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J Thorac Cardiovasc Surg 2003;125:1363-1371
© 2003 The American Association for Thoracic Surgery

Surgery for Acquired Cardiovascular Disease

Radial artery patency and clinical outcomes: Five-year interim results of a randomized trial

From the Department of Cardiac Surgery,^a Austin and Repatriation Medical Centre, Melbourne, Victoria, Australia, The Statistical Consulting Centre,^b University of Melbourne, Parkville, Victoria, Australia, and the Departments of Cardiology^c and Intensive Care and Research,^d Austin and Repatriation Medical Centre, Melbourne, Victoria, Australia.

Supported by a grant from Ethicon, a division of Johnson & Johnson Medical. Also supported by the Sir Edward Dunlop Medical Research Foundation.

Received for publication April 17, 2002. Revisions requested June 18, 2002; revisions received Aug 5, 2002. Accepted for publication Aug 15, 2002. Address for correspondence: Brian F. Buxton, MD, Director of Cardiac Surgery, HS-5, Austin Hospital, Heidelberg, Victoria 3084, Australia. (E-mail: brian.buxton{at}austin.org.au).

	Abstract

Top Abstract Introduction Material and methods Results Discussion Conclusion Appendix: Discussion References

 
Objective: This study was undertaken to compare elective angiographic patency and cardiac event-free survival of the radial artery graft with that of the free right internal thoracic artery or saphenous vein during a 10-year period after primary coronary artery bypass surgery.
Methods: This prospective, randomized, single-center trial was conducted on two groups of patients undergoing primary coronary artery bypass surgery. In a younger group (group 1, n = 285, <70 years), the radial artery was compared with the free right internal thoracic artery. In an older group (group 2, n = 153, ≥70 years), the radial artery was compared with the saphenous vein. The trial conduit was grafted to the largest available coronary artery other than the left anterior descending coronary artery. Angiography was scheduled at intervals between 0 and 10 years according to a second random assignment. Patients were followed up at yearly intervals to assess clinical outcomes. Clinical outcomes were analyzed on an intent-to-treat basis during the 10-year follow-up with time-related analyses. This interim study reports angiographic and clinical outcome results during the first 5 years.
Results: Graft patency estimates were as follows: 0.95 (95% confidence interval 0.85-0.99) in 39 radial arteries versus 1.0 in 29 right internal thoracic arteries (P = .4) in group 1, and 0.86 (95% confidence interval 0.67-0.99) in 24 radial arteries versus 0.95 (95% confidence interval 0.83-0.99) in 22 saphenous veins (P = .5) in group 2. Cardiac event-free survival estimates were as follows: 0.91 (95% confidence interval 0.76-0.99) for the radial artery versus 0.82 (95% confidence interval 0.63-0.99) for the right internal thoracic artery (P = .7) in group 1, and 0.84 (95% confidence interval 0.64-0.99) for the radial artery versus 0.89 (95% confidence interval 0.72-0.99) for the saphenous vein (P = .9) in group 2.
Conclusion: The 5-year interim results do not support the hypothesis that the radial artery has superior patency to or is associated with fewer clinical events than free right internal thoracic artery or saphenous vein grafts.

	Introduction

Top Abstract Introduction Material and methods Results Discussion Conclusion Appendix: Discussion References

 

View larger version (93K): [in this window] [in a new window]   Dr Buxton and Dr Hare

Studies indicate that the SV has excellent early patency results; however, between 5 and 10 years there is accelerated graft atheroma and increasing rates of graft failure, so that at 10 years approximately 40% of grafts have failed. This has led to a search for arteries that could be used to replace the SV. These arteries include the right gastroepiploic artery, inferior epigastric artery, and radial artery (RA). All have demonstrated excellent patency rates in symptom-directed studies; however, there are few data about their durability when studied by elective angiography.

