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CLINICAL RESEARCH: CLINICAL TRIALS

Impact of Oxypurinol in Patients With Symptomatic Heart Failure

Results of the OPT-CHF Study

Joshua M. Hare, MD^_*,_*, Brian Mangal, MSc, Joanne Brown, BSc, Charles Fisher, Jr, MD, Ronald Freudenberger, MD, Wilson S. Colucci, MD, Douglas L. Mann, MD^||, Peter Liu, MD^¶, Michael M. Givertz, MD^#, Richard P. Schwarz, PhD^_* for the OPT-CHF Investigators

^_* The University of Miami Miller School of Medicine, Miami, Florida
Cardiome Pharma Corporation, Vancouver, British Columbia, Canada
Robert Wood Johnson University Hospital, New Brunswick, New Jersey
Boston University, Boston, Massachusetts
^|| Baylor Heart Clinic, Houston, Texas
^¶ Toronto General Hospital, Toronto, Ontario, Canada
^# Brigham & Women's Hospital, Boston, Massachusetts.

Manuscript received October 4, 2007; revised manuscript received January 2, 2008, accepted January 15, 2008.

^_* Reprint requests and correspondence: Dr. Joshua M. Hare, Division of Cardiology, University of Miami Miller School of Medicine, 1120 NW 14th Street, Suite 1124, Miami, Florida 33136. (Email: jhare{at}med.miami.edu).

	Abstract

Top Abstract Methods Results Discussion Conclusions Appendix References

 
Objectives: This study evaluated whether a xanthine oxidase (XO) inhibitor, oxypurinol, produces clinical benefits in patients with New York Heart Association functional class III to IV heart failure due to systolic dysfunction receiving optimal medical therapy.

Background: Increased XO activity may contribute to heart failure pathophysiology.

Methods: Patients (n = 405) were randomized to oxypurinol (600 mg/day) or placebo. Efficacy at 24 weeks was assessed using a composite end point comprising heart failure morbidity, mortality, and quality of life.

Results: The percentage of patients characterized as improved, unchanged, or worsened did not differ between those receiving oxypurinol or placebo. Oxypurinol reduced serum uric acid (SUA) by 2 mg/dl (p < 0.001). In a subgroup analysis, patients with elevated SUA (>9.5 mg/dl, n = 108) responded favorably to oxypurinol (p = 0.02 for interaction term), whereas oxypurinol patients with SUA <9.5 mg/dl exhibited a trend towards worsening. In addition, SUA reduction to oxypurinol correlated with favorable clinical response. Within the entire oxypurinol patient cohort, those characterized as either improved or unchanged had significantly greater reductions in SUA compared with patients who worsened (–2.3 ± 2.1 mg/dl vs. –1.0 ± 1.9 mg/dl, p = 0.0006). In placebo patients, lower baseline SUA, but not change in SUA, correlated with improved clinical outcome.

Conclusions: Oxypurinol did not produce clinical improvements in unselected patients with moderate-to-severe heart failure. However, post-hoc analysis suggests that benefits occur in patients with elevated SUA in a manner correlating with the degree of SUA reduction. Serum uric acid may serve as a valuable biomarker to target XO inhibition in heart failure. (Oxypurinol Compared With Placebo for Class III-IV NYHA Congestive Heart Failure; NCT00063687 [ClinicalTrials.gov] )

Abbreviations and Acronyms   BNP = brain natriuretic peptide   CCE = composite clinical end point   CI = confidence interval   CV = cardiovascular   ITT = intent to treat   MLHF = Minnesota Living with Heart Failure   NYHA = New York Heart Association   PGHFCS = Patient Global Heart Failure Clinical Status   SUA = serum uric acid   XO = xanthine oxidase

	Methods

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The design of this multicenter, randomized, double-blind, placebo-controlled, parallel group OPT-CHF study (The Efficacy and Safety Study of Oxypurinol Added to Standard Therapy in Patients With New York Heart Association Class III-IV Congestive Heart Failure) is described in detail elsewhere (11).

