Celecoxib for the Prevention of Sporadic Colorectal Adenomas
Monica M. Bertagnolli, M.D., Craig J. Eagle, M.D., Ann G. Zauber, Ph.D., Mark Redston, M.D., Scott D. Solomon, M.D., KyungMann Kim, Ph.D., Jie Tang, M.S., Rebecca B. Rosenstein, Ph.D., Janet Wittes, Ph.D., Donald Corle, M.S., Timothy M. Hess, M.S., G. Mabel Woloj, Ph.D., Frédéric Boisserie, William F. Anderson, M.D., M.P.H., Jaye L. Viner, M.D., M.P.H., Donya Bagheri, M.S., D.A.B.T., John Burn, M.D., Daniel C. Chung, M.D., Thomas Dewar, M.D., T. Raymond Foley, M.D., Neville Hoffman, M.D., Finlay Macrae, M.D., Ronald E. Pruitt, M.D., John R. Saltzman, M.D., Bruce Salzberg, M.D., Thomas Sylwestrowicz, M.D., Gary B. Gordon, M.D., Ph.D., Ernest T. Hawk, M.D., M.P.H., for the APC Study Investigators
Background Studies showing that drugs that inhibit cyclooxygenase-2(COX-2) reduce the number of colorectal adenomas in animalsand patients with familial adenomatous polyposis suggest thatCOX-2 inhibitors may also prevent sporadic colorectal neoplasia.
Methods We randomly assigned patients who had adenomas removedbefore study entry to receive placebo (679 patients) or 200mg (685 patients) or 400 mg (671 patients) of celecoxib twicedaily. Randomization was stratified for the use of low-doseaspirin. Follow-up colonoscopies were performed at one and threeyears after randomization. The occurrence of newly detectedcolorectal adenomas was compared among the groups with the life-tableextension of the Mantel–Haenszel test.
Results Follow-up colonoscopies were completed at year 1 in89.5 percent of randomized patients, and at year 3 in 75.7 percent.The estimated cumulative incidence of the detection of one ormore adenomas by year 3 was 60.7 percent for patients receivingplacebo, as compared with 43.2 percent for those receiving 200mg of celecoxib twice a day (risk ratio, 0.67; 95 percent confidenceinterval, 0.59 to 0.77; P<0.001) and 37.5 percent for thosereceiving 400 mg of celecoxib twice a day (risk ratio, 0.55;95 percent confidence interval, 0.48 to 0.64; P<0.001). Seriousadverse events occurred in 18.8 percent of patients in the placebogroup, as compared with 20.4 percent of those in the low-dosecelecoxib group (risk ratio, 1.1; 95 percent confidence interval,0.9 to 1.3; P=0.5) and 23.0 percent of those in the high-dosegroup (risk ratio, 1.2; 95 percent confidence interval, 1.0to 1.5; P=0.06). As compared with placebo, celecoxib was associatedwith an increased risk of cardiovascular events (risk ratiofor the low dose, 2.6; 95 percent confidence interval, 1.1 to6.1; and risk ratio for the high dose, 3.4; 95 percent confidenceinterval, 1.5 to 7.9).
Conclusions These findings indicate that celecoxib is an effectiveagent for the prevention of colorectal adenomas but, becauseof potential cardiovascular events, cannot be routinely recommendedfor this indication. (ClinicalTrials.gov number, NCT00005094
[ClinicalTrials.gov]
.)
Colorectal cancer is a common malignant condition, responsiblefor approximately 150,000 new patients and approximately 55,000deaths per year in the United States alone.1 Despite these statistics,colorectal cancer is one of the most preventable cancers. Mostcolorectal cancers develop from precursor adenomas, which canbe identified and removed during a screening colonoscopy. Thisprocedure may lower the rates of death due to colorectal cancerby as much as 30 to 40 percent.2 The aim of chemopreventionis to use pharmacologic agents to augment the benefits of colonoscopicpolypectomy by inhibiting early stages of tumorigenesis, therebypreventing malignant transformation of precursor adenomas.
A remarkable concordance of data from more than 40 observationalstudies suggests that nonsteroidal antiinflammatory drugs (NSAIDs)reduce the incidence of colorectal adenomas, colorectal cancer,and deaths from colorectal cancer.3 The effects of NSAIDs havebeen confirmed in randomized trials showing that aspirin hasa modest chemopreventive effect on sporadic colorectal adenomas.4,5,6A leading hypothesis explaining this result is based on thepresence of tumorigenic cyclooxygenase-2 (COX-2) within adenomasbut not in normal intestinal tissue. COX-2 mediates the productionof prostaglandin E2 (PGE2) in epithelial tissues, resultingin activation of signaling pathways that promote cell proliferationand inhibit cell death.7,8 Selective COX-2 inhibitors, suchas celecoxib, were originally developed for the treatment ofpain and inflammation. In patients with familial adenomatouspolyposis, celecoxib (Celebrex) also showed antitumor activity.9We conducted a randomized trial to determine whether celecoxibalso prevents sporadic colorectal adenomas.
Methods
Study Design
The Adenoma Prevention with Celecoxib (APC) trial was a randomized,placebo-controlled trial to test whether celecoxib reduces theoccurrence of endoscopically detected colorectal adenomas. Wetested the safety and antitumor efficacy of 200 mg of celecoxibtwice daily, 400 mg of celecoxib twice daily, and placebo. Therandomization was stratified on the basis of the use or nonuseof low-dose aspirin (325 mg or less every other day or 162.5mg or less every day) and clinical site. The trial involved91 clinical sites (72 in the United States, 8 in Australia,10 in Canada, and 1 in the United Kingdom). The study protocolwas approved by the human-subjects committee at each site. Allpatients provided written informed consent before enrollment.An independent data and safety monitoring board reviewed safetydata monthly and efficacy data twice a year. All study colonoscopieswere performed by gastroenterologists associated with the APCtrial. The APC trial was funded by the National Cancer Instituteand by Pfizer, through a clinical trials agreement with theNational Cancer Institute. The APC trial was a cooperative effortled by a study steering committee composed of the lead principalinvestigator, the National Cancer Institute project officer,and a representative from Pfizer. The steering committee ofthe APC trial directed all aspects of the study, including itsdesign, data gathering, data analysis, and manuscript preparation.The authors vouch for the completeness and veracity of the dataand data analysis.
Recruitment and Randomization
Staff at the clinical sites identified eligible study participantsby reviewing colonoscopy records during a recruitment periodfrom November 1999 to March 2002. Participants ranged from 31to 88 years of age at enrollment and had recently undergonecolonoscopic removal of colorectal adenomas and had a high riskof recurrent adenomas on the basis of a history of either multipleadenomas or removal of a single adenoma more than 5 mm in diameter.Within six months before enrollment, eligible patients underwentcomplete colonoscopy with removal of all polyps, one or moreof which was a histologically confirmed adenoma.
Patients were willing to abstain from long-term use of NSAIDs(defined as more than 21 days of use per year) or COX-2 inhibitors,excluding low-dose aspirin, for the duration of the study. Patientsnot taking aspirin at baseline were required to abstain fromtaking it during the trial.