The RA was first used in the early 1970s by Carpentier and colleagues. ⁵ It has many desirable characteristics. It is readily available in a length suitable for bypassing most coronary lesions. It is similar in diameter to the proximal coronary arteries, marginally larger than the ITA and smaller than most SV grafts. The use of the RA was revisited by Acar and colleagues ⁶ and others, ^7,8 who discovered the excellent late patency in a number of Carpentier and colleagues' early series. These patients had been receiving calcium channel blockers.

RA grafts are receiving increasing acceptance, and their removal is associated with few hand complications, such as ischemia and donor site hematoma, ^9,10 with a lower sternal infection rate, ¹¹ and with excellent early clinical results. ^12,13 Fremes and associates, ⁸ Dietl and Benoit, ¹⁴ and Bhan and colleagues ¹⁵ reported low rates of recurrence of angina, myocardial infarction, and death. Recent angiographic studies have shown that the RA achieves excellent short-term patency when used as a coronary artery bypass conduit. ^14,16-25 Although results of RA grafting are encouraging, most angiographic results are from small numbers of patients who are seen again because of evidence of ischemia. There are few long-term patency rates of RA grafts studied electively in symptom-free patients, and little scientific evidence comparing the RA with the right ITA used as a free graft or with the SV. There is one ongoing randomized study originating from Toronto evaluating the fate of the RA. This study, which is comparing patency between the RA and SV in the same patient, is known as the Radial Artery Patency Study (RAPS). ²⁶ However, there are no previous studies in which patients have been prospectively randomly assigned to receive either the RA or another bypass conduit. In this study, the Radial Artery Patency and Clinical Outcome (RAPCO) Study, patients are randomly assigned to receive either RA or, in two separate stratified groups, right ITA or SV.

	Material and methods

Top Abstract Introduction Material and methods Results Discussion Conclusion Appendix: Discussion References

 
Study design
This is a prospective, randomized, single-center trial, stratified into a group younger than 70 years (group 1), in which the RA patency was compared with that of the free right ITA, and a group aged 70 years or more (group 2), in which RA patency was compared with that of the SV graft. Programmed angiography was performed at a predetermined interval between 0 and 10 years according to a second random assignment. In addition, a 5-year angiogram was offered to all patients.

Hypotheses
The following hypotheses were tested:

1. Angiographic patency of the RA graft is superior to that of the free right ITA or SV graft.
   
2. Patients who receive RA grafts have clinical outcomes superior to those of patients who receive free right ITA or SV grafts.
   

Specific aims
This study was undertaken to compare elective angiographic patency of the RA with those of the free right ITA and SV during 5 to 10 years after surgery and to assess the survival, myocardial infarction, and reintervention rates in patients with RA grafts versus those with right ITA and SV grafts.

Entry criteria
Male or female patients younger than 80 years undergoing elective primary isolated coronary artery bypass surgery and requiring more than one bypass conduit were eligible for the study. An ejection fraction greater than 35% and at least one non-LAD vessel with a proximal stenosis of at least 70% and a diameter of at least 1.5 mm were required.

Exclusion criteria
General exclusions
Patients were excluded because of body mass index greater than 35 kg/m², renal impairment with serum creatinine level greater than 300 µmol/L, lung disease with a forced expiratory volume in 1 second less than 1 L, associated major illnesses (eg, malignancy) with the survival expected to be less than 10 years, concomitant cardiac disease (such as valve disease or a left ventricular aneurysm), chronic heart failure, emergency presentation, or myocardial infarction less than 1 week before surgery.

Specific exclusions
Patients were deemed ineligible if either of the proposed randomly assigned grafts was not available. The RA was not harvested if the recovery time on the modified Allen test was longer than 10 seconds in the nondominant hand. ²⁷ The right ITA was not removed in patients with poor lung function, chest wall trauma, or previous chest wall radiotherapy. The SV was not used if it was varicose, if the ankle/brachial systolic blood pressure index was less than 0.75, or if peripheral pulses were absent.

