European Heart Journal

European Heart Journal Advance Access originally published online on July 5, 2007
European Heart Journal 2007 28(15):1904-1909; doi:10.1093/eurheartj/ehm209

This Article Abstract FREE Full Text (PDF) All Versions of this Article: 28/15/1904    most recent ehm209v1 E-letters: Submit a response Alert me when this article is cited Alert me when E-letters are posted Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in ISI Web of Science Similar articles in PubMed Alert me to new issues of the journal Add to My Personal Archive Download to citation manager Request Permissions Disclaimer Google Scholar Articles by Borer, J. S. Articles by Zannad, F. Search for Related Content PubMed PubMed Citation Articles by Borer, J. S. Articles by Zannad, F. Social Bookmarking          What's this?

© The European Society of Cardiology 2007. All rights reserved. For Permissions, please e-mail: journals.permissions@oxfordjournals.org

Cardiovascular safety of drugs not intended for cardiovascular use: need for a new conceptual basis for assessment and approval

Jeffrey S. Borer^1,*, Hubert Pouleur², Eric Abadie³, Ferrenc Follath⁴, Janet Wittes⁵, Marc A. Pfeffer⁶, Bertram Pitt⁷ and Faiez Zannad⁸

¹ Division of Cardiovascular Pathophysiology, Weill Medical College of Cornell University, 47 East 88th Street, New York, NY 10128-1152, USA
² Pfizer, Inc., New York, NY, USA
³ AFSSAPS, Paris, France
⁴ University Hospital, Zurich, Switzerland
⁵ Statistics Collaborative, Washington DC, USA
⁶ Brigham and Women's Hospital, Boston, MA, USA
⁷ University of Michigan, Ann Arbor, MI, USA
⁸ Hypertension and Preventive Cardiology Division, Department of Cardiovascular disease, Centre d'Investigations Cliniques INSERM-CHU, INSERM U684, Nancy, France

Received 4 December 2006; revised 24 April 2007; accepted 3 May 2007; online publish-ahead-of-print 5 July 2007.

^* Corresponding author. Tel: +1 212 746 4646; fax: +1 212 426 4353. E-mail address: canadad45{at}aol.com

	Abstract

Top Abstract Introduction Background Classification of cardiovascular... Surrogate measures of risk Timing of risk assessment Acceptable mechanisms to... Regulatory impediments to post... Other considerations Conclusion Appendix References

 
Recently, several drugs for non-cardiovascular diseases have ceased marketing because of cardiovascular risk, highlighting the importance of evaluating the cardiovascular safety of new drugs even if not intended for cardiovascular diseases. Assessing and ensuring acceptable cardiovascular safety of non-cardiovascular drugs is difficult; nonetheless, governmental regulatory agencies are likely to change the requirements for drug safety information. This article explores our recommendations for rethinking current regulatory policies, emphasizing the need for mandatory post-marketing surveillance registries and highlighting the exposures necessary to subserve the need for greater assessment of safety issues.

Key Words: Cardiovascular diseases • Safety • Drug evaluation

	Introduction

Top Abstract Introduction Background Classification of cardiovascular... Surrogate measures of risk Timing of risk assessment Acceptable mechanisms to... Regulatory impediments to post... Other considerations Conclusion Appendix References

 
All drugs have multiple pharmacological actions, some beneficial and some detrimental. The perceived relation between benefit and risk, defined from pre-approval studies, forms the basis for drug approval and drug use. Pre-approval requirements must enable (i) delivery of effective and acceptably safe therapy to the public as quickly as is reasonable, (ii) information for prescribers sufficient to assure administration plans that will maximize benefit and minimize risk, and (iii) fairness to drug manufacturers to maintain incentives for drug development. The resulting process yields a body of information that, at drug approval, is unlikely to define all clinically important risks associated with drug use, especially those involving rare events that are difficult to detect after the relatively modest mandatory pre-approval drug exposure but may appear when a drug is in widespread clinical use. Indeed, pharmacological actions of a single drug can differ among functionally different organ systems; benefit for non-cardiovascular targets may be associated with cardiovascular adversity. However, cardiovascular testing is not a major focus of evaluation and development of non-cardiovascular drugs. Consequently, at approval, the relation between non-cardiovascular benefit and cardiovascular risk may not be adequately defined.