Exclusion criteria included a history of familial adenomatouspolyposis, hereditary nonpolyposis colon cancer, inflammatorybowel disease, or large-bowel resection other than appendectomy.Other exclusion criteria included a history of a renal or hepaticdisorder, a clinically significant bleeding disorder, or treatmentfor a gastrointestinal ulcer in the month before study entry.Patients were ineligible if they had used NSAIDs or aspirinat doses of more than 325 mg every other day at least threetimes a week during the two months before randomization or ifthey had received treatment with oral or intravenous corticosteroidsfor more than two weeks during the six months before randomization.
A total of 2457 potential participants entered a 30-day placeborun-in period during which they were required to have at least80 percent adherence to medication use, as measured by pillcounts, in order to proceed to randomization (Figure 1). Duringthis time, a central study pathologist reviewed baseline adenomasto confirm study eligibility; subsequently, 2035 patients werestratified according to clinical site and the use or nonuseof low-dose aspirin and were randomly assigned to treatmentby means of an interactive voice-response system.
Patients who violated study entry criteria were those for whom the presence of an adenoma on colonoscopy at baseline could not be confirmed. Patients who withdrew consent for study participation included those who withdrew from the study for nonmedical reasons, those who failed to complete a post-randomization colonoscopy for nonmedical reasons, or those who did not adhere to the protocol for other reasons. Adherence to the use of study medication was calculated as the duration of use in days, divided by 1095. Because of rounding, not all percentages total 100.
Study Treatment
Study medication was distributed in capsules containing 100mg of celecoxib for the 685 patients assigned to 200 mg twicedaily, 200 mg of celecoxib for the 671 patients assigned to400 mg twice daily, or placebo for the remaining 679 patients.Each capsule was identical in appearance. Patients were providedmedication at six-month intervals and were instructed to taketwo capsules with food in the morning and in the evening eachday. Open-label low-dose aspirin was supplied for patients alreadytaking aspirin, and acetaminophen was supplied for the treatmentof minor pain and febrile illnesses. In compliance with a recommendationby the data and safety monitoring board, which was based onan analysis revealing that patients taking celecoxib were atincreased risk for cardiovascular events, study treatment wasdiscontinued on December 17, 2004, before all patients had completedthree years of treatment.10
Assessment of End Points and Follow-up
All primary efficacy analyses were performed on an intention-to-treatbasis, with primary end points determined for all patients bymeans of follow-up colonoscopies, regardless of whether thepatient adhered to the treatment regimen. The primary efficacyend point was the detection of an adenoma during a post-randomizationcolonoscopy. One secondary end point was the detection of advancedadenomas, defined as adenomas having any of the following characteristics:a diameter of at least 1 cm according to endoscopic measurement,villous or tubulovillous histologic appearance, high-grade dysplasia,intramucosal carcinoma, or invasive cancer. Other secondaryend points included the number of adenomas, the size of thelargest adenoma, and the adenoma burden (the sum of the diameterof all adenomas).
A complete physical examination, including clinical laboratorytests (i.e., complete blood count, serum chemical analysis,and urinalysis) and determination of vital signs, was performedat baseline and one and three years after randomization. Patientswere contacted every two months to report use of concomitantmedication and adverse events. During these discussions, patientswere also counseled to avoid nonprotocol use of aspirin andNSAIDs.
A study investigator performed a complete colonoscopy with visualizationof the cecum and endoscopic removal of all polyps one and threeyears after randomization. In cases of inadequate bowel preparationor failure to reach the cecum, year 1 colonoscopies were repeatedat the discretion of the investigator, and year 3 colonoscopieswere repeated within six weeks after the incomplete examination.A central study pathologist examined in a blinded fashion allpolyps removed during these colonoscopies. If the central studypathologist and the institutional pathologist disagreed, polypswere examined by an independent, adjudicating pathologist whowas unaware of the previous histologic diagnosis and whose opinionresolved the discrepancy. Adverse events reported by investigatorswere classified according to criteria from the Medical Dictionaryfor Regulatory Activities (MedDRA), version 8.1. Serious adverseevents were reported to a study monitor within 24 hours afteridentification by personnel at the clinical site.
Statistical Analysis
The trial was designed with a statistical power of 96 percentto detect a 35 percent reduction in the relative risk from aplacebo incidence of 40 percent11 in the proportion of patientsin whom adenomas were detected during a three-year follow-upperiod at the 0.025 (two-sided) level of significance for eachcelecoxib group as compared with the placebo group. Power calculationsassumed a dropout rate of up to 40 percent and were adjustedfor use or nonuse of aspirin. The primary end point of the detectionof an adenoma and the secondary end point of the detection ofadvanced adenomas were compared for each treatment group withthe use of the Mantel–Cox test, which is a life-tableextension of the Mantel–Haenszel statistic with stratificationfor aspirin use or nonuse at baseline.12,13,14 The Mantel–Coxprocedure also provides a summary risk ratio, which is the weightedaverage of the relative risk over the two intervals and twoaspirin strata.13,14 Patients with no follow-up colonoscopywere excluded from both intervals. A patient with a colonoscopyat year 3 but with no colonoscopy at year 1 was included inthe analysis through year 1, with the assumption that the patienthad no adenoma by year 1, and was then included in the analysisthrough year 3 according to the findings of the colonoscopyat year 3. The analyses at year 3 excluded patients with anadenoma at the year 1 colonoscopy and patients with no adenomaat year 1 and no colonoscopy at year 3.
Investigator-reported adverse events were analyzed in totaland according to prespecified categories to describe renal andhypertensive disorders, gastrointestinal ulceration and hemorrhage,and cardiovascular disorders. The analyses included all eventsoccurring after the first dose of study medication. Patientswith the end point of an adverse event were defined as thosewho had at least one of the adverse events during the courseof the study, and the risk ratio was estimated on the basisof the relative risk (adjusted for aspirin use).
An additional analysis separately examined serious cardiovascularevents, since these events were considered to be of the greatestclinical importance. These serious adverse events were thenadjudicated and analyzed by an independent cardiovascular safetyteam, as reported previously, and updated for the current reportwith the use of final study data.10 The outcome of a seriousadverse event was based on a time-to-event analysis, and theCox proportional hazards model was used to assess the risk ratio.There were no formal interim analyses of efficacy. All reportedP values for safety analyses are two-sided and not adjustedfor multiple testing. All analyses were performed with SAS software,version 8 or higher.
Results
Baseline variables were similar across all treatment groups(Table 1). Risk factors for adverse events, such as a historyof cardiovascular disease, smoking, or diabetes, were also balancedamong treatment groups. Colonoscopic end points were assessedin 1822 of 2035 patients who had undergone randomization (89.5percent); 1541 patients (75.7 percent) completed the examinationat year 3 (Figure 1). Before assessment of the end points, 10.5percent of the patients withdrew from the study. This includes1.2 percent of patients who had undergone randomization butwere lost to follow-up before a study colonoscopy was performed.Patients who did not complete the study were relatively evenlydistributed among the treatment groups (Figure 1).
Table 1. Baseline Characteristics of the Patients.