Random assignment
All patients received an in situ left ITA graft to the LAD. The choice of the second conduit was determined by random assignment. If additional grafts were required, the SV was used. There were two groups, according to age and current practice. Group 1 consisted of patients younger than 70 years. The trial conduit was either right ITA (control graft) or RA (experimental graft). This trial graft was anastomosed to the largest available non-LAD vessel (Table 1).

Random numbers were generated from the Minitab statistical package (Minitab, Inc, State College, Pa) and placed in sealed envelopes. The patient's name, the date, and the name of the person performing the random assignment were recorded on each envelope before it was opened. Random assignment was undertaken by the University Statistical Consulting Center and kept at arm's length from the clinical staff involved. Patient information and consent forms were approved by the institution's human research ethics committee.

Surgical technique
the RA was removed from the nondominant arm. The RA was dilated in situ with an intraluminal ejection of 4 mL of a 1-mM solution of papaverine (40 mg in 100 mL) with a mixture of 50% blood and Ringer's lactate solution. This was injected retrogradely into the distal end of the RA, which was clipped and left for 5 minutes to dilate under arterial pressure. The artery was removed and stored in a bath of the same solution. The SV and the right ITA were dilated with the same papaverine mixture and stored in an identical manner to the RA. All operations were performed with cardiopulmonary bypass. The technique of RA harvest and coronary artery bypass grafting has been described previously elsewhere. ^31-34 The left ITA and right ITA were mobilized with a wide pedicle. The left ITA was left in situ for anastomosis to the LAD; the right ITA was used as a free graft. The trial graft was sutured to the largest available non-LAD coronary artery and grafted proximally to the aorta as a standard aorta-coronary bypass graft. All anastomoses were performed by staff surgeons. Sequential anastomoses were permitted between the diagonal artery and the LAD and when using nonstudy SV grafts.

Postoperative management
All patients were given milrinone in a loading dose of 25 µg/kg in 15 minutes followed by 0.25 µg/(kg · min) to produce a cardiac index of 2.5 to 3 L/(m² · min). Milrinone was discontinued if the cardiac index exceeded 3 L/(m² · min), the mean blood pressure was less than 70 mm Hg, or the peripheral vascular resistance was less than 1000 dynes · s · cm^-5. Milrinone was continued for the first 12 to 18 hours. After that, oral amlodipine at 2.5 to 5 mg daily was commenced and continued for 6 months. Aspirin at 100 mg per day was commenced the day after surgery and continued indefinitely.

Angiography
Patients underwent a second random assignment for the timing of the elective coronary angiogram and graft study during the 10 years after surgery. The frequency of protocol-directed angiography was weighted toward the end of the study, because it was anticipated that there would be relatively few events in the first 5 years and thus most of the information would come from the latter part of the study. Ten percent of the patients were randomly assigned to undergo angiography within 12 months from the time of surgery, 10% at 2 years after the operation, 20% at 5 years, 30% at 7 years, and 30% at 10 years (Figure 1). In addition to the protocol-directed angiography program, all patients were offered an angiogram at 5 years after the operation. Left ventriculography was not performed routinely.

View larger version (13K): [in this window] [in a new window]   Fig. 1. Protocol-directed angiography schedule. Each patient was randomly allocated one of five schedule dates: 1, 2 5, 7, and 10 (range) years. Angiograms were weighted to latter part of 10-year study.

Clinical data collection
After discharge from the hospital, those patients recruited into both the control and experimental groups received standard follow-up care. All patients were contacted yearly after their coronary artery bypass surgery. At the time of contact, the clinical nurse consultant obtained data regarding patient survival, myocardial infarction, and further revascularization (surgical or percutaneous intervention). Angiography was performed on an outpatient basis to investigate the patency of the RA, right ITA, and SV grafts. Patients underwent yearly clinical review by a cardiac surgeon. Survival was confirmed with the National Death Index, a register of all deaths. ³⁶ All data are stored in a Visual Fox Pro database (Microsoft Corporation, Redmond, Wash).