Deficiencies of pre-approval data are exemplified by issues emerging from the withdrawal of two non-steroidal anti-inflammatory drugs (NSAIDs), both cyclo-oxygenase (COX)-2 selective.^1–4 These actions followed several publications associating NSAIDs with cardiovascular event rates higher than observed among non-drug users, and highlighting the effects of COX-2 selective agents, the most recently approved members of this drug group.^5–11 These deficiencies are difficult to remedy within current regulatory algorithms, which create barriers to detecting relatively uncommon adverse events before approval. The problem is illustrated in Table 1, with absolute event rates taken from the Adenoma Prevention with Celecoxib (APC) trial (n = 2035 patients). A clear relative risk gradient was apparent between placebo and the two doses of celecoxib. However, the number of patients employed in this post-approval trial exceeded the total required patient exposure needed to meet pre-approval regulatory requirements. Current laws do not permit regulatory agencies to mandate such post-approval studies; current regulations limit mandatory pre-approval exposure to limit unfair development costs in the absence of a compelling evidentiary basis (see in what follows). Given the relatively modest absolute risks observed in APC, an a priori commitment from the manufacturer (revocable at any time under current laws) would have been needed to assure a post-approval trial with power adequate for likely detection of the relative risks actually observed. Thus, it is fair to question whether we need a new conceptual basis for assessment and approval. This article provides some responsive suggestions, developed at a meeting of cardiovascular clinical trialists, biostatisticians, FDA and European Medicines Agency (EMEA) regulators, representatives of the National Institutes of Health (NIH), and pharmaceutical industry scientists in Versailles, France, in December 2005.

View this table: [in this window] [in a new window]   Table 1 Sample sizes [as a function of power (type II error)] to detect cardiovascular risk in a randomized, controlled clinical trial, assuming risk in the placebo group is 0.33%/year, and each participant is followed for 1 year (two groups, equal n/group, type I error = 0.05; two-tailed test)31

 

	Background

Top Abstract Introduction Background Classification of cardiovascular... Surrogate measures of risk Timing of risk assessment Acceptable mechanisms to... Regulatory impediments to post... Other considerations Conclusion Appendix References

 
The NSAIDs are not the first drugs for non-cardiovascular targets evidencing unexpected cardiovascular risk after market release. For example, in 1997, fenfluramine and dexfenfluramine were withdrawn when data suggested they could cause cardiac valvular disease.^12–16 The following year, terfenadine was withdrawn because of association with fatal cardiac arrhythmias when it was administered with cytochrome p450 enzyme system inhibitors;^17,18 2 years later, cisapride was withdrawn upon reports of cardiac arrhythmias and deaths.¹⁹

Thus, new approaches are needed to document cardiovascular effects of new pharmacological agents not intended for cardiovascular targets. However, potential pathophysiological links may not be evident between cardiovascular events and drugs prescribed for non-cardiac conditions, particularly when clinical trials for the primary disease targets are short-term or if the relevant populations already are at risk for cardiovascular disease because of age, systemic inflammatory diseases, or other conditions. Even in the pre-approval period, detection of cardiovascular events during rigorous clinical trials of ‘non-cardiovascular’ drugs generally relies on spontaneous reporting of adverse events by investigators not trained in cardiology, who may not recognize subtle cardiovascular complaints. Most importantly, as noted earlier, pre-approval patient exposure requirements provide scant statistical power to detect differences in rates of infrequent events between the new drug and comparators, especially if pre-treatment cardiovascular risk is low. In the absence of organized trials, post-approval detection depends on spontaneous cardiac event reporting by practitioners (largely non-cardiologists), a notoriously insensitive and inefficient approach.

Because of these considerations and experiences, the United States Food and Drug Administration (FDA) is likely to change its process for evaluating drug safety.²⁰ Optimally, such change should define the type and magnitude of cardiovascular risks that must be detected before marketing to adequately protect public health. If pre-approval studies can assure that these important adverse events occur at less than a pre-specified rate, further information may not be necessary prior to approval,²¹ though post-approval data enhancement may be useful. Concomitantly, the scientific rigor required to establish the association between a new drug and cardiovascular risk must be established, i.e. when must the relevant data come from prospective, randomized clinical trials, when will registries (voluntary inclusion or mandated consecutive patient series) suffice, and when will retrospective prescription-based data sets be adequate.