Patients who did not adhere to the use of the study drug forany reason remained in the study until the scheduled completiontime for the determination of the end points, in keeping withthe intention-to-treat principle. Approximately two thirds ofparticipants adhered to the treatment regimen at least 80 percentof the time, with no significant difference among the treatmentgroups (Figure 1). Because of an increased incidence of cardiovascularevents in the two groups treated with celecoxib, use of thestudy medication by patients who had undergone randomizationwas discontinued on December 17, 2004, in compliance with therecommendations of the data and safety monitoring board. Atthat time, 1762 patients (86.6 percent) had completed threeyears of treatment. Of the 273 patients who still had one tothree months remaining of planned use of the study drug, 199(72.9 percent) underwent study colonoscopy at year 3, and thesedata were used in the primary efficacy analyses.
The primary efficacy analysis considered adenomas detected atany time after randomization (Table 2). A small percentage ofpolyps removed (1.4 percent) were not retrieved and could notbe examined. In the placebo group, 354 patients had at leastone adenoma, as did 252 patients in the group receiving 200mg of celecoxib twice daily, and 213 patients in the group receiving400 mg of celecoxib twice daily. The estimated cumulative incidenceof the detection of one or more adenomas was 60.7 percent inthe placebo group, 43.2 percent in the group receiving 200 mgof celecoxib twice daily, and 37.5 percent in the group receiving400 mg of celecoxib twice daily. This corresponds to a riskratio of 0.67 (95 percent confidence interval, 0.59 to 0.77)in the 200-mg group and 0.55 (95 percent confidence interval,0.48 to 0.64) in the 400-mg group.
Celecoxib therapy was associated with a reduced number of advancedadenomas; 99 patients in the placebo group had at least oneadvanced adenoma during the three-year period, as compared with44 patients in the group receiving 200 mg of celecoxib twicedaily and 35 patients in the group receiving 400 mg of celecoxibtwice daily. The estimated cumulative incidence of advancedadenomas was 17.2 percent for patients receiving placebo, 7.8percent for those treated with 200 mg of celecoxib twice daily,and 6.3 percent for those treated with 400 mg of celecoxib twicedaily, corresponding to a risk ratio of 0.43 (95 percent confidenceinterval, 0.31 to 0.61) in the 200-mg group and 0.34 (95 percentconfidence interval, 0.24 to 0.50) in the 400-mg group. Subgroupanalyses according to the use or nonuse of low-dose aspirinyielded similar results (Table 2).
During the three-year study, the adenoma burden was smalleramong patients given celecoxib than among those given placebo.Patients receiving placebo had a mean (±SE) adenoma burdenof 1.3±0.1 cm, as compared with 1.0±0.1 cm amongpatients receiving 200 mg of celecoxib twice daily (P=0.004)and 0.9±0.1 cm among those receiving 400 mg of celecoxibtwice daily (P=0.002) (Figure 2).
Figure 2. Summary of Efficacy Results during the Three-Year Post-Randomization Period.
For the 2035 patients who underwent randomization, Panel A represents the estimated cumulative incidence of adenomas or advanced adenomas detected during the three years after randomization. The highest point of each bar indicates the proportion of patients with any adenoma detected, and the lower section of each bar indicates the proportion with advanced adenomas. For all adenomas, P<0.001 for the comparison with placebo for both drug doses. Advanced lesions were identified in 17.2 percent of patients taking placebo, 7.8 percent of patients taking 200 mg of celecoxib twice daily, and 6.3 percent of patients taking 400 mg of celecoxib twice daily. Panel B shows the mean (±SE) treatment-associated reduction in adenoma burden (defined as the sum of the diameter of all adenomas) among all 819 patients in whom recurrent adenomas were detected during the three years after randomization.15
Clinical variables measured during physical examinations duringthe study showed increased blood pressure among patients inthe celecoxib groups, with a change from baseline to year 3in mean blood pressure of –1.6/–3.0 mm Hg in theplacebo group, +1.0/–1.2 mm Hg in patients assigned to200 mg of celecoxib twice daily, and +3.6/–1.0 mm Hg inpatients assigned to 400 mg of celecoxib twice daily (P<0.001and P=0.01 for the comparison of the combined celecoxib groupswith the placebo group for systolic and diastolic blood pressure,respectively). No drug-associated change was observed in serumlevels of creatinine, alanine aminotransferase, or hemoglobin.
At least one adverse event was reported in 617 patients in theplacebo group (91.3 percent), 645 of those receiving 200 mgof celecoxib twice daily (94.4 percent), and 635 of those receiving400 mg of celecoxib twice daily (94.9 percent) (Table 3). Atleast one serious adverse event was reported in 18.8 percentof the patients in the placebo group, as compared with 20.4percent of those receiving 200 mg of celecoxib twice daily (riskratio, 1.1; 95 percent confidence interval, 0.9 to 1.3; P=0.5),and 23.0 percent of those receiving 400 mg of celecoxib twicedaily (risk ratio, 1.2; 95 percent confidence interval, 1.0to 1.5; P=0.06) (Table 3 and Supplementary Appendix, availablewith the full text of this article at www.nejm.org). One patientin the placebo group had grade 3 bleeding after the polypectomy— a serious complication resulting from a study colonoscopy.
Table 3. Incidence of Adverse Events after Randomization.
Nonadjudicated investigator-reported renal and hypertensivedisorders, gastrointestinal ulceration and hemorrhage, and cardiovasculardisorders were analyzed separately. No consistent dose-relatedtrend toward an increased incidence of renal and hypertensivedisorders or gastrointestinal ulceration and hemorrhage wasobserved, although aspirin users assigned to receive celecoxibshowed a trend toward increased gastrointestinal ulcerationand hemorrhage.
Cardiovascular adverse events among participants in the APCtrial have been reported previously, according to a prespecifiedanalysis of adjudicated serious adverse events,10 and were updatedwith the final study data (Table 3). This analysis indicatedan increased risk of serious cardiovascular complications (i.e.,death from cardiovascular causes, nonfatal myocardial infarction,stroke, or heart failure) among those receiving celecoxib, withrisk ratios of 2.6 (95 percent confidence interval, 1.1 to 6.1)and 3.4 (95 percent confidence interval, 1.5 to 7.9) for thelow-dose and high-dose cohorts, respectively. The absolute magnitudeof risk was greatest for patients with a history of cardiovascularevents at baseline, although no relation between cardiovascularevents at baseline and during the study was observed in patientsreceiving celecoxib. Patients who entered the study with a historyof myocardial infarction, stroke, congestive heart failure,or angina had a 3.0 percent incidence of serious cardiovascularevents if they took placebo and an 8.8 percent incidence ifthey took celecoxib at either dose (risk ratio for the comparisonwith placebo, 3.0; 95 percent confidence interval, 0.9 to 10.4).Among patients without these risk factors at baseline, 0.7 percentof those in the placebo group had a serious cardiovascular event,as compared with 2.1 percent of those in either celecoxib group(risk ratio, 3.0; 95 percent confidence interval, 1.0 to 8.7).The adjudicated analysis of data pertaining to serious adverseevents agreed substantially with nonadjudicated investigatorreports of serious adverse events related to cardiovasculardisorders.
