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J Thorac Cardiovasc Surg 1996;112:69-78
© 1996 Mosby, Inc.

SURGERY FOR ACQUIRED HEART DISEASE

DIFFERENT CLINICAL OUTCOME IN CORONARY ARTERY BYPASS WITH SINGLE AND SEQUENTIAL VEIN GRAFTS: A FIFTEEN-YEAR FOLLOW-UP STUDY

Received for publication Feb. 15, 1995 Accepted for publication Oct. 3, 1995. Address for reprints: B. L. van Brussel, MD, Diaconessenhuis, Department of Cardiology, PO Box 90.052, 5600 PD Eindhoven, The Netherlands.

Abstract

Objective: In trying to answer the question about the controversial use of sequential grafts, we determined the long-term clinical outcome of patients in whom coronary artery bypass was done with different types of vein grafts. Methods: A total of 428 consecutive patients who underwent isolated coronary artery bypass with vein grafts between April 1, 1976, and April 1, 1977, were prospectively observed. In these patients three groups could be defined with single grafts only, sequential grafts only, and combined single and sequential grafts. Follow-up was 99.8% complete and averaged 15.4 years for the survivors. The Kaplan-Meier method and multivariate analysis done with the Cox regression model were used for survival, myocardial infarction, reintervention, and "any event." Results: Perioperative mortality and perioperative myocardial infarction rate were not statistically different among the three groups. During follow-up more myocardial infarctions (hazard ratio: 2.06; 95% confidence interval: 1.08 to 3.93; p = 0.0293) or any events (hazard ratio: 1.54; 95% confidence interval: 1.01 to 2.36; p = 0.0450) occurred in patients with sequential grafts only than in patients with single grafts only. Conclusion: Although more complete revascularization was obtained in patients with sequential vein grafts only, more events during a 15-year follow-up occurred in these patients than in patients with single vein grafts only. (J THORAC CARDIOVASC SURG 1996;112:69-78)

In 1971 coronary artery bypass surgery with sequential vein grafts was introduced by Flemma and associates. ¹ Use of these grafts made it easier to achieve complete revascularization. Nevertheless, the use of sequential vein grafts has been the subject of controversy because a severe stenosis of the main stem of a graft may jeopardize a greater part of the myocardium than is true if single vein grafts are used.

In the present era of coronary artery surgery the internal thoracic artery is preferred because of its higher patency rate. However, in many patients with arterial conduits, coronary artery bypass with single or sequential vein grafts (or both) will continue to be used to achieve complete coronary revascularization. Therefore, even today it remains important to study the long-term clinical outcome as a function of the type of vein grafts used during coronary bypass. The literature contains only a few studies on this subject. ^2,3

We report the long-term results of three different patient groups (patients with single vein grafts only [group I] or sequential vein grafts only [group II] and patients with combined single and sequential vein grafts [group III]) belonging to a consecutive patient group who underwent isolated coronary artery bypass grafting with only vein grafts in 1 year and whom we followed up prospectively.

Methods

The angiographic and clinical definitions and the patient group have been described in detail before. ⁴ In brief, the study group consisted of 428 consecutive patients, 383 men and 45 women, with an average age of 52.6 years (range 20 to 74 years) who underwent isolated coronary artery bypass operations with vein grafts between April 1, 1976, and April 1, 1977, at the St. Antonius Hospital, Nieuwegein, The Netherlands. Nearly half of the patients (49%) had had a myocardial infarction and more than 2% had a history of heart failure before the operation. In 61% of the study population the severity of preoperative angina was class III or IV according to the Canadian Cardiovascular