	Classification of cardiovascular risk

Top Abstract Introduction Background Classification of cardiovascular... Surrogate measures of risk Timing of risk assessment Acceptable mechanisms to... Regulatory impediments to post... Other considerations Conclusion Appendix References

 
The drug development process aims to define the benefits and risks of an investigational agent for a specific population. Results may be skewed by patient selection criteria in pre-approval clinical trials, which generally are designed to eliminate characteristics that might confound interpretation of the primary study outcome, e.g. childhood or advanced age, pregnancy, or patients with various comorbidities (thus optimizing likelihood of observing a drug effect if it exists). The resulting cohort can differ importantly from the population that will receive the drug after approval. In addition, the duration of observation in clinical trials commonly is shorter than the prolonged exposure in clinical settings. Regulatory agencies often require trial durations in part based on the presumption that, since spontaneous reports of major problems in long-term use generally have been rare in the past, mandatory prolongation of trials is not needed. However, as earlier, recent experience belies this presumption.

Prolonging pre-approval trials or increasing sample sizes to detect rare events during a relatively short interval have potentially important drawbacks. The costs of trials can increase dramatically with duration. However, patent life, the basis upon which drug manufacturers can recoup their development costs, is relatively short. Increasing the size of study cohorts may maintain study duration but also is associated with increasing costs of patient evaluation and of accelerated recruitment. Consequently, decisions to prolong and/or enlarge pre-approval trials to detect relatively infrequent potential adverse effects must be based on a clear determination of the importance to the public health of the increment in information that can be obtained, based on such factors as the number of patients likely to use the drug after approval, the potential for use in high-risk populations, and the biological plausibility of cardiovascular risks.

There is general consensus on the nature of major cardiovascular risks. These comprise three broad categories: cardiovascular death or major irreversible morbidity (e.g. non-fatal MI and stroke); debilitating but reversible cardiovascular symptoms or events (e.g. fluid retention sufficient to cause dyspnoea, palpitations, lightheadedness, syncope due to non-lethal arrhythmias, angina, transient ischaemic attacks); and pathophysiological characteristics that increase the likelihood of cardiovascular adverse events (e.g. hypertension, accelerated thrombogenesis, asymptomatic arrhythmogenesis).^22–24

	Surrogate measures of risk

Top Abstract Introduction Background Classification of cardiovascular... Surrogate measures of risk Timing of risk assessment Acceptable mechanisms to... Regulatory impediments to post... Other considerations Conclusion Appendix References

 
Cardiovascular events can be determined only by direct clinical observation. However, potentially important pathophysiological changes can be measured objectively to predict events. The appropriateness of such pathophysiological surrogates for determining cardiovascular benefit is controversial. At present, for example, the FDA accepts only blood pressure reduction in hypertensive patients and LDL reduction in hypercholesterolemic patients as surrogates for cardiovascular clinical benefit. In assessing adverse effects, however, greater latitude is accepted. For example, both the FDA and the EMEA mandate measurement of the electrocardiographic QT interval during drug development, expecting that its substantial increase predicts potentially lethal arrhythmia. The International Conference of Harmonisation (ICH) documents E14 and S7B emphasize the need for thorough assessments of the QT interval during preclinical and clinical testing,^25–27 supported by in vivo cardiovascular safety studies and in vitro electrophysiological studies, and generally to include a dedicated study specifically to assess drug effect on cardiac repolarization.^26,28 Inferences concerning adverse events from such data can be overcome only with trials that measure clinical events directly.

Nonetheless, surrogates are imperfect predictors of adversity. For example, most drugs associated in humans with the potentially lethal arrhythmia, torsades de pointes (TdP), inhibit the rapidly activating delayed rectifier potassium current in myocardial tissues. In vivo or in vitro studies that identify this activity may be useful for determining the potential for drug-induced TdP; however, not all drugs that cause QT prolongation act through the delayed rectifier, and not all will result in TdP.²⁹ Also, clinically important QT abnormalities may not be apparent pre-approval, even though they may occur in some patients after marketing, possibly due to unpredictable drug–drug interactions that emerge only with multiple drug therapies that were precluded in pre-approval trials.

Safety surrogates may indicate risk that may not be actuated in all patients. Nonetheless, even an incompletely predictive surrogate may preclude approval if other therapies can provide acceptable benefit without the risk of concern. On the other hand, even a moderate risk might be acceptable if relatively greater benefit is perceived, though approval on this basis should lead to well-designed post-marketing studies to evaluate mortality and major morbidity. Thus, safety surrogates must be assessed case by case, and structured post-approval monitoring is irreplaceable for complete assessment of drug safety.

	Timing of risk assessment

Top Abstract Introduction Background Classification of cardiovascular... Surrogate measures of risk Timing of risk assessment Acceptable mechanisms to... Regulatory impediments to post... Other considerations Conclusion Appendix References

 
Detection of the potential for a cardiovascular safety problem in pre-clinical or early clinical studies should lead to detailed pre-approval definition of acceptable cardiovascular safety if a drug is to be approved for non-cardiovascular targets.