Discussion
Previous attempts to modify the risk of sporadic adenomas throughdietary interventions have been largely unsuccessful,16,17 althoughcalcium and vitamin D supplementation demonstrated a slightbenefit.18,19,20 Randomized trials of aspirin showed a moresubstantial chemopreventive effect, with reductions of approximately20 percent among patients in whom recurrent adenomas developed.4,5,6These findings are tempered somewhat by the observation in onestudy that low-dose, but not high-dose, aspirin had an antitumoreffect.4 We studied a cohort at high risk for colorectal tumors,as evidenced by a 60.7 percent incidence of newly detected adenomasin the placebo group during the three-year period and a 17.2percent incidence of advanced lesions. Treatment with a 400-mgdose of celecoxib twice daily for three years reduced the incidenceof recurrent adenomas of any type by 45 percent and of high-risklesions by 66 percent. The effect was confirmed by a similarlydesigned independent study, the PreSAP Trial, described by Arberet al. elsewhere in this issue of the Journal.21 Patients inthe APC trial who took aspirin in addition to celecoxib didnot show greater chemopreventive benefit than those who tookcelecoxib alone.
We did not directly assess the effect of celecoxib on colorectalcancer. In the context of a program of surveillance colonoscopyto detect and remove premalignant adenomas, the benefit of celecoxibin the prevention of colorectal cancer is still unknown, andfurther research is necessary to develop a successful chemopreventiveregimen. To optimize the benefit, studies should focus on personswho are at the highest risk for colorectal cancer, since celecoxibwas particularly effective in preventing advanced lesions. Colorectalcancer takes many years to develop, and celecoxib causes regression,in addition to suppression, of established adenomas.9 Thus,additional investigations should address the value of variousdosing schedules, considering the dose-related effects on theprevention of adenomas and on adverse events.
Selective COX-2 inhibitors were developed as a safer alternativeto nonselective NSAIDs, with respect to gastrointestinal bleeding.These agents preferentially inhibit COX-2, an inducible enzymemediating inflammation and tumorigenesis, and not COX-1, theconstitutively expressed enzyme responsible for protective mechanismsin the gastric mucosa and renal vasculature. Selective COX-2inhibitors have fewer effects on gastric mucosa or plateletfunction than do the nonselective NSAIDs and, as a result, maybe associated with fewer ulcers and hemorrhagic complications.22In general, our results are consistent with these assertions,although the combination of aspirin and celecoxib may be associatedwith more gastrointestinal ulceration and hemorrhagic eventsthan is placebo.
Previously, we reported the results of a cardiovascular analysisconducted of the APC trial while the treatment portion of thestudy was still under way.10 The data were analyzed on an intention-to-treatbasis and included adjudicated serious cardiovascular events,and the analysis revealed an increased risk among patients takingcelecoxib of a combined end point including myocardial infarction,stroke, congestive heart failure, or death due to cardiovasculardisease. The updated adjudicated analysis reported here, whichincludes one additional event in the low-dose celecoxib group,also shows a dose-related increased cardiovascular risk associatedwith celecoxib. Not surprisingly, subgroup analyses suggestedthat the absolute risk of cardiovascular events was greatestamong patients with a history of cardiovascular events at baseline,but the risk ratio did not differ significantly among thosewith and those without cardiovascular events at baseline. Inaddition, blood pressure increased with the use of celecoxib,suggesting that changes in vascular tone may predispose patientsto cardiovascular events.
In summary, the use of celecoxib by patients at high risk forcolorectal neoplasia significantly reduced the proportion ofpatients with adenomas detected during a three-year study. Thistrial documented prevention of premalignant adenomas with celecoxibbut was not designed to assess effectiveness of the drug forthe prevention of colorectal cancer, and no claims about itsuse in this regard can be made from our data. Safety analysesconfirmed previous reports of an increased incidence of seriouscardiovascular events. If future study of celecoxib for thechemoprevention of colorectal cancer is pursued, the potentialaddition of this drug to an optimal endoscopic surveillanceprogram must be weighed against the known risk of serious cardiovascularevents.
Supported by the National Cancer Institute (N01-CN-95015) andPfizer.
Drs. Bertagnolli and Redston report having received grant supportfor the APC trial from Pfizer under a clinical trials agreementwith Brigham & Women's Hospital. Dr. Macrae reports havingreceived grant support for clinical trials from Pfizer. Drs.Eagle, Rosenstein, Woloj, and Ms. Tang report being employeesof Pfizer. Drs. Eagle, Rosenstein, Gordon, and Ms. Tang reportowning stock in Pfizer. Dr. Kim reports being a member of alegal-defense team for Merck. No other potential conflict ofinterest relevant to this article was reported.
* Investigators participating in the Adenoma Prevention with Celecoxib(APC) study are listed in the Appendix.
Source Information
From Brigham and Women's Hospital, Boston (M.M.B., M.R., S.D.S., J.R.S.); Pfizer, New York (C.J.E., J.T., R.B.R., G.M.W., F.B.); Memorial Sloan-Kettering Cancer Center, New York (A.G.Z.); the University of Wisconsin, Madison (K.K., T.M.H.); the Statistics Collaborative, Washington, D.C. (J.W.), the National Cancer Institute, Bethesda, Md. (D.C., W.F.A., J.L.V., E.T.H.); CCS Associates, Mountain View, Calif. (D.B.), the University of Newcastle upon Tyne, Newcastle upon Tyne, United Kingdom (J.B.); Massachusetts General Hospital, Boston (D.C.C.); Harris Methodist Hospital Fort Worth, Fort Worth, Tex. (T.D.); Regional Gastroenterology Associates of Lancaster, Lancaster, Pa. (T.R.F.), Sir Charles Gairdner Hospital, Perth, Australia (N.H.); the Royal Melbourne Hospital, Melbourne, Australia (F.M.), Nashville Medical Research Institute, Nashville (R.E.P.); Atlanta Gastroenterology Associates, Atlanta (B.S.); St. Paul's Hospital, University of Saskatchewan, Saskatoon, Canada (T.S.); and G.D. Searle, Skokie, Ill. (G.B.G.).
Address reprint requests to Dr. Bertagnolli at the Division of Surgical Oncology, Brigham and Women's Hospital, 75 Francis St., Boston, MA 02115, or at mbertagnolli{at}partners.org.
