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A current understanding of drug-induced QT prolongation and its implications for anticancer therapy

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Zeitschriftentitel: Cardiovascular Research
Personen und Körperschaften: Roden, Dan M
In: Cardiovascular Research, 115, 2019, 5, S. 895-903
Format: E-Article
Sprache: Englisch
veröffentlicht:
Oxford University Press (OUP)
Schlagwörter:
Physiology (medical)
Cardiology and Cardiovascular Medicine
Physiology
author_facet Roden, Dan M
Roden, Dan M
author Roden, Dan M
spellingShingle Roden, Dan M
Cardiovascular Research
A current understanding of drug-induced QT prolongation and its implications for anticancer therapy
Physiology (medical)
Cardiology and Cardiovascular Medicine
Physiology
author_sort roden, dan m
spelling Roden, Dan M 0008-6363 1755-3245 Oxford University Press (OUP) Physiology (medical) Cardiology and Cardiovascular Medicine Physiology http://dx.doi.org/10.1093/cvr/cvz013 <jats:title>Abstract</jats:title> <jats:p>The QT interval, a global index of ventricular repolarization, varies among individuals and is influenced by diverse physiologic and pathophysiologic stimuli such as gender, age, heart rate, electrolyte concentrations, concomitant cardiac disease, and other diseases such as diabetes. Many drugs produce a small but reproducible effect on QT interval but in rare instances this is exaggerated and marked QT prolongation can provoke the polymorphic ventricular tachycardia ‘torsades de pointes’, which can cause syncope or sudden cardiac death. The generally accepted common mechanism whereby drugs prolong QT is block of a key repolarizing potassium current in heart, IKr, generated by expression of KCNH2, also known as HERG. Thus, evaluation of the potential that a new drug entity may cause torsades de pointes has relied on exposure of normal volunteers or patients to drug at usual and high concentrations, and on assessment of IKr block in vitro. More recent work, focusing on anticancer drugs with QT prolonging liability, is defining new pathways whereby drugs can prolong QT. Notably, the in vitro effects of some tyrosine kinase inhibitors to prolong cardiac action potentials (the cellular correlate of QT) can be rescued by intracellular phosphatidylinositol 3,4,5-trisphosphate, the downstream effector of phosphoinositide 3-kinase. This finding supports a role for inhibition of this enzyme, either directly or by inhibition of upstream kinases, to prolong QT through mechanisms that are being worked out, but include enhanced inward ‘late’ sodium current during the plateau of the action potential. The definition of non-IKr-dependent pathways to QT prolongation will be important for assessing risk, not only with anticancer therapies but also with other QT prolonging drugs and for generating a refined understanding how variable activity of intracellular signalling systems can modulate QT and associated arrhythmia risk.</jats:p> A current understanding of drug-induced QT prolongation and its implications for anticancer therapy Cardiovascular Research
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title A current understanding of drug-induced QT prolongation and its implications for anticancer therapy
title_unstemmed A current understanding of drug-induced QT prolongation and its implications for anticancer therapy
title_full A current understanding of drug-induced QT prolongation and its implications for anticancer therapy
title_fullStr A current understanding of drug-induced QT prolongation and its implications for anticancer therapy
title_full_unstemmed A current understanding of drug-induced QT prolongation and its implications for anticancer therapy
title_short A current understanding of drug-induced QT prolongation and its implications for anticancer therapy
title_sort a current understanding of drug-induced qt prolongation and its implications for anticancer therapy
topic Physiology (medical)
Cardiology and Cardiovascular Medicine
Physiology
url http://dx.doi.org/10.1093/cvr/cvz013
publishDate 2019
physical 895-903
description <jats:title>Abstract</jats:title> <jats:p>The QT interval, a global index of ventricular repolarization, varies among individuals and is influenced by diverse physiologic and pathophysiologic stimuli such as gender, age, heart rate, electrolyte concentrations, concomitant cardiac disease, and other diseases such as diabetes. Many drugs produce a small but reproducible effect on QT interval but in rare instances this is exaggerated and marked QT prolongation can provoke the polymorphic ventricular tachycardia ‘torsades de pointes’, which can cause syncope or sudden cardiac death. The generally accepted common mechanism whereby drugs prolong QT is block of a key repolarizing potassium current in heart, IKr, generated by expression of KCNH2, also known as HERG. Thus, evaluation of the potential that a new drug entity may cause torsades de pointes has relied on exposure of normal volunteers or patients to drug at usual and high concentrations, and on assessment of IKr block in vitro. More recent work, focusing on anticancer drugs with QT prolonging liability, is defining new pathways whereby drugs can prolong QT. Notably, the in vitro effects of some tyrosine kinase inhibitors to prolong cardiac action potentials (the cellular correlate of QT) can be rescued by intracellular phosphatidylinositol 3,4,5-trisphosphate, the downstream effector of phosphoinositide 3-kinase. This finding supports a role for inhibition of this enzyme, either directly or by inhibition of upstream kinases, to prolong QT through mechanisms that are being worked out, but include enhanced inward ‘late’ sodium current during the plateau of the action potential. The definition of non-IKr-dependent pathways to QT prolongation will be important for assessing risk, not only with anticancer therapies but also with other QT prolonging drugs and for generating a refined understanding how variable activity of intracellular signalling systems can modulate QT and associated arrhythmia risk.</jats:p>