Pre-approval assessments of drug-associated risks commonly suffer from inadequate statistical power because of the relatively modest pre-approval exposure requirements imposed by regulatory agencies. Currently, post-approval assessments usually suffer from inadequate controls, from cohorts not representative of the population actually using the drug, and from inadequate power to identify adverse events. Brass et al.²¹ have proposed an approach to resolving the latter problem by basing safety evaluations not on point estimates but rather on the upper bounds of confidence intervals circumscribing the point estimate, allowing predefinition of the unacceptable risk level and accrual of sufficient events to provide power adequate to assess whether risk is within the pre-determined acceptable range. If the confidence limit is acceptable relative to the demonstrated benefit of therapy, approval may be justified to avoid delaying availability of effective therapy. The approval letter and/or label could state the need for post-marketing assessments for increasingly precise definition of cardiovascular risk. Patient exposure needed to generate the required events could be gathered by extending safety follow-up beyond that required for the primary efficacy endpoint in pre-approval trials, eliminating the need to design and conduct new studies or to enrol additional patients in pivotal trials.²¹

	Acceptable mechanisms to evaluate cardiovascular risk

Top Abstract Introduction Background Classification of cardiovascular... Surrogate measures of risk Timing of risk assessment Acceptable mechanisms to... Regulatory impediments to post... Other considerations Conclusion Appendix References

 
Drug development should incorporate cardiovascular safety assessment beginning with pre-clinical/animal studies of drug effects on cardiac physiology/pharmacology. Phase 1 and 2 trials should evaluate pre-specified parameters including, but not limited to, coagulation profiles, blood pressure, blood lipid concentrations, left ventricular size and function, body weight, cardiac dimensions, QT intervals, and other ECG parameters and, to the extent feasible, interactions between drug effects and specific genomic or proteomic characteristics. Data generated from these studies provide the foundation upon which Phase 3 trials can be designed.

Most Phase 3 trials of ‘non-cardiac’ drugs should pre-specify measurement of cardiovascular events of interest, clearly stating the diagnostic criteria by which these events will be identified, and mandating regular measurement of variables to detect clinically silent events. In addition, the protocol should define a method for combining the adverse experiences from all trials in the development program to enhance power to identify problems if they exist.

Given the relative frequency of the non-cardiac outcome events in many of these trials, large sample sizes often are not required for demonstrating superior benefit of a new agent vs. placebo if a beneficial drug effect exists. Since the need to avoid confounding influences in these relatively small populations commonly results in relatively young patients with low cardiovascular risk, the capacity to detect cardiovascular adversity is inherently limited even if such events truly are associated with therapy. For example, when placebo-treated cohorts have annual event rates for the pre-specified cardiovascular safety composite as low as that found in the APC trial (earlier), population sizes (and costs) for clinical trials would need to be several orders of magnitude greater than typical pre-approval exposure for non-cardiac drugs (e.g. terfenadine = 5000 patients, fenfluramine = 340, dexfenfluramine = 1200³⁰) if trials were designed a priori to achieve power sufficient to establish clinically meaningful cardiovascular risk that is 1.5 to two-fold greater than placebo (Table 1). Enlarging trials to identify statistically significant differences in cardiovascular risk between a new non-cardiovascular drug and a comparator is rarely feasible and generally would represent a wasteful expenditure of research resources. Non-inferiority trial design also can be employed to assess relative safety; regulators and investigators then would need to agree upon the magnitude of difference between adverse event rates caused by the new agent and those caused by an established drug (or by placebo) that would be ‘clinically unimportant’. As in superiority trials, however, large numbers of patients are needed when adverse events are relatively uncommon (Table 2).

View this table: [in this window] [in a new window]   Table 2 Number of patients needed to demonstrate non-inferiority assuming type I error = 0.05 and power = 0.90 (computation based on Chow et al.32)

 
However, the absolute magnitude of risk reliably excluded by trial data can be defined from registries/observational studies, less rigorous than randomized controlled trials for comparisons of effects of different therapeutic strategies, but perhaps better suited for providing credible absolute risk estimates. Actual detection of relatively rare events is likely to require a prohibitively large sample size (Table 3) but excluding a risk of unacceptable magnitude can be achieved with population sizes likely attainable in practice. As projected in Table 4, such populations could provide a point estimate of absolute risk, with narrower and more credible confidence intervals, than now is commonly available, enabling more confident comparison of benefit and risk than currently is possible.

