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iPSC-CM Platform for Drug-induced Contractility Assessment

This project aims to develop an iPSC-CM platform to assess drug-induced contractility liabilities. It will utilize advances in material science and bio-engineering to create a pliable substrate that allows cardiomyocytes to mature and demonstrate relevant physiology and pharmacology. The goal is to enable a medium-throughput screen for simultaneous contractility and electrophysiological changes.

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iPSC-CM Platform for Drug-induced Contractility Assessment

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  1. InPulse: Development of an iPSCcardiomyocyte (iPSC-CM) platform to assess drug-induced contractility liabilities. Sponsors: Arun Sridhar, Peter J. Clements, Brian Berridge,

  2. Drug induced contractility change – a balancing act! • Contractility assessment in drug discovery and development for: • Primary & Secondary pharmacology screening paradigms • Hazard management: e.g. inclusion of relevant patient population or additional monitoring in clinical trials • Regulatory implications: Black-box warnings Places long term stress on the heart Reduced perfusion to end-organs Contractility Slower, costly development with implications on patient health

  3. State of contractility assays in discovery and safety • Discovery: • Ligand binding • Mechanism based molecular reporters. • Isolated myocyte contractility • In vitro langendorff • In vivo cardiac output and hemodynamic assessments. • Echocardiography • Preclinical safety: • Early indicators of off-target activity at GPCR’s and calcium channels affecting contractility • Isolated adult myocyte measurements • Tissue preparations • Single dose in vivo CV study (first to assess ECG and blood pressure) • Follow up repeat dose CV parameters – limited measures of contractility • Cardiac output and mechanistic studies are undertaken only if signals are found in one or more assays. (Current measurements in routine screening is indirect or resource-, time- consuming with heavy reliance on animals) (Must cater to all drug classes irrespective of therapeutic area!). (Restricted to cardiovascular drug discovery, rarely beyond!).

  4. Evidence of drugs from various therapeutic classes altering cardiac contractile function Potential role of off-target effects in mediating cardiotoxicity of multi-targeted tyrosine kinase inhibithors Nature Reviews Cancer 7, 332-344 (May 2007)

  5. Safety Related Attrition

  6. Why are contractility changes important in drug safety screening? Nature Reviews Drug Discovery 11, 751-761 (October 2012)

  7. Why are the current stem cell screens inadequate? • Heavily focussed on electrophysiology! • Immature, neonatal phenotype with poorly developed architecture and physiology . • Impedence changes ≠ electrophysiology and contractility changes • Currently, electrophysiology, calcium and contractility are all done in separate assays – not a good use of animals and time! • Current methods (using rigid substrates – PDMS based polymers) deliver isometric contraction. A cardiac myocyte contraction is both isometric and isotonic • Cells mature and demonstrate striations, but are not bulked up in volume to aid 2-D cell shortening measurements.

  8. The Challenge • Vision (What we seek to achieve): • Create an assay for stem cell based contractility assay with mature adult-like population grown on an engineered substrate that demonstrates relevant physiology & pharmacology to enable discovery and safety screening of drug induced changes in contractility. • How: • Marry advances in material science/bio-engineering with physiology to deliver a pliable substrate to drive cardiomyocyte maturation. • Re-capitulate ventricular stress-strain relationships on extracellular substrate’s tensile strength (changes in polymerization of the substrate). • Actively contracting iPSC-CMs attached to this substrate will mature based on the load it perceives and develop striations and increased cell volume. • Alterations of load (e.g: by changes in polymerization) will provide normal vs. disease (e.g: hypertrophy) phenotypes to aid comparison. • Validate with demonstrable physiology (as outlined) and pharmacology • Enable a medium throughput screen (as non-invasive as possible) for simultaneous contractility and electrophysiological changes.

  9. Framework for comparison

  10. Back up slides

  11. Caveat to be remembered The translatable endpoint that is available between pre-clinical and clinical studies for assessment of contractility liabilities is reduction in fractional shorterning or ejection fraction, as assessed by echocardiography. Advantages: • Non-invasive • Cheaper and easily tolerated in clinical trials in an outpatient and inpatient setting. • Can be pursued in repeat dose setting Every other measurement from pre-clinical studies are mere indicators to potential changes in ejection fraction in vivo (acutely) Primary Purpose:Hazard Detection in early pre-candidate screening Potential 3R’s benefit: The proposed challenge will be a first step to make a potential paradigm change for preclinical assessment of contractility early in discovery and safety screening.

  12. iPSC-CM phenotype Biomaterials. 2013 Mar;34(10):2399-411.

  13. Why Impedence changes are indirect and rarely accurate? Action Potential Ca2+ transient Impedance readout from Xcelligence Cardio system An impedance based system will not distinguish an electrical phenomenon (AP prolongation vs. EADs) and Ca2+ transient abnormalities Pharmacology & Therapeutics Volume 119, Issue 2 2008 179 - 185

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