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Appendix
The following persons participated in the APC study: SteeringCommittee — M.M. Bertagnolli, E.T. Hawk, C.J. Eagle; StatisticalTeam — A.G. Zauber, K. Kim, D. Corle, R.B. Rosenstein,J. Tang, T. Hess, A. Wilton; Medical Monitors — W. Anderson,L. Doody; Central Pathology Review — M. Redston; K. Geisinger,C. Compton; Project Directors — G.M. Woloj, D. Bagheri,A. Crawford, F. Boisserie, M. Schietrum, V. Ladouceur; Dataand Safety Monitoring Board — S. Rosen (chair), L. Friedman,R. Makuch, R. Phillips, P. Taylor; Principal Investigators —United States: S. Auerbach (California Professional Research,Newport Beach), C.F. Barish (Wake Research Associates, Raleigh,N.C.), T. Barringer (Carolinas Medical Center, Charlotte, N.C.),R.W. Bennetts (Northwest Gastroenterology Clinic, Portland,Oreg.), M. Blitstein (Associates in Gastroenterology and LiverDisease, Lake Forest, Ill.), J. Bruggen (Wake Forest UniversityBaptist Medical Center, Winston Salem, N.C.), P. Carricaburu(Veterans Affairs Hospital, Sheridan, Wyo.), D. Chung (MassachusettsGeneral Hospital, Boston), F. Colizzo (Pentucket Medical Associates,Haverhill, Mass.), R. Curtis (Newton–Wellesley Hospital,Newton, Mass.), T. Dewar (Harris Methodist Hospital Fort Worth,Fort Worth, Tex.), R. DuBois (Vanderbilt University MedicalCenter, Nashville), T. Feinstat (Gastroenterology Consultantsof Sacramento, Roseville, Calif.), T.R. Foley (Regional GastroenterologyAssociates of Lancaster, Lancaster, Pa.), D. Gabbaizadeh (HuntingtonResearch Group, Huntington Station, N.Y.), J. Geenen (WisconsinCenter for Advanced Research, Milwaukee), F. Giardiello (JohnsHopkins Hospital, Baltimore), A. Goetsch (nTouch Research, Huntsville,Ala.), M. Goldberg (Regional Gastroenterology Associates ofLancaster, Evanston, Ill.), J.L. Goldstein (University of Illinoisat Chicago, Chicago), W. Harlan, III (Asheville GastroenterologyAssociates, Asheville, N.C.), R. Hogan (Gastrointestinal Associates,Jackson, Miss.), M. Kamionkowski (Gastroenterology Associatesof Cleveland, Mayfield Heights, Ohio), M. Kelfer (Fallon Clinic,West Boylston, Mass.), B. Kerzner (Health Trends Research, Baltimore),K. Kim (University of Chicago Medical Center, Chicago), I. Klimberg(Gastroenterology Associates of Ocala, Ocala, Fla.), G. Koval(West Hills Gastroenterology Associates, Portland, Oreg.), C.Krone (Advanced Clinical Therapeutics, Tucson, Ariz.), S. Krumholz(Waterside Clinical Research, West Palm Beach, Fla.), M.W. Layton(South Puget Sound Clinical Research Center, Olympia, Wash.),C. Lightdale (Columbia-Presbyterian Medical Center, New York),P.J. Limburg (Mayo Clinic, Rochester, Minn.), C. Lind (VanderbiltUniversity Medical Center, Nashville), D. Lipkis (Institutefor Health Care Assessment, San Diego, Calif.), M. Lloyd (IdahoGastroenterology, Meridian, Idaho), D. Maccini (Spokane DigestiveDisease Center, Spokane, Wash.), F. MacMillan, Sr. (PentucketMedical Associates, Haverhill, Mass.), R. Madoff (Universityof Minnesota, Minneapolis), A. Malik (Advanced Clinical Research,North Providence, R.I.), A. Markowitz (Memorial Sloan KetteringCancer Center, New York), R. Marks (Alabama Digestive ResearchCenter, Alabaster), C.J. McDougall (Manhattan Associates, NewYork), P. Miner (Oklahoma Foundation for Digestive Research,Oklahoma City), M. Murphy (Southern Digestive and Liver DiseaseInstitute, Savannah, Ga.), A. Namais (Gastrointestinal Physicians,Salem, Mass.), N. Nickl (University of Kentucky Medical Center,Lexington), M. Pochapin (Jay Monahan Center for GastrointestinalHealth, New York), R.E. Pruitt (Nashville Medical Research Institute,Nashville), J. Puolos (Cumberland Research Associates, Fayetteville,N.C.), D.S. Riff (AGMG Clinical Research, Anaheim, Calif.),R. Roman (South Denver Gastroenterology, Englewood, Colo.),L. Rubin (New Jersey Physicians, Passaic), D. Ruff (HealthcareDiscoveries, San Antonio, Tex.), M. Safdi (Consultants for ClinicalResearch, Cincinnati), J. Saltzman (Brigham and Women's Hospital,Boston), B. Salzberg (Atlanta Gastroenterology Associates, Atlanta),J.A. Sattler (Western Clinical Research, Torrance, Calif.),P. Schleinitz (Americas Doctors Research, Medford, Oreg.), J.Schwartz (Northwest Gastroenterologists, Arlington Heights,Ill.), M. Schwartz (Jupiter Research Association, Jupiter, Fla.),M. Silpa (Gastroenterology Associates of the East Bay MedicalGroup, Berkeley, Calif.), D. Silvers (Drug Research Services,Metairie, La.), D. Smoot (Howard University Cancer Center, Washington,D.C.), S. Sontag (Veterans Affairs Medical Center, Hines, Ill.),R.J. Sorrell (Gastroenterology Specialties, Lincoln, Nebr.),D. Stanton (Community Clinical Trials, Orange, Calif.), J. Sturgeon(Americas Doctors Research, Shawnee Mission, Kans.), J.P. Tracey(Hawthorne Medical Associates, North Dartmouth, Mass.), T. Werth(Charlotte Gastroenterology and Hepatology, Charlotte, N.C.),C.M. Wilcox (University of Alabama at Birmingham, Birmingham),R. Wohlman (Northwest Gastroenterology Associates, Bellevue,Wash.), S. Woods (Gastroenterology Associates of Fairfield County,Bridgeport, Conn.); United Kingdom: J. Burn, G. Brigham, (SouthCleveland Hospital, Middlesbrough); Australia: H. Ee (Sir CharlesGairdner Hospital, Nedlands, W.A.), M. Korman (Monash MedicalCentre, Clayton, Victoria), A. Lee (Concord Repatriation andGeneral Hospital, Concord, N.S.W.), B. Leggett (Royal BrisbaneHospital, Herston, Queensland), F. Macrae (Royal Melbourne Hospital,Melbourne, Victoria), L. Mollison (Freemantle Hospital, Freemantle,W.A.), N. Yeomans (Western Hospital, Footscray, Victoria), G.Young (Flinders Medical Center, Bedford, S.A.); Canada: G. Aumais(Hospital Maisonneuve-Rosemont, Montreal), R. Bailey (Hys MedicalCenter, Edmonton, Alta.), C. Bernstein (Winnipeg Health SciencesCentre, Winnipeg, Man.), L. Cohen (Sunnybrook and Women's Hospital,Toronto), C. Dallaire, R. Dube (Centre Hospitalier Universitairede Quebec, Que.), D. Morgan (McMaster University, Hamilton,Ont.), T. Sylwestrowicz (St. Paul's Hospital, Saskatoon, Sask.),G. Van Rosendaal (University of Calgary, Calgary, Alta.), S.J.Van Zantan (Queen Elizabeth II Health Sciences Centre, Halifax,N.S.).
Slattery, M. L., Fitzpatrick, F.A.