View this table: [in this window] [in a new window]   Table 3 Minimum number of subjects to assure observing at least one event if the true event rate is 0.0001

 

View this table: [in this window] [in a new window]   Table 4 Sample size needed to determine if true event rate is 0.015 and not 0.02 (calculated from formula of van Belle et al.31)

 
Observational studies are less intricate and costly and, therefore, often more practical, than randomized trials for defining absolute risk. Also, compared with randomized trials that must employ rigorous exclusion criteria to minimize factors likely to confound data interpretation, observational studies of absolute risk do not necessarily require such exclusions and, in fact, may avoid them to mimic the ‘real world’ population at risk. Unfortunately, the strength of the observational study also is its weakness: the lack of a comparator and the potential for multiple confounders limits the breadth of acceptable conclusions and can lead to erroneous inferences, declaring a drug acceptably safe when it is not, or unacceptably harmful when it is safe. Sample sizes for observational studies depend on the pre-defined magnitude of acceptable risk and on decisions about confounder exclusions.

To use observational studies for safety assessment, the design must be prospective, with pre-specified definition of cardiovascular outcomes. Retrospective assessment may fail to provide documentation of variables of interest. When comparative risks are required, randomized trials may be the only acceptable design. The strength of evidence inferrable from the study design must be considered when evaluating drug safety.

Large insurance databases are often used in observational studies to evaluate drug safety. These databases contain thousands of patient records with up to several years of follow-up. Adequately powered studies using these databases can be prospectively designed with strict procedures for data collection and verification. These databases can be excellent tools for evaluating the long-term safety of cardiovascular and non-cardiovascular drugs in much larger populations than would be feasible in prospective randomized trials, though inferences from them are limited by lack of information about doses actually used vs. those prescribed, and by imprecision or inaccuracy in diagnoses and other patient characteristics, since these generally are not entered directly or checked by treating physicians.

	Regulatory impediments to post-marketing safety assessment

Top Abstract Introduction Background Classification of cardiovascular... Surrogate measures of risk Timing of risk assessment Acceptable mechanisms to... Regulatory impediments to post... Other considerations Conclusion Appendix References

 
Currently, the FDA can request post-marketing studies, but can legally require them only for new drugs approved under Subpart H, granted on the basis of a surrogate endpoint or when approval carries restrictions to ensure safe use. The EMEA has parallel limitations. To improve post-marketing safety assessment, all regulatory agencies must be empowered to mandate adequately designed post-marketing studies as a condition of approval, with the capacity to withdraw approval if the sponsor does not perform the mandated studies. Drug approval should be viewed as the initial, not the final, step in defining appropriate drug use. The drug label developed at the time of approval should be subject to continual refinement in response to results of post-marketing studies. Post-marketing experience should not be primarily a basis for withdrawing marketing approval but rather a basis for continually improving the precision of information to prescribers/users about risks (and benefits) to be considered in employing a therapy. In the early post-approval period, a label could include a warning that ‘the cardiovascular risk has not been fully evaluated’ with a numerical statement about the level of risk that cannot be excluded, to be removed when risk is more fully examined. The label could also indicate the date by which post-marketing evaluations are anticipated.

	Other considerations

Top Abstract Introduction Background Classification of cardiovascular... Surrogate measures of risk Timing of risk assessment Acceptable mechanisms to... Regulatory impediments to post... Other considerations Conclusion Appendix References

 
Dose- response relations for safety end-points may differ quantitatively from those for efficacy. In addition, the exposure time required to observe an adverse cardiovascular effect is not known; it is likely to be different for different drugs. Drug-related risks may vary with the pre-therapy cardiovascular risk of the patient. For example, a drug may have minimal absolute cardiovascular risk in a young patient without comorbid conditions, but it may be associated with far greater absolute risk in a 70-year-old with known coronary disease and diabetes. Thus, for non-cardiovascular drugs, it may be useful to perform at least one efficacy study in patients with relatively high cardiovascular risk if the drug will ultimately be used in this population; this approach requires careful safety monitoring during the trial. However, without empirical data, it cannot be known if findings from a high-risk population (either positive or negative) can be extrapolated to lower risk patients. Finally, all risks may not be evident even if the processes for assessing cardiovascular safety are revised.