Patients.   Eligible patients were between 18 to 85 years old, had symptomatic heart failure (New York Heart Association [NYHA] functional class III to IV), and left ventricular dysfunction defined as a left ventricular ejection fraction 40%. Patients were eligible if they had at least 1 hospitalization for heart failure within 18 months, an emergency room visit resulting in treatment with intravenous therapy for worsening heart failure, or if a new drug class for heart failure was added to their regimen due to lack of medical stability. Patients receiving continuous or intermittent intravenous inotropic or vasodilator agents for a period of at least 4 weeks before entering the study in any dosage (varying dosages allowed) met the criteria for new drug therapy addition. Investigators were asked to ensure each patient was, in their opinion, on an optimum dose of heart failure medication, a requirement for study entry.

Study design.   Patients were randomized to oxypurinol or placebo. The initial dose for both active and placebo groups during the first week post-randomization was 1 capsule (100 mg oxypurinol or matching placebo). Subsequently, both groups received 6 capsules (600 mg) daily. Patients with reduced renal function had their study medication titrated based on serum creatinine levels, and those with creatinine >3.0 were excluded (11).

Study drug was initiated after a 2-week run-in period, during which time stability of symptoms and background treatment were assessed and baseline assessments were obtained. Patients were monitored with outpatient visits every 4 weeks for 24 weeks, at which time they received a history and physical examination, NYHA functional class assessment, a 6-min walk test, the Patient Global Assessment of Heart Failure questionnaire, and the Minnesota Living with Heart Failure (MLHF) questionnaire (a quality-of-life assessment).

Patients remained on their assigned dosage until the end of the study, unless the investigator felt an adverse event was drug related and required drug withdrawal, or the patient withdrew consent to continue on study medication. These patients were followed as part of the intent-to-treat (ITT) cohort, and received all protocol-related study procedures through the 24-week time point. Patients who did not return for study procedures after study drug withdrawal were contacted at the conclusion of the trial to determine their mortality status, unless they formally withdrew consent to participate in the study.

Study end points.   The primary end point was a composite clinical end point (CCE) that classified subject's clinical status as improved, worsened, or unchanged at week 24, similar to that reported in Packer (12), with a slight modification. The classification followed sequential rules based on the outcomes of the following items: 1) CV death; 2) hospitalization, emergency room, or emergent office/clinic visit for worsening heart failure; 3) administration of a new drug class for heart failure or the administration of intravenous diuretics de novo for worsening heart failure; 4) permanent withdrawal of study drug due to worsening heart failure; 5) NYHA functional class; or 6) Patient Global Heart Failure Clinical Status (PGHFCS). These components were adjudicated by a clinical events committee. A patient was classified as worsened if they died, were hospitalized, visited an emergency room, or experienced an emergent office or clinic visit adjudicated by the clinical events committee to be primarily for treatment of worsening heart failure symptoms. In addition, worsening was defined by a decrement in NYHA functional class at week 24, a PGHFCS assessment at week 24 in which the patient indicated moderately or markedly worse symptoms of heart failure, the addition of a new drug class for heart failure, the administration of intravenous diuretics de novo for worsening heart failure, or permanent discontinuation from study medication due to worsening heart failure. With regards to addition of a new class of drugs, substituting one class for another due to a side effect (e.g., angiotensin receptor blocker for angiotensin-converting enzyme inhibitor) did not constitute this end point. A patient was characterized as improved if none of the above occurred and they improved one or more NYHA functional classes, or if they indicated a moderate or marked improvement in the PGHFCS assessment. Patients who met criteria for neither improving nor worsening were classified as unchanged. Patients were evaluated on an ITT basis.

Secondary efficacy end points included time to first occurrence of CV death or hospitalization for worsening heart failure; change from baseline to week 24 in quality-of-life score as assessed by the MLHF questionnaire, and change from baseline to week 24 in serum uric acid (SUA) levels. Tertiary end points included individual components of the CCE in addition to the 6-min walk test, and the time to all-cause death and all-cause hospitalization.

The study was approved by institutional review boards at all participating centers, and all patients gave written informed consent. Four hundred and five patients were enrolled between March 2003 and December 2004 at 54 centers in Canada and the U.S. Of the 405 randomized patients, 51 patients did not complete the study through to the 24-week visit, 22 withdrew consent, 15 died, and 14 discontinued for other reasons. Where possible, every effort was made to determine the 24-week status of all patients who withdrew from the study.

Subgroup analysis.   An additional exploratory analysis was conducted to examine the effect of SUA on the primary CCE outcome. Patients were classified as high SUA if they had a baseline SUA >9.5 mg/dl, and low SUA if they had a baseline SUA 9.5 mg/dl, which was a cutoff chosen based on previously published findings (7). In addition, the degree of SUA reduction was assessed within these subgroups.