(2009). Convergence of Hormones, Inflammation, and Energy-Related Factors: A Novel Pathway of Cancer Etiology. Cancer Prevention Research
2: 922-930
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Steele, V. E., Rao, C. V., Zhang, Y., Patlolla, J., Boring, D., Kopelovich, L., Juliana, M. M., Grubbs, C. J., Lubet, R. A.
(2009). Chemopreventive Efficacy of Naproxen and Nitric Oxide-naproxen in Rodent Models of Colon, Urinary Bladder, and Mammary Cancers. Cancer Prevention Research
2: 951-956
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Kekatpure, V. D., Boyle, J. O., Zhou, X. K., Duffield-Lillico, A. J., Gross, N. D., Lee, N. Y., Subbaramaiah, K., Morrow, J. D., Milne, G., Lippman, S. M., Dannenberg, A. J.
(2009). Elevated Levels of Urinary Prostaglandin E Metabolite Indicate a Poor Prognosis in Ever Smoker Head and Neck Squamous Cell Carcinoma Patients. Cancer Prevention Research
2: 957-965
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Antonarakis, E. S., Heath, E. I., Walczak, J. R., Nelson, W. G., Fedor, H., De Marzo, A. M., Zahurak, M. L., Piantadosi, S., Dannenberg, A. J., Gurganus, R. T., Baker, S. D., Parnes, H. L., DeWeese, T. L., Partin, A. W., Carducci, M. A.
(2009). Phase II, Randomized, Placebo-Controlled Trial of Neoadjuvant Celecoxib in Men With Clinically Localized Prostate Cancer: Evaluation of Drug-Specific Biomarkers. JCO
27: 4986-4993
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Sirianni, R., Chimento, A., De Luca, A., Zolea, F., Carpino, A., Rago, V., Maggiolini, M., Ando, S., Pezzi, V.
(2009). Inhibition of Cyclooxygenase-2 Down-regulates Aromatase Activity and Decreases Proliferation of Leydig Tumor Cells. J. Biol. Chem.
284: 28905-28916
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Barry, E. L., Sansbury, L. B., Grau, M. V., Ali, I. U., Tsang, S., Munroe, D. J., Ahnen, D. J., Sandler, R. S., Saibil, F., Gui, J., Bresalier, R. S., McKeown-Eyssen, G. E., Burke, C., Baron, J. A.
(2009). Cyclooxygenase-2 Polymorphisms, Aspirin Treatment, and Risk for Colorectal Adenoma Recurrence--Data from a Randomized Clinical Trial. Cancer Epidemiol. Biomarkers Prev.
18: 2726-2733
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GEE, J. R., BURMEISTER, C. B., HAVIGHURST, T. C., KIM, K.
(2009). Cyclin-mediated G1 Arrest by Celecoxib Differs in Low-versus High-grade Bladder Cancer. Anticancer Res
29: 3769-3775
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(2009). Bile acids inhibit NAD+-dependent 15-hydroxyprostaglandin dehydrogenase transcription in colonocytes. Am. J. Physiol. Gastrointest. Liver Physiol.
297: G559-G566
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Chan, A. T., Ogino, S., Fuchs, C. S.
(2009). Aspirin Use and Survival After Diagnosis of Colorectal Cancer. JAMA
302: 649-658
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Neugut, A. I.
(2009). Aspirin as Adjuvant Therapy for Colorectal Cancer: A Promising New Twist for an Old Drug. JAMA
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Li, M., Edamatsu, H., Kitazawa, R., Kitazawa, S., Kataoka, T.
(2009). Phospholipase C{varepsilon} promotes intestinal tumorigenesis of ApcMin/+ mice through augmentation of inflammation and angiogenesis. Carcinogenesis
30: 1424-1432
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Lippman, S. M., Hawk, E. T.
(2009). Cancer Prevention: From 1727 to Milestones of the Past 100 Years. Cancer Res.
69: 5269-5284
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Yan, M., Myung, S.-J., Fink, S. P., Lawrence, E., Lutterbaugh, J., Yang, P., Zhou, X., Liu, D., Rerko, R. M., Willis, J., Dawson, D., Tai, H.-H., Barnholtz-Sloan, J. S., Newman, R. A., Bertagnolli, M. M., Markowitz, S. D.
(2009). 15-Hydroxyprostaglandin dehydrogenase inactivation as a mechanism of resistance to celecoxib chemoprevention of colon tumors. Proc. Natl. Acad. Sci. USA
106: 9409-9413
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Krum, H., Curtis, S. P., Kaur, A., Wang, H., Smugar, S. S., Weir, M. R., Laine, L., Brater, D. C., Cannon, C. P.
(2009). Baseline factors associated with congestive heart failure in patients receiving etoricoxib or diclofenac: multivariate analysis of the MEDAL program. Eur J Heart Fail
11: 542-550
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Lippman, S. M.
(2009). Cancer Prevention Research: Back to the Future. Cancer Prevention Research
2: 503-513
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Bertagnolli, M. M., Eagle, C. J., Zauber, A. G., Redston, M., Breazna, A., Kim, K., Tang, J., Rosenstein, R. B., Umar, A., Bagheri, D., Collins, N. T., Burn, J., Chung, D. C., Dewar, T., Foley, T. R., Hoffman, N., Macrae, F., Pruitt, R. E., Saltzman, J. R., Salzberg, B., Sylwestrowicz, T., Hawk, E. T., for the Adenoma Prevention with Celecoxib Study In,
(2009). Five-Year Efficacy and Safety Analysis of the Adenoma Prevention with Celecoxib Trial. Cancer Prevention Research
2: 310-321
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Marnett, L. J.
(2009). Mechanisms of Cyclooxygenase-2 Inhibition and Cardiovascular Side Effects--The Plot Thickens. Cancer Prevention Research
2: 288-290
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DuBois, R. N.
(2009). New, Long-term Insights from the Adenoma Prevention with Celecoxib Trial on a Promising but Troubled Class of Drugs. Cancer Prevention Research
2: 285-287
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Zell, J. A., Pelot, D., Chen, W.-P., McLaren, C. E., Gerner, E. W., Meyskens, F. L.
(2009). Risk of Cardiovascular Events in a Randomized Placebo-Controlled, Double-Blind Trial of Difluoromethylornithine plus Sulindac for the Prevention of Sporadic Colorectal Adenomas. Cancer Prevention Research
2: 209-212
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Goodson, N J, Brookhart, A M, Symmons, D P M, Silman, A J, Solomon, D H
(2009). Non-steroidal anti-inflammatory drug use does not appear to be associated with increased cardiovascular mortality in patients with inflammatory polyarthritis: results from a primary care based inception cohort of patients. Ann Rheum Dis
68: 367-372
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Epstein, B. J., Taylor, J. R.
(2009). Osteoarthritis: An Update on Data Currently Reshaping Practice. Journal of Pharmacy Practice
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Daniel, C. R., McCullough, M. L., Patel, R. C., Jacobs, E. J., Flanders, W. D., Thun, M. J., Calle, E. E.
(2009). Dietary Intake of {omega}-6 and {omega}-3 Fatty Acids and Risk of Colorectal Cancer in a Prospective Cohort of U.S. Men and Women. Cancer Epidemiol. Biomarkers Prev.