Major outcome measures
A major end point of the study was angiographic patency of the RA, right ITA, and SV grafts during a 10-year period after surgery. This interim study assesses the outcomes of 114 angiograms performed during the first 5 years of the study. Other major outcomes were survival and cardiac event-free survival. Death, perioperative or subsequent, was defined as all-cause mortality, and cardiac event-free survival was defined as survival with freedom from myocardial infarction, percutaneous intervention, or reoperation.

Statistical analysis
All patients randomly assigned were included in the analyses. Patients whose chosen graft conduit was found during the operation to be unsuitable were included in the clinical analysis on an intent-to-treat basis. The focus of this interim report is 5-year graft patency and cardiac event-free survival. Most angiograms in this study to date were performed in the latter part of the follow-up period. Categoric patency, clinical end points, all-cause mortality, and cardiac event-free survival were analyzed by standard survival analysis techniques. Kaplan-Meier estimates were obtained for each of the two arms of both trials. Because of the random assignment, a simple comparison of the two treatment groups is unbiased. The log-rank statistic was used to test for differences between the survival curves.

Estimation of sample size
The 5-year patency was expected to be high for both trial and control grafts in both groups. In the younger patients (group 1), in whom the RA is being compared with the right ITA, 154 patients in each group are sufficient to detect a true difference of patency percentages of at least 10% when the patency is 85% in one group and 95% in the other, by a 2-sided test with a power of 80% and the best approximation for comparing two proportions. ³⁷ In the older patients (group 2), in whom the comparison is between the RA and SV, to detect a difference of at least 15% for a 2-sided test with a power of 80%, 84 patients are required in each arm to detect a difference between a patency of 80% for one treatment and a patency of 95% for the other.

Enrollment
Between June 1996 and February 2002, a total of 1004 patients were assessed but were not randomly assigned because they failed to meet the entry criteria, for example, the lack of availability of one of the potential trial grafts or presence of one of the major clinical exclusions. Seventy-eight patients met the entry criteria but refused to comply with the follow-up criteria of yearly visits and undergoing at least one postoperative angiogram. Four hundred thirty-eight patients, 285 in group 1 and 153 in group 2, were randomly assigned to receive RA grafting or a control graft. In group 1, 140 patients were randomly assigned to RA grafting and 145 to right ITA grafting. In group 2, 73 patients were randomly assigned to RA grafting and 80 were to receive SV grafts. All 438 patients were included for analysis of survival and event-free survival outcomes according to intent to treat.

Angiography enrollment
Thirty-two patients were withdrawn from the graft patency study at the time of surgery because of the poor quality of the randomly assigned conduit (eg, damaged during removal) or extensive calcification. A further 8 patients were withdrawn because the appropriate coronary artery was not grafted and 2 patients withdrew consent, leaving 396 patients who were suitable for a scheduled angiogram during the 10-year study. The decision by the surgeon to alter the operation or grafting strategy, (for example, to operate off-pump in 2 patients, to repair a left ventricular aneurysm, to use a sequential graft, or to perform a proximal anastomosis with the left ITA or the addition of an arterial graft conduit instead of the SV as a subsequent graft) was not considered an indication for removal.

This 5-year interim graft patency study reports the Kaplan-Meier graft patency estimates of 114 angiograms: 53 protocol-directed angiograms and 61 optional angiograms. The current status of the angiography program is summarized in Tables 2A and 2B.

	Results

Top Abstract Introduction Material and methods Results Discussion Conclusion Appendix: Discussion References

View larger version (12K): [in this window] [in a new window]   Fig. 2. Five year Kaplan-Meier estimates of graft patency. A, Comparison of RA grafts with free right ITA (RITA) grafts. B, Comparison of RA grafts with SV grafts

View larger version (13K): [in this window] [in a new window]   Fig. 3. Five-year Kaplan-Meier estimates of cardiac event-free survival. A, Group 1, RA versus free right ITA (RITA). B, Group 2, RA versus SV.