Statistical methods.   All analyses were conducted using the ITT principle. Analysis of the primary efficacy CCE end point utilized the Cochran-Mantel-Haenszel mean score test with modified ridit scores to compare the distributions. Patients who were lost to follow-up were evaluated for all end points using the last value carried forward method. The same approach was applied to the analysis of the change from baseline in NYHA functional class, where subjects were classified as improved by 2 or more categories, improved by 1 category, unchanged, or worsened by 1 category, and the PGHFCS assessment at week 24. Analyses of the time-to-event end points utilized the log-rank test to compare distributions between treatment groups, and a Cox proportional hazards regression model for estimation of the hazard ratios. Analysis of the change from baseline in SUA, MLHF questionnaire score, and the 6-min walk test score was conducted using a repeated measures mixed model, with baseline score as a covariate and treatment, time, and the treatment by time interaction as fixed effects. For the MLHF questionnaire score and the 6-min walk test, the covariance matrix was specified to be autoregressive of order one, while for SUA an unstructured covariance matrix was used. The choice of covariance matrix was examined. Examination of the strength of an association between the primary end point and both SUA and brain natriuretic peptide (BNP), as well as between BNP and SUA were conducted using Pearson's correlation test. Brain natriuretic peptide was log transformed for these analyses. All analyses were conducted using SAS version 8.2 (SAS Institute, Cary, North Carolina).

	Results

Top Abstract Methods Results Discussion Conclusions Appendix References

 
Table 1 depicts the baseline characteristics of patients enrolled in this study. Both groups were comparable across all baseline characteristics. The majority of patients were NYHA functional class III (96%), and virtually all patients (99%) were on maximum tolerated medications for their heart failure.

View larger version (29K): [in this window] [in a new window] [Download PPT slide]   Figure 1 Impact of Oxypurinol on the CCE As depicted, randomization to oxypurinol failed to increase the proportion of patients improving according to the composite categorization. CCE = composite clinical end point.

View larger version (9K): [in this window] [in a new window] [Download PPT slide]   Figure 2 Impact of Oxypurinol on SUA Serum uric acid (SUA) was measured at monthly intervals throughout the 6-month follow-up period. As depicted, oxypurinol effectively lowered SUA by approximately 2 mg/dl, and this effect was evident within 1 month of therapy. *Indicates p < 0.0001 versus placebo and is based on a repeated measures mixed model with baseline as a covariate and change from baseline as the dependent variable.

View larger version (28K): [in this window] [in a new window] [Download PPT slide]   Figure 3 Impact of Oxypurinol on the CCE in High and Low SUA Subgroups p = 0.02 for interaction between high and low serum uric acid (SUA) groups. CCE = composite clinical end point.

View larger version (24K): [in this window] [in a new window] [Download PPT slide]   Figure 4 Scatterplot of Baseline SUA to Final SUA by Outcome Overall, the oxypurinol-treated group had improved final serum uric acid (SUA) compared with their baseline SUA levels when evaluated against the placebo group.

View larger version (32K): [in this window] [in a new window] [Download PPT slide]   Figure 5 Degree of SUA Reduction in Patients With Low and High SUA As depicted, the degree of serum uric acid (SUA) reduction was greatest in treated patients classified as improved or unchanged with high baseline SUA. *p < 0.05 versus worsened group.

	Discussion

Top Abstract Methods Results Discussion Conclusions Appendix References

Examination of secondary and tertiary end points showed little to no impact of oxypurinol therapy. The combined end point of time to CV death plus heart failure hospitalization suggested the possibility of an adverse response to oxypurinol (Table 2). This finding argues against the use of oxypurinol in all patients with symptomatic heart failure due to systolic dysfunction, and prompted an examination of predictors of outcome within the study population.

