High-throughput screening of tyrosine kinase inhibitor cardiotoxicity with human induced pluripotent stem cells

Sharma, Arun; Burridge, Paul W.; McKeithan, Wesley L.; Serrano, Ricardo; Shukla, Praveen; Sayed, Nazish; Churko, Jared M.; Kitani, Tomoya; Wu, Haodi; Holmström, Alexandra; Matsa, Elena; Zhang, Yuan; Kumar, Anusha; Fan, Alice C.; Álamo, Juan C. del; Wu, Sean M.; Moslehi, Javid; Mercola, Mark

doi:10.1126/scitranslmed.aaf2584

Cited by 313 publications

(288 citation statements)

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“…The potential exists to correlate drug dosing and plasma concentrations with cardiotoxic and myopathic risk. Recent studies suggest that iPSC-cardiomyocytes can reveal cardiotoxicities manifesting as alterations in cardiomyocyte viability, contractility, intracellular signaling and gene expression [127, 128]. As above, however, there is great need for validation, especially considering that many anti-cancer drugs elicit their cardiac effects by affecting mitochondrial function [129, 130] and that iPSC-cardiomyocytes are metabolically immature [131].…”

Section: Modeling Cardiotoxicitymentioning

confidence: 99%

High throughput physiological screening of iPSC-derived cardiomyocytes for drug development

Álamo

Lemons

Serrano

et al. 2016

Biochimica et Biophysica Acta (BBA) - Molecular Cell Research

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101

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Cardiac drug discovery is hampered by the reliance on non-human animal and cellular models with inadequate throughput and physiological fidelity to accurately identify new targets and test novel therapeutic strategies. Similarly, adverse drug effects on the heart are challenging to model, contributing to costly failure of drugs during development and even after market launch. Human induced pluripotent stem cell derived cardiac tissue represents a potentially powerful means to model aspects of heart physiology relevant to disease and adverse drug effects, providing both the human context and throughput needed to improve the efficiency of drug development. Here we review emerging technologies for high throughput measurements of cardiomyocyte physiology, and comment on the promises and challenges of using iPSC-derived cardiomyocytes to model disease and introduce the human context into early stages of drug discovery.

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Section: Modeling Cardiotoxicitymentioning

confidence: 99%

High throughput physiological screening of iPSC-derived cardiomyocytes for drug development

Álamo

Lemons

Serrano

et al. 2016

Biochimica et Biophysica Acta (BBA) - Molecular Cell Research

Self Cite

101

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“…Culturing such CMs is of great interest not only because of their applications in cell therapy but also owing to their considerable potential in the patient-specific study of heart disease 64,65 . Human-iPSCs (hiPSCs) have created unique opportunities in cardiology; specifically, CMs differentiated from these stem cells have excellent potential in the study of heart disease and can model patient-specific myocardial physiology in vitro 47,66,67 . However, the substantial structural and functional differences between hiPSC/MSC-derived CMs (derived from existing chemically defined approaches) and adult mature CMs pose major challenges for precise drug screening and highly efficient therapeutic applications 65,68–71 .…”

Section: Cell Therapy For Salvage and Regeneration Of Heart Tissuementioning

confidence: 99%

Multiscale technologies for treatment of ischemic cardiomyopathy

et al. 2017

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The adult mammalian heart possesses only limited capacity for innate regeneration and the response to severe injury is dominated by the formation of scar tissue. Current therapy to replace damaged cardiac tissue is limited to cardiac transplantation and thus many patients suffer progressive decay in the heart’s pumping capacity to the point of heart failure. Nanostructured systems have the potential to revolutionize both preventive and therapeutic approaches for treating cardiovascular disease. Here, we outline recent advancements in nanotechnology that could be exploited to overcome the major obstacles in the prevention of and therapy for heart disease. We also discuss emerging trends in nanotechnology affecting the cardiovascular field that may offer new hope for patients suffering massive heart attacks.

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“…Although cardiovascular pharmacology has traditionally not been well-suited for high throughput studies, the development of hiPSC-CMs has expanded the possibilities. For instance, a recent study described the development of a comprehensive assay that evaluated cellular effects of TKIs in hiPSC-CMs (Sharma et al, 2017). Using hiPSC lines from 13 individuals, the investigators examined how 21 FDA-approved small molecule TKIs affected cell viability, contractility, and gene expression.…”

Section: Complexities Of Tki-induced Cardiotoxicity and The Need Formentioning

confidence: 99%

“…Using hiPSC lines from 13 individuals, the investigators examined how 21 FDA-approved small molecule TKIs affected cell viability, contractility, and gene expression. By integrating the results with literature-reported TKI serum levels in patients, the authors developed a novel cardiac safety index for TKIs (Sharma et al, 2017).…”

Section: Complexities Of Tki-induced Cardiotoxicity and The Need Formentioning

confidence: 99%

“…As noted above, an important recent study by Sharma et al (2017) derived a "toxicity index" by examining effects of TKIs in hiPSC-CMs through several assays. Although the large-scale nature of this study justifies the "systems" label, and the toxicity index is a quantitative risk score, it's important to emphasize that QSP modeling, which can provide mechanistic insight and actionable predictions, is complementary to a high-throughput, data-driven strategy such as that used in this study (Sharma et al, 2017).…”

Section: Initial Efforts To Use Qsp Approaches To Understand Tki-indumentioning

confidence: 99%

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Mechanistic Systems Modeling to Improve Understanding and Prediction of Cardiotoxicity Caused by Targeted Cancer Therapeutics

Shim

2018

Biophysical Journal

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Tyrosine kinase inhibitors (TKIs) are highly potent cancer therapeutics that have been linked with serious cardiotoxicity, including left ventricular dysfunction, heart failure, and QT prolongation. TKI-induced cardiotoxicity is thought to result from interference with tyrosine kinase activity in cardiomyocytes, where these signaling pathways help to control critical processes such as survival signaling, energy homeostasis, and excitation-contraction coupling. However, mechanistic understanding is limited at present due to the complexities of tyrosine kinase signaling, and the wide range of targets inhibited by TKIs. Here, we review the use of TKIs in cancer and the cardiotoxicities that have been reported, discuss potential mechanisms underlying cardiotoxicity, and describe recent progress in achieving a more systematic understanding of cardiotoxicity via the use of mechanistic models. In particular, we argue that future advances are likely to be enabled by studies that combine large-scale experimental measurements with Quantitative Systems Pharmacology (QSP) models describing biological mechanisms and dynamics. As such approaches have proven extremely valuable for understanding and predicting other drug toxicities, it is likely that QSP modeling can be successfully applied to cardiotoxicity induced by TKIs. We conclude by discussing a potential strategy for integrating genome-wide expression measurements with models, illustrate initial advances in applying this approach to cardiotoxicity, and describe challenges that must be overcome to truly develop a mechanistic and systematic understanding of cardiotoxicity caused by TKIs.

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High-throughput screening of tyrosine kinase inhibitor cardiotoxicity with human induced pluripotent stem cells

Cited by 313 publications

References 50 publications

High throughput physiological screening of iPSC-derived cardiomyocytes for drug development

High throughput physiological screening of iPSC-derived cardiomyocytes for drug development

Multiscale technologies for treatment of ischemic cardiomyopathy

Mechanistic Systems Modeling to Improve Understanding and Prediction of Cardiotoxicity Caused by Targeted Cancer Therapeutics

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