	Conclusion

Top Abstract Introduction Background Classification of cardiovascular... Surrogate measures of risk Timing of risk assessment Acceptable mechanisms to... Regulatory impediments to post... Other considerations Conclusion Appendix References

 
Harms identified after drug approval during the past decade suggest the need for new approaches to evaluating potential cardiovascular risk in the context of non-cardiovascular therapy. Unfortunately, currently feasible strategies cannot guarantee detection and quantitation of all major adverse drug effects; biological variability will continue to provide uncertainty, which will be minimized only with pharmacogenomic and other novel initiatives. Nonetheless, in the present, we can and must improve upon efficiency in defining the risk:benefit relations of non-cardiovascular drugs. This will happen only if patient exposure, in number and duration, is increased in pre- and post-approval studies sufficiently to enable exclusion, with reasonable certainty, of unacceptable cardiovascular risks. Strategies to achieve this goal, outlined in this article, may be useful.

	Appendix

Top Abstract Introduction Background Classification of cardiovascular... Surrogate measures of risk Timing of risk assessment Acceptable mechanisms to... Regulatory impediments to post... Other considerations Conclusion Appendix References

 
The following individuals participated in the December 2005 8th Cardiovascular Clinical Trialists Workshop:

E.A., MD; Kirkwood F. Adams, MD; Corine Bernaud, MD; J.B., MD; John Cleland, MD; Rory Collins, MBBS; Nicolas Danchin, MD; David DeMets, PhD; Ferenc Follath, MD, PhD; Nancy Geller, PhD; Mathieu Ghadanfar, MD; Sidney Goldstein, MD; David Gordon, MD, PhD, MPH; Peter Held, MD; H.M. James Hung, PhD; Desmond Julian, MD; Bridget-Anne Kirwan, PhD; Alain Leizorovicz, MD; Richard Lewis, PhD; Raymond Lipicky, MD; Alice Mascette, MD; M.A.P., MD, PhD; B.P., MD; Stuart Pocock, BA, MSc, PhD; Philip Poole Wilson, MD; H.P., MD, PhD; Edmond Roland, MD; Denise Simons-Morton, MD, PhD; Scott Solomon, MD; Christian Torp-Pedersen, MD; J.W., PhD; F.Z., MD, PhD.

	Acknowledgments

 
Conflict of interest: The symposium was supported by an unrestricted educational grant from Pfizer, Inc., New York, NY, USA. J.S.B. receives an honorarium as member of a Data and Safety Monitoring Committee and a blinded Events Adjudication Committee for two Pfizer-sponsored trials of non-cardiovascular drugs. He is also a member of the Executive Committee for PRECISION, a comparison of several non-steroidal anti-inflammatory drugs, funded by a grant from Pfizer to the Cleveland Clinic Foundation; J.S.B. receives no remuneration for this work. H.P. is a Pfizer employee, and holds stock in Pfizer. E.A. has no relations to report. F.F. participates on a cardiovascular drugs advisory board on for Pfizer Switzerland. J.W. has no relations to report. M.A.P. reports having received honoraria from Pfizer; and served as a member of the Data Safety Monitoring Board for the National Cancer Institute Contract no. N01-CN-95015, Prevention of Sporadic Colorectal Adenomas with Celecoxib, which was funded by a grant from the Strang Cancer Prevention Center. B.P. is a consultant to Pfizer. F.Z. receives research support from Pfizer.

	References

Top Abstract Introduction Background Classification of cardiovascular... Surrogate measures of risk Timing of risk assessment Acceptable mechanisms to... Regulatory impediments to post... Other considerations Conclusion Appendix References

 