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author_sort roden, dan m
container_issue 5
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description <jats:title>Abstract</jats:title> <jats:p>The QT interval, a global index of ventricular repolarization, varies among individuals and is influenced by diverse physiologic and pathophysiologic stimuli such as gender, age, heart rate, electrolyte concentrations, concomitant cardiac disease, and other diseases such as diabetes. Many drugs produce a small but reproducible effect on QT interval but in rare instances this is exaggerated and marked QT prolongation can provoke the polymorphic ventricular tachycardia ‘torsades de pointes’, which can cause syncope or sudden cardiac death. The generally accepted common mechanism whereby drugs prolong QT is block of a key repolarizing potassium current in heart, IKr, generated by expression of KCNH2, also known as HERG. Thus, evaluation of the potential that a new drug entity may cause torsades de pointes has relied on exposure of normal volunteers or patients to drug at usual and high concentrations, and on assessment of IKr block in vitro. More recent work, focusing on anticancer drugs with QT prolonging liability, is defining new pathways whereby drugs can prolong QT. Notably, the in vitro effects of some tyrosine kinase inhibitors to prolong cardiac action potentials (the cellular correlate of QT) can be rescued by intracellular phosphatidylinositol 3,4,5-trisphosphate, the downstream effector of phosphoinositide 3-kinase. This finding supports a role for inhibition of this enzyme, either directly or by inhibition of upstream kinases, to prolong QT through mechanisms that are being worked out, but include enhanced inward ‘late’ sodium current during the plateau of the action potential. The definition of non-IKr-dependent pathways to QT prolongation will be important for assessing risk, not only with anticancer therapies but also with other QT prolonging drugs and for generating a refined understanding how variable activity of intracellular signalling systems can modulate QT and associated arrhythmia risk.</jats:p>
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spelling Roden, Dan M 0008-6363 1755-3245 Oxford University Press (OUP) Physiology (medical) Cardiology and Cardiovascular Medicine Physiology http://dx.doi.org/10.1093/cvr/cvz013 <jats:title>Abstract</jats:title> <jats:p>The QT interval, a global index of ventricular repolarization, varies among individuals and is influenced by diverse physiologic and pathophysiologic stimuli such as gender, age, heart rate, electrolyte concentrations, concomitant cardiac disease, and other diseases such as diabetes. Many drugs produce a small but reproducible effect on QT interval but in rare instances this is exaggerated and marked QT prolongation can provoke the polymorphic ventricular tachycardia ‘torsades de pointes’, which can cause syncope or sudden cardiac death. The generally accepted common mechanism whereby drugs prolong QT is block of a key repolarizing potassium current in heart, IKr, generated by expression of KCNH2, also known as HERG. Thus, evaluation of the potential that a new drug entity may cause torsades de pointes has relied on exposure of normal volunteers or patients to drug at usual and high concentrations, and on assessment of IKr block in vitro. More recent work, focusing on anticancer drugs with QT prolonging liability, is defining new pathways whereby drugs can prolong QT. Notably, the in vitro effects of some tyrosine kinase inhibitors to prolong cardiac action potentials (the cellular correlate of QT) can be rescued by intracellular phosphatidylinositol 3,4,5-trisphosphate, the downstream effector of phosphoinositide 3-kinase. This finding supports a role for inhibition of this enzyme, either directly or by inhibition of upstream kinases, to prolong QT through mechanisms that are being worked out, but include enhanced inward ‘late’ sodium current during the plateau of the action potential. The definition of non-IKr-dependent pathways to QT prolongation will be important for assessing risk, not only with anticancer therapies but also with other QT prolonging drugs and for generating a refined understanding how variable activity of intracellular signalling systems can modulate QT and associated arrhythmia risk.</jats:p> A current understanding of drug-induced QT prolongation and its implications for anticancer therapy Cardiovascular Research
spellingShingle Roden, Dan M, Cardiovascular Research, A current understanding of drug-induced QT prolongation and its implications for anticancer therapy, Physiology (medical), Cardiology and Cardiovascular Medicine, Physiology
title A current understanding of drug-induced QT prolongation and its implications for anticancer therapy
title_full A current understanding of drug-induced QT prolongation and its implications for anticancer therapy
title_fullStr A current understanding of drug-induced QT prolongation and its implications for anticancer therapy
title_full_unstemmed A current understanding of drug-induced QT prolongation and its implications for anticancer therapy
title_short A current understanding of drug-induced QT prolongation and its implications for anticancer therapy
title_sort a current understanding of drug-induced qt prolongation and its implications for anticancer therapy
title_unstemmed A current understanding of drug-induced QT prolongation and its implications for anticancer therapy
topic Physiology (medical), Cardiology and Cardiovascular Medicine, Physiology
url http://dx.doi.org/10.1093/cvr/cvz013