	Discussion

Top Abstract Introduction Material and methods Results Discussion Conclusion Appendix: Discussion References

There are a number of reports of RA graft patency in patients who underwent angiography directed by symptoms suggestive of ischemia. ^{14,17,18,22,23,25,39} There have been few published results of elective angiograms of the RA when used as a coronary artery bypass graft. The angiographic patency rate from the RAPCO study is similar to other reported RA patency results of studies that were based on ischemic symptoms. Our early SV graft patency appears superior to that recorded previously, suggesting that the choice of a large target artery and factors currently used to protect grafts, such as vasodilators and 3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitors, may have improved the outcomes of both the control and study grafts.

There are two randomized trials that have analyzed graft patency as an end point, one published, ⁴⁰ and the other in progress. ²⁶ Fremes ²⁶ and the RAPS investigators from Sunnybrook (Toronto, Ontario, Canada) have enrolled 560 patients in a prospective multicenter randomized clinical trial comparing the RA patency with that of the SV when grafted to the right or circumflex coronary arteries. This study is comparing the 8- to 12-month protocol-directed angiographic patency of the RA versus the SV coronary bypass grafts, with each patient serving as his or her own control. The primary end point of the study is the proportion of RA and control SV grafts occluded at the time of angiography. TIMI flow and graft stenoses are also recorded. Because the RA and the control SV are used in all patients, however, it will be difficult to attribute a clinical outcome to the use of a particular graft. In contrast, the RAPCO trial has both graft patency and survival end points. The trial was designed with two strata, a younger and older group, which reflects current clinical practice. This study is designed to answer the following questions: Should the surgeon choose an RA or ITA graft in young patients? Should the surgeon favor the RA rather than SV in older patients? There is one trial graft in each patient, compared with two trial grafts in the RAPS. Thus the RAPCO angiographic study is relatively underpowered compared with the RAPS; the power calculation is not time dependent, and therefore it would be expected that if a true difference existed, a longer follow-up period would be required to achieve a statistically significant result. This 5-year interim report represents a small proportion of the expected angiographic results. Compliance with the protocol-directed angiography schedule in the first year was about 80%, although some missed the scheduled date. The clinical end points of survival and freedom from myocardial infarction, percutaneous intervention, and reoperation are robust end points that will continue to be recorded during the next decade.

The categoric angiographic end point of graft failure, defined as occlusion or a stenosis of at least 70%, corresponds with the accepted threshold for intervention in native coronary arteries. Graft failure is defined by occlusion and absence of TIMI 3 flow in the RAPS. ²⁶ In the RAPCO, trial the string sign was defined as uniform narrowing (>50%) of a graft with delayed opacification of the target artery (TIMI 1 or 2 flow) and recorded as graft failure. Similarly, Fremes ²⁶ defines the string sign as occlusion of the graft. Graft disease may involve the proximal and distal anastomoses. Anastomotic disease may be the result of poor surgical technique, the healing and remodeling process, or disease in the native coronary artery or aorta. Anastomotic disease in the RAPCO trial has been flagged and will be analyzed separately. The angiographic committee will make recommendations on the presurgical entry angiographic criteria and the management of anastomotic disease. Quantitative coronary angiography will be subsequently undertaken to provide an independent assessment of graft disease.

Protocol-directed angiography, unlike symptom-directed angiography, provides an opportunity to analyze the rate of graft failure in patients both with and without symptoms. There is a paucity of elective angiographic results of conduits in coronary artery surgery. Symptom-directed angiography may select patients with severe disease, thus introducing a bias in the patency rate. Previous data from symptom-directed angiography in our unit suggested that there would be few graft failures in the first 5 years after surgery with SV or ITA grafts; more graft patency end points are expected in the second 5 years. Therefore optional 5-year angiograms, which likewise should not introduce bias, were included in this interim analysis. Furthermore, the 61 optional angiograms provide angiographic data for these elderly patients with associated morbidity, some of whom will die before the protocol-directed angiogram. The choice remains to analyze the protocol-directed angiograms separately from the optional 5-year angiograms. The addition of a second or even a third angiogram to the protocol-directed study has the benefit of allowing assessment of the progression of graft disease.