1. Couzin J. Drug safety withdrawal of Vioxx casts a shadow over COX-2 inhibitors. Science (2004) 306:384–385.[Abstract/Free Full Text]
2. Couzin J. Drug safety. FDA panel urges caution on many anti-inflammatory drugs. Science (2005) 307:1183–1185.[Web of Science][Medline]
3. Frantz S. Drug safety special: chasing shadows. Nature (2005) 434:557–558.[CrossRef][Medline]
4. Psaty BM, Furberg CD. COX-2 inhibitors–lessons in drug safety. N Engl J Med (2005) 352:1133–1135.[Free Full Text]
5. Nussmeier NA, Whelton AA, Brown MT, Langford RM, Hoeft A, Parlow JL, Boyce SW, Verburg KM. Complications of the COX-2 inhibitors parecoxib and valdecoxib after cardiac surgery. N Engl J Med (2005) 352:1081–1091.[Abstract/Free Full Text]
6. Solomon SD, McMurray JJ, Pfeffer MA, Wittes J, Fowler R, Finn P, Anderson WF, Zauber A, Hawk E, Bertagnolli M. Cardiovascular risk associated with celecoxib in a clinical trial for colorectal adenoma prevention. N Engl J Med (2005) 352:1071–1080.[Abstract/Free Full Text]
7. Bresalier RS, Sandler RS, Quan H, Bolognese JA, Oxenius B, Horgan K, Lines C, Riddell R, Morton D, Lanas A, Konstam MA, Baron JA. Cardiovascular events associated with rofecoxib in a colorectal adenoma chemoprevention trial. N Engl J Med (2005) 352:1092–1102.[Abstract/Free Full Text]
8. White WB, Faich G, Borer JS, Makuch RW. Cardiovascular thrombotic events in arthritis trials of the cyclooxygenase-2 inhibitor celecoxib. Am J Cardiol (2003) 92:411–418.[CrossRef][Web of Science][Medline]
9. Ray WA, Stein CM, Hall K, Daugherty JR, Griffin MR. Non-steroidal anti-inflammatory drugs and risk of serious coronary heart disease: an observational cohort study. Lancet (2002) 359:118–123.[CrossRef][Web of Science][Medline]
10. Graham DJ, Campen D, Hui R, Spence M, Cheetham C, Levy G, Shoor S, Ray WA. Risk of acute myocardial infarction and sudden cardiac death in patients treated with cyclo-oxygenase 2 selective and non-selective non-steroidal anti-inflammatory drugs: nested case-control study. Lancet (2005) 365:475–481.[Web of Science][Medline]
11. Chan AT, Manson JE, Albert CM, Chae CU, Rexrode KM, Curhan GC, Rimm EB, Willett WC, Fuchs CS. Nonsteroidal antiinflammatory drugs, acetaminophen, and the risk of cardiovascular events. Circulation (2006) 113:1578–1587.[Abstract/Free Full Text]
12. Devereux RB. Appetite suppressants and valvular heart disease. N Engl J Med (1998) 339:765–766.[Free Full Text]
13. Jick H, Vasilakis C, Weinrauch LA, Meier CR, Jick SS, Derby LE. A population-based study of appetite-suppressant drugs and the risk of cardiac-valve regurgitation. N Engl J Med (1998) 339:719–724.[Abstract/Free Full Text]
14. Khan MA, Herzog CA, St Peter JV, Hartley GG, Madlon-Kay R, Dick CD, Asinger RW, Vessey JT. The prevalence of cardiac valvular insufficiency assessed by transthoracic echocardiography in obese patients treated with appetite-suppressant drugs. N Engl J Med (1998) 339:713–718.[Abstract/Free Full Text]
15. Mark EJ, Patalas ED, Chang HT, Evans RJ, Kessler SC. Fatal pulmonary hypertension associated with short-term use of fenfluramine and phentermine. N Engl J Med (1997) 337:602–606.[Free Full Text]
16. Connolly HM, Crary JL, McGoon MD, Hensrud DD, Edwards BS, Edwards WD, Schaff HV. Valvular heart disease associated with fenfluramine-phentermine. N Engl J Med (1997) 337:581–588.[Abstract/Free Full Text]
17. Honig PK, Wortham DC, Zamani K, Conner DP, Mullin JC, Cantilena LR. Terfenadine-ketoconazole interaction. Pharmacokinetic and electrocardiographic consequences. JAMA (1993) 269:1513–1518.[Abstract/Free Full Text]
18. Honig PK, Woosley RL, Zamani K, Conner DP, Cantilena LR Jr. Changes in the pharmacokinetics and electrocardiographic pharmacodynamics of terfenadine with concomitant administration of erythromycin. Clin Pharmacol Ther (1992) 52:231–238.[Web of Science][Medline]
19. Wysowski DK, Corken A, Gallo-Torres H, Talarico L, Rodriguez EM. Postmarketing reports of QT prolongation and ventricular arrhythmia in association with cisapride and Food and Drug Administration regulatory actions. Am J Gastroenterol (2001) 96:1698–1703.[CrossRef][Web of Science][Medline]
20. Wadman M. Drug safety special: the safety catch. Nature (2005) 434:554–556.[CrossRef][Medline]
21. Brass EP, Lewis RJ, Lipicky R, Murphy J, Hiatt WR. Risk assessment in drug development for symptomatic indications: a framework for the prospective exclusion of unacceptable cardiovascular risk. Clin Pharmacol Ther (2006) 79:165–172.[CrossRef][Web of Science][Medline]
22. Kwon HJ, Cote TR, Cuffe MS, Kramer JM, Braun MM. Case reports of heart failure after therapy with a tumor necrosis factor antagonist. Ann Intern Med (2003) 138:807–811.[Abstract/Free Full Text]
23. Nesto RW, Bell D, Bonow RO, Fonseca V, Grundy SM, Horton ES, Le WM, Porte D, Semenkovich CF, Smith S, Young LH, Kahn R. Thiazolidinedione use, fluid retention, and congestive heart failure: a consensus statement from the American Heart Association and American Diabetes Association. Circulation (2003) 108:2941–2948.[Free Full Text]
24. Hartung DM, Touchette DR, Bultemeier NC, Haxby DG. Risk of hospitalization for heart failure associated with thiazolidinedione therapy: a medicaid claims-based case-control study. Pharmacotherapy (2005) 25:1329–1336.[CrossRef][Web of Science][Medline]
25. European Medicines Agency. The clinical evaluation of QT/QTc interval prolongation and proarrhythmic potential for non-antiarrhythmic drugs. (2005) 23 January 2006. ICH E14. http://www.emea.eu.int/pdfs/human/ich/000204en.pdf.
26. The European Agency for the Evaluation of Medicinal Products. Committee for proprietary medicinal products. Points to consider: the assessment of the potential for QT interval prolongation by non-cardiovascular medicinal products. (1997) 20 January 2006. http://www.emea.eu.int/pdfs/human/swp/098696en.pdf.
27. FDA - Health Canada. The digital ECG imperative for cardiac safety: issues and opportunities. (2002) 20 January 2006. http://www.ert.com/investor/pdfs/Digital_Imperative.pdf.
28. Finlayson K, Witchel HJ, McCulloch J, Sharkey J. Acquired QT interval prolongation and HERG: implications for drug discovery and development. Eur J Pharmacol (2004) 500:129–142.[CrossRef][Web of Science][Medline]
29. Redfern WS, Carlsson L, Davis AS, Lynch WG, MacKenzie I, Palethorpe S, Siegl PK, Strang I, Sullivan AT, Wallis R, Camm AJ, Hammond TG. Relationships between preclinical cardiac electrophysiology, clinical QT interval prolongation and torsade de pointes for a broad range of drugs: evidence for a provisional safety margin in drug development. Cardiovasc Res (2003) 58:32–45.[Abstract/Free Full Text]
30. Friedman MA, Woodcock J, Lumpkin MM, Shuren JE, Hass AE, Thompson LJ. The safety of newly approved medicines: do recent market removals mean there is a problem? JAMA (1999) 281:1728–1734.[Abstract/Free Full Text]
31. van Belle G, Fisher L, Heagerty P, Lumley T. Biostatistics: A Methodology for the Health Sciences (2004) Hoboken: John Wiley & Sons.
32. Chow S, Shao J, Wang H. Sample Size Calculations in Clinical Research (2003) New York: Taylor and Francis.

