulate the HSC phenotype. Furthermore, analysis of HSC responses revealed that the influences of Wnt signaling molecules on HSC fate are dependent on the ECMP composition in which they are presented. Collectively, our results demonstrate the utility of high-content, array-based screens to provide a better understanding of HSC biology. Our results indicate that array-based screens may provide an efficient means for identifying candidate signaling pathways to be targeted for anti-fibrotic therapies.

Published

2009