Subgroup analysis demonstrated that patients with elevated levels of SUA may represent a responsive population. The SUA findings are consistent with a series of reports indicating that elevated SUA is a valuable biomarker of morbidity and mortality in heart failure (8). Anker et al. (7) proposed a cutoff of 9.5 mg/dl based on an analysis of several populations. In the latter analysis, using a cross-sectional study design, high uric acid was demonstrated to be associated with higher mortality and greater need for cardiac transplantation. Importantly, in the present study, the change in SUA response also correlated with clinical outcome. First, in the placebo group, SUA did not change over the 6-month period of study, and baseline SUA correlated with outcome. Second, in both the entire cohort and the high SUA group, patients who worsened had substantially lower reductions in SUA compared with the other groups. Finally, when relevant secondary or tertiary end points were examined, a failure to decrease SUA correlated with adverse outcome. Together, these analyses strongly suggest that an attenuated response to oxypurinol, as indicated by diminished SUA reduction, predicts failure of clinical response and possibly adverse outcomes.

Whether uric acid is toxic, per se, or is a biomarker of xanthine oxidoreductase activity is currently unclear. Interestingly, most mammalian species have low circulating uric acid due to the presence of uricase, an enzyme inactive in humans, which degrades uric acid (13). Nevertheless, cardiac injury is associated with increased XO activity in many animal models, and one in particular demonstrated the association between XO activity and uric acid in myocardial tissue (14). Collectively, numerous animal models and human studies demonstrate improved cardiac remodeling (3,15), cardiac energetics (16,17), endothelial function (5,9,18,19), and survival after cardiac injury (1,20) in response to XO inhibition. Most recently, George et al. (21) argued against direct toxicity of uric acid, and have demonstrated that the ability of allopurinol to improve endothelial function cannot be attributed to uric acid lowering, per se (21). Together, these experimental and clinical studies suggest that uric acid may represent a valuable biomarker of XO activity in the CV system. Indeed, the fact that approximately one-quarter of the patients in this study had levels of SUA above 9.5 mg/dl argues that this pathway is not addressed by other conventional medications, and represents an unaddressed therapeutic target in a substantial proportion of patients. With regard to usage as a biomarker, it is interesting to note that here we confirm our previous finding that SUA only weakly correlates with the logarithm of BNP and thus may offer additive clinical information (22).

There are several reasons why oxypurinol may not have led to clinical benefits in the broad population of symptomatic, treated patients. First, it is possible that sources of oxidative stress are already inhibited by other medications such as inhibitors of the renin-angiotensin-aldosterone pathway or carvedilol. In this regard, angiotensin II can activate XO directly (23) and indirectly via NADPH oxidase (24). However, it may be argued that patients with high SUA who did not respond to oxypurinol and worsened did so due to lack of efficacy of the medication. Indeed, in this cohort the level of SUA reduction was substantially and significantly less compared with that in patients with high SUA who remained unchanged or who clinically improved. Moreover, findings from retrospective analyses have previously suggested that patients receiving low-dose XO inhibitors may worsen, whereas those receiving high doses may have mortality and hospitalization reductions (25).

Although the post-hoc analysis of SUA is provocative, it is limited. This was not a pre-specified analysis, and the numbers of patients in the high SUA group were small. These results, however, are hypothesis generating, and offer potential explanations for why a hypothesis that was so well supported by pre-clinical work failed to be borne out in humans with advanced heart failure. Future clinical trials are required to prospectively assess the impact of XO inhibition in patients with high SUA.

	Conclusions

Top Abstract Methods Results Discussion Conclusions Appendix References

 
In summary, this study demonstrates that oxypurinol did not improve a clinical composite score in patients with systolic, symptomatic heart failure, and could potentially cause harm to some patients. Subgroup analysis supports the concept that patients with these clinical characteristics and a high SUA may benefit from XO inhibition. Moreover, the degree of SUA reduction correlated with clinical outcome, such that patients who worsened despite oxypurinol therapy had relatively less reduction in uric acid. Measurements of uric acid may aid in individualizing therapy with XO inhibitors.

	Appendix

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For a complete list of investigators, please see the online version of this article.

	Footnotes

 
This study was funded by Cardiome Pharma Corp., Vancouver, British Columbia, Canada. Brian Mangal, Joanne Brown, and Dr. Fisher are employees of Cardiome Pharma Corp. Dr. Hare is a consultant to Cardiome Pharma Corp.

	References

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This Article Abstract Figures Only Full Text (PDF) View Online Appendix View Related Story on Cardiosmart Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in Web of Science Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Web of Science (13) Citing Articles via Google Scholar Google Scholar Articles by Hare, J. M. Search for Related Content PubMed Articles by Hare, J. M. Related Collections Related Articles