CiteULike    Connotea    Del.icio.us    What's this?

This article has been cited by other articles:

				F. Zannad, P. Bousquet, and L. Monassier CHAPTER 11 Clinical Pharmacology of Cardiovascular Drugs ESC Textbook of Cardiovascular Medicine, January 1, 2009; 2(1): med-9780199566990-chapter - med-9780199566990-chapter. [Abstract] [Full Text] [PDF]

This Article Abstract FREE Full Text (PDF) All Versions of this Article: 28/15/1904    most recent ehm209v1 E-letters: Submit a response Alert me when this article is cited Alert me when E-letters are posted Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in ISI Web of Science Similar articles in PubMed Alert me to new issues of the journal Add to My Personal Archive Download to citation manager Request Permissions Disclaimer Google Scholar Articles by Borer, J. S. Articles by Zannad, F. Search for Related Content PubMed PubMed Citation Articles by Borer, J. S. Articles by Zannad, F. Social Bookmarking          What's this?

Online ISSN 1522-9645 - Print ISSN 0195-668x

Copyright © 2009 European Society of Cardiology

Oxford Journals Oxford University Press

• Site Map
• Privacy Policy
• Frequently Asked Questions

Other Oxford University Press sites: Oxford University Press Oxford Journals China Oxford Journals Japan American National Biography Booksellers' Information Service Children's Fiction and Poetry Children's Reference Corporate & Special Sales Dictionaries Dictionary of National Biography Digital Reference English Language Teaching Higher Education Textbooks Humanities International Education Unit Law Medicine Music Online Products Oxford English Dictionary Reference Rights and Permissions Science School Books Social Sciences Very Short Introductions World's Classics