18: 516-525
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Lippman, S. M., Klein, E. A., Goodman, P. J., Lucia, M. S., Thompson, I. M., Ford, L. G., Parnes, H. L., Minasian, L. M., Gaziano, J. M., Hartline, J. A., Parsons, J. K., Bearden, J. D. III, Crawford, E. D., Goodman, G. E., Claudio, J., Winquist, E., Cook, E. D., Karp, D. D., Walther, P., Lieber, M. M., Kristal, A. R., Darke, A. K., Arnold, K. B., Ganz, P. A., Santella, R. M., Albanes, D., Taylor, P. R., Probstfield, J. L., Jagpal, T. J., Crowley, J. J., Meyskens, F. L. Jr, Baker, L. H., Coltman, C. A. Jr
(2009). Effect of Selenium and Vitamin E on Risk of Prostate Cancer and Other Cancers: The Selenium and Vitamin E Cancer Prevention Trial (SELECT). JAMA
301: 39-51
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FATIMA, N., CHELIUS, D., LUKE, B. T., YI, M., ZHANG, T., STAUFFER, S., STEPHENS, R., LYNCH, P., MILLER, K., GUSZCZYNSKI, T., BORING, D., GREENWALD, P., ALI, I. U.
(2009). Label-free Global Serum Proteomic Profiling Reveals Novel Celecoxib-modulated Proteins in Familial Adenomatous Polyposis Patients. Cancer Genomics Proteomics
6: 41-49
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Daniel, C. R., Bostick, R. M., Flanders, W. D., Long, Q., Fedirko, V., Sidelnikov, E., Seabrook, M. E.
(2009). TGF-{alpha} Expression as a Potential Biomarker of Risk Within the Normal-appearing Colorectal Mucosa of Patients with and without Incident Sporadic Adenoma. Cancer Epidemiol. Biomarkers Prev.
18: 65-73
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Schiffmann, S., Sandner, J., Schmidt, R., Birod, K., Wobst, I., Schmidt, H., Angioni, C., Geisslinger, G., Grosch, S.
(2009). The selective COX-2 inhibitor celecoxib modulates sphingolipid synthesis. J. Lipid Res.
50: 32-40
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FOELDVARI, I., SZER, I. S., ZEMEL, L. S., LOVELL, D. J., GIANNINI, E. H., ROBBINS, J. L., WEST, C. R., STEIDLE, G., KRISHNASWAMI, S., BLOOM, B. J.
(2009). A Prospective Study Comparing Celecoxib with Naproxen in Children with Juvenile Rheumatoid Arthritis. The Journal of Rheumatology
36: 174-182
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Ogino, S., Kirkner, G. J., Nosho, K., Irahara, N., Kure, S., Shima, K., Hazra, A., Chan, A. T., Dehari, R., Giovannucci, E. L., Fuchs, C. S.
(2008). Cyclooxygenase-2 Expression Is an Independent Predictor of Poor Prognosis in Colon Cancer. Clin. Cancer Res.
14: 8221-8227
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Garman, K. S., Acharya, C. R., Edelman, E., Grade, M., Gaedcke, J., Sud, S., Barry, W., Diehl, A. M., Provenzale, D., Ginsburg, G. S., Ghadimi, B. M., Ried, T., Nevins, J. R., Mukherjee, S., Hsu, D., Potti, A.
(2008). A genomic approach to colon cancer risk stratification yields biologic insights into therapeutic opportunities. Proc. Natl. Acad. Sci. USA
105: 19432-19437
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Subbaramaiah, K., Benezra, R., Hudis, C., Dannenberg, A. J.
(2008). Cyclooxygenase-2-derived Prostaglandin E2 Stimulates Id-1 Transcription. J. Biol. Chem.
283: 33955-33968
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Shimizu, M., Fukutomi, Y., Ninomiya, M., Nagura, K., Kato, T., Araki, H., Suganuma, M., Fujiki, H., Moriwaki, H.
(2008). Green Tea Extracts for the Prevention of Metachronous Colorectal Adenomas: A Pilot Study. Cancer Epidemiol. Biomarkers Prev.
17: 3020-3025
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Fatima, N., Yi, M., Ajaz, S., Stephens, R. M., Stauffer, S., Greenwald, P., Munroe, D. J., Ali, I. U.
(2008). Altered Gene Expression Profiles Define Pathways in Colorectal Cancer Cell Lines Affected by Celecoxib. Cancer Epidemiol. Biomarkers Prev.
17: 3051-3061
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Szabo, E.
(2008). Assessing Efficacy in Early-Phase Cancer Prevention Trials: The Case of Oral Premalignancy. Cancer Prevention Research
1: 312-315
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Wirth, L. J., Krane, J. F., Li, Y., Othus, M., Moran, A. E., Dorfman, D. M., Norris, C. M. Jr, Goguen, L., Posner, M. R., Haddad, R. I., Bertagnolli, M. M.
(2008). A Pilot Surrogate Endpoint Biomarker Study of Celecoxib in Oral Premalignant Lesions. Cancer Prevention Research
1: 339-348
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Hughes, D., Otani, T., Yang, P., Newman, R. A., Yantiss, R. K., Altorki, N. K., Port, J. L., Yan, M., Markowitz, S. D., Mazumdar, M., Tai, H.-H., Subbaramaiah, K., Dannenberg, A. J.
(2008). NAD+-Dependent 15-Hydroxyprostaglandin Dehydrogenase Regulates Levels of Bioactive Lipids in Non-Small Cell Lung Cancer. Cancer Prevention Research
1: 241-249
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Arber, N.
(2008). Cyclooxygenase-2 Inhibitors in Colorectal Cancer Prevention: Point. Cancer Epidemiol. Biomarkers Prev.
17: 1852-1857
[Abstract][Full Text]
Jankowski, J., Hunt, R.
(2008). Cyclooxygenase-2 Inhibitors in Colorectal Cancer Prevention: Counterpoint. Cancer Epidemiol. Biomarkers Prev.
17: 1858-1861
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Zauber, A. G., Bertagnolli, M. M., for the APC Trial Investigators,
(2008). Comment re: "Sporadic Aberrant Crypt Foci Are Not a Surrogate Endpoint for Colorectal Adenoma Prevention" and "Aberrant Crypt Foci in the Adenoma Prevention with Celecoxib Trial". Cancer Prevention Research
1: 216-216
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Abrams, J. A.
(2008). Review: Chemoprevention of esophageal adenocarcinoma. Therapeutic Advances in Gastroenterology
1: 7-18
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Markowitz, S. D.
(2008). Colorectal Neoplasia Goes with the Flow: Prostaglandin Transport and Termination. Cancer Prevention Research
1: 77-79
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Lance, P., Hamilton, S. R.
(2008). Sporadic Aberrant Crypt Foci Are Not a Surrogate Endpoint for Colorectal Adenoma Prevention. Cancer Prevention Research
1: 4-8
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Sporn, M. B., Hong, W. K.