Time-related analyses of clinical events such as death, reoperation, or myocardial infarction provide an accurate assessment that can be used to predict complication rates and outcomes in a similar population. However, the use of actuarial techniques to assess graft patency is based on the assumption that the event occurs at the time of the angiogram, and absolute failure rates therefore cannot be defined. Graft failure, which may be silent, can occur any time from implantation up to angiography, and rates of failure will therefore be underestimated. Comparisons of relative failure rates of trial versus control grafts are valid, because the same technique and time intervals were used to assess both trial and control grafts.

Improved graft durability would be expected to correlate with fewer clinical events and improved survival. This association is often delayed. Improved survival has been observed with in situ ITAs relative to SV grafts; a decrease in clinical events from the use of a second arterial graft or a different type of arterial conduit is likely to be less dramatic. Those patients who died or were unavailable for follow-up and not identified by the regular clinical follow-up mechanism are readily identified through the Australian National Death Index, ³⁶ thus providing reliable survival data.

	Conclusion

Top Abstract Introduction Material and methods Results Discussion Conclusion Appendix: Discussion References

 
The 5-year interim results of the RAPCO study do not support the hypotheses that the RA has a superior patency to the free right ITA and the SV when used as a coronary artery bypass graft and that it is associated with fewer clinical events. On the basis of the previous experience of persisting patency of arterial compared with SV grafts, however, the continued evaluation of the RA is justified.

	Appendix: Discussion

Top Abstract Introduction Material and methods Results Discussion Conclusion Appendix: Discussion References

 
Dr Stephen E. Fremes (Toronto, Ontario, Canada). Buxton and colleagues have contributed greatly to our knowledge of arterial conduits. They have successfully enrolled in this randomized clinical trial a total of 438 patients, all from their own institution, which is a remarkable accomplishment. They have completed recruitment to this challenging long-term study. The rate of follow-up angiography is good to date, the preliminary results are interesting, and the final results should be valuable.

Having said that, I have several questions about the study. This Australian study compares the RA with the free ITA in group 1 and with SV in group 2. I would expect the RA to have better patency than a venous graft both early and late, although I would expect the patencies of the free ITA and RA grafts to be similar. The 5-year observational studies by Acar, ¹⁷ Possati, ²⁴ and Iaco ²² suggest that the late patency of the RA will be approximately 85% to 90%. Previously reported data from Buxton and colleagues' institution for the free ITA are similar. Dr Buxton, please describe the rationale for your hypothesis regarding the relative patencies of the RA and free ITA for this trial. The study is powered to test a difference in patency of 90% versus 80% favoring the RA. Next, it has been our preference to sew the RA directly to the aorta. On the other hand, we frequently avoid direct aortic anastomosis with the free ITA, often sewing it to a vein hood or to the body of a thoracic artery as a composite. Dr Buxton, please describe your preferred method of RA and free ITA construction. Do you believe that proximal aortic anastomosis may favor the RA versus the free ITA group?

I have two questions about the sample size. First, was it inflated to adjust for expected protocol violations, late refusals of research angiography, death, and so on? Second, did you calculate what difference in clinical events could be tested in your study?

A big surprise for me was the graft patency results for the study SVs. Only 1 of 22 grafts was occluded or significantly narrowed. Although the sample size was small, the 95% confidence interval surrounding that estimate was 83% to 99%, which is pretty good, and in the range of what we would expect from RAs and free ITAs. I think it will be interesting to see what happens to this group with additional numbers. Dr Buxton, would you comment first on why this result is as good as it is and second on the results of the nonstudy SV grafts?

Dr Buxton. Let me start with the rationale for using the right ITA for comparison with the RA. Although we expect the results to be very similar, that is not quite the same as knowing that they are similar. Within our group, we are committed to extensive, if not total arterial, grafting. We would have had trouble with enrollment of younger patients in this study if the control group had received only a single ITA graft and the balance in SV grafts. Our cardiologists believe the propaganda, which has made it more difficult to enroll young patients in studies that involve multiple venous grafts. Therefore a younger group with a left ITA and a second arterial graft (RA or right ITA) was studied separately.

The reason that we chose direct aorta-coronary anastomosis was to standardize the technique. In this way, we avoided having some grafts attached proximally to the ITA and some from the aorta. We have great experience with right ITA grafting. As you point out, most of those early right ITAs were attached to the aorta. Provided the aorta is not calcified, one can anastomose any of the grafts to the aorta. I accept that there may be a prejudice favoring the slightly larger RA in that setting. However, the aim of this trial has been to compare grafts in the way they are used in clinical practice, and we still anastomose many grafts directly to the aorta.

Regarding the protocol, I prefer "amended" rather than "protocol violation." In some study patients, the early angiogram was delayed beyond the scheduled date. Furthermore, it is likely that some patients in their late 70s might enter and not complete the trial. We added two additional optional angiograms at 5 and 10 years to compensate for these losses. The only problem is that this might create bias. My view is that it does not, but I accept the criticism. I notice in your own protocol that you have a similar additional 5- and 10-year studies. An additional 10% of patients above the estimated sample size were enrolled to compensate for any unexpected losses. Although the power calculations for graft patency and clinical events were similar, there are likely to be more clinical events than graft failures.

The low failure rate of the control SV grafts is fascinating. There appears to have been a change in the SV. You may recall from the article that we prepared the control SV in an identical manner to that of the experimental arterial graft, and further we used a careful harvest technique. A senior surgeon often removed trial grafts, which were bathed in the vasodilator papaverine, a phosphodieserase III inhibitor that enhances the nitric oxide pathway, to dilate all conduits before implantation. Also, and perhaps most important, many of these patients had their cholesterol and triglyceride levels kept to much lower levels than perhaps we have been accustomed to historically.

Dr Fremes. There were two other things. First, what was the difference in clinical events you could see with your study? Second, how were the nonstudy SV grafts?

Dr Buxton. There have been no differences so far in any of the three major clinical end points. The differences in clinical outcomes that could be detected in this study are similar to those of the graft patency study.

To summarize the patencies at 5 years of all trial and nontrial grafts in the study, in the left ITA the patency was 97% (n = 87), in the free right ITA it was 91% (n = 22), in the RA it was 86% (n = 49). In nonstudy SVs it was 84% (n = 85) compared with 94% (n = 22) for the study of SVs.

	Acknowledgments

 
The following participants are acknowledged. Surgeons: George Matalanis, MD, Siven Seevanayagam, MD, Julian Gaer, MD, Anand Dixit, MD, and Masashi Komeda, MD, PhD; cardiologists involved with angiography: Paul Kertes, MD, Keith Woollard, MD, George Proimos, MD, Ron Dick, MD, John Brennan, MD, Anthony Jackson, MD, Robert Chan, MD, Angas Hamer, MD, Les Oliver, MD, Jennifer Johns, MD, Tony Dortimer, MD, Alexander Black, MD, David Clark, MD, Ben Sia, MD, Jack Federman, MD, Allan Appelbe, MD, Julie A. Bradley, MD, and Christopher Webb, MD; intensive care unit physicians: Larry McNicol, MD, and Laurie Doolan, MD; editorial staff: Mardi A. Malone; and research nurses: Louise Mullaly, RN, Meg Storer, RN, Cath Cowie, RN, and Catherine Folvig, RN.

	Footnotes

 
Read at the Eighty-second Annual Meeting of The American Association for Thoracic Surgery, Washington, DC, May 5-8, 2002.

	References

Top Abstract Introduction Material and methods Results Discussion Conclusion Appendix: Discussion References

 

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