(2008). Clinical Prevention of Recurrence of Colorectal Adenomas by the Combination of Difluoromethylornithine and Sulindac: An Important Milestone. Cancer Prevention Research
1: 9-11
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Cho, N. L., Redston, M., Zauber, A. G., Carothers, A. M., Hornick, J., Wilton, A., Sontag, S., Nishioka, N., Giardiello, F. M., Saltzman, J. R., Gostout, C., Eagle, C. J., Hawk, E. T., Bertagnolli, M. M.
(2008). Aberrant Crypt Foci in the Adenoma Prevention with Celecoxib Trial. Cancer Prevention Research
1: 21-31
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Meyskens, F. L. Jr., McLaren, C. E., Pelot, D., Fujikawa-Brooks, S., Carpenter, P. M., Hawk, E., Kelloff, G., Lawson, M. J., Kidao, J., McCracken, J., Albers, C. G., Ahnen, D. J., Turgeon, D. K., Goldschmid, S., Lance, P., Hagedorn, C. H., Gillen, D. L., Gerner, E. W.
(2008). Difluoromethylornithine Plus Sulindac for the Prevention of Sporadic Colorectal Adenomas: A Randomized Placebo-Controlled, Double-Blind Trial. Cancer Prevention Research
1: 32-38
[Abstract][Full Text]
Schwartz, J. I., Dallob, A. L., Larson, P. J., Laterza, O. F., Miller, J., Royalty, J., Snyder, K. M., Chappell, D. L., Hilliard, D. A., Flynn, M. E., Cavanaugh, P. F. Jr, Wagner, J. A.
(2008). Comparative Inhibitory Activity of Etoricoxib, Celecoxib, and Diclofenac on COX-2 Versus COX-1 in Healthy Subjects. J Clin Pharmacol
48: 745-754
[Abstract][Full Text]
Solomon, S. D., Wittes, J., Finn, P. V., Fowler, R., Viner, J., Bertagnolli, M. M., Arber, N., Levin, B., Meinert, C. L., Martin, B., Pater, J. L., Goss, P. E., Lance, P., Obara, S., Chew, E. Y., Kim, J., Arndt, G., Hawk, E., for the Cross Trial Safety Assessment Group,
(2008). Cardiovascular Risk of Celecoxib in 6 Randomized Placebo-Controlled Trials: The Cross Trial Safety Analysis. Circulation
117: 2104-2113
[Abstract][Full Text]
Hubner, R. A., Muir, K. R., Liu, J.-F., Logan, R. F.A., Grainge, M. J., Houlston, R. S., Members of the UKCAP Consortium,
(2008). Ornithine Decarboxylase G316A Genotype Is Prognostic for Colorectal Adenoma Recurrence and Predicts Efficacy of Aspirin Chemoprevention. Clin. Cancer Res.
14: 2303-2309
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Dhawan, D., Jeffreys, A. B., Zheng, R., Stewart, J. C., Knapp, D. W.
(2008). Cyclooxygenase-2 dependent and independent antitumor effects induced by celecoxib in urinary bladder cancer cells. Molecular Cancer Therapeutics
7: 897-904
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Papadimitrakopoulou, V. A., William, W. N. Jr., Dannenberg, A. J., Lippman, S. M., Lee, J. J., Ondrey, F. G., Peterson, D. E., Feng, L., Atwell, A., El-Naggar, A. K., Nathan, C.-A., Helman, J. I., Du, B., Yueh, B., Boyle, J. O.
(2008). Pilot Randomized Phase II Study of Celecoxib in Oral Premalignant Lesions. Clin. Cancer Res.
14: 2095-2101
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Reid, J. M., Mandrekar, S. J., Carlson, E. C., Harmsen, W. S., Green, E. M., McGovern, R. M., Szabo, E., Ames, M. M., Boring, D., Limburg, P. J., for the Cancer Prevention Network,
(2008). Comparative Bioavailability of Sulindac in Capsule and Tablet Formulations. Cancer Epidemiol. Biomarkers Prev.
17: 674-679
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Patrono, C., Rocca, B.
(2008). Aspirin: Promise and Resistance in the New Millennium. Arterioscler. Thromb. Vasc. Bio.
28: s25-s32
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Sieper, J, Klopsch, T, Richter, M, Kapelle, A, Rudwaleit, M, Schwank, S, Regourd, E, May, M
(2008). Comparison of two different dosages of celecoxib with diclofenac for the treatment of active ankylosing spondylitis: results of a 12-week randomised, double-blind, controlled study. Ann Rheum Dis
67: 323-329
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Aneja, A., Farkouh, M. E.
(2008). Review: Adverse cardiovascular effects of NSAIDs: driven by blood pressure, or edema?. Ther Adv Cardiovasc Dis
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Amrite, A. C., Kompella, U. B.
(2008). Celecoxib Inhibits Proliferation of Retinal Pigment Epithelial and Choroid-Retinal Endothelial Cells by a Cyclooxygenase-2-Independent Mechanism. J. Pharmacol. Exp. Ther.
324: 749-758
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Kesari, S., Schiff, D., Henson, J. W., Muzikansky, A., Gigas, D. C., Doherty, L., Batchelor, T. T., Longtine, J. A., Ligon, K. L., Weaver, S., Laforme, A., Ramakrishna, N., Black, P. McL., Drappatz, J., Ciampa, A., Folkman, J., Kieran, M., Wen, P. Y.
(2008). Phase II study of temozolomide, thalidomide, and celecoxib for newly diagnosed glioblastoma in adults. Neuro Oncol Duke
10: 300-308
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Joshi, G. P., Gertler, R., Fricker, R.
(2007). Cardiovascular Thromboembolic Adverse Effects Associated with Cyclooxygenase-2 Selective Inhibitors and Nonselective Antiinflammatory Drugs. Anesth. Analg.
105: 1793-1804
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Sagiv, E., Rozovski, U., Kazanov, D., Liberman, E., Arber, N.
(2007). Gene Expression Analysis Proposes Alternative Pathways for the Mechanism by Which Celecoxib Selectively Inhibits the Growth of Transformed but not Normal Enterocytes. Clin. Cancer Res.
13: 6807-6815
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Beliveau, R., Gingras, D.
(2007). Role of nutrition in preventing cancer. cfp
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Kuriki, K., Wakai, K., Matsuo, K., Hiraki, A., Suzuki, T., Yamamura, Y., Yamao, K., Nakamura, T., Tatematsu, M., Tajima, K.
(2007). Gastric Cancer Risk and Erythrocyte Composition of Docosahexaenoic Acid with Anti-inflammatory Effects. Cancer Epidemiol. Biomarkers Prev.
16: 2406-2415
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Liu, M., Yang, S.-C., Sharma, S., Luo, J., Cui, X., Peebles, K. A., Huang, M., Sato, M., Ramirez, R. D., Shay, J. W., Minna, J. D., Dubinett, S. M.
(2007). EGFR Signaling Is Required for TGF-beta1 Mediated COX-2 Induction in Human Bronchial Epithelial Cells. Am. J. Respir. Cell Mol. Bio.
37: 578-588
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Logan, R.
(2007). Commentary: Preventing colorectal cancer with aspirin what next?. Int J Epidemiol
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Buchanan, F. G., Holla, V., Katkuri, S., Matta, P., DuBois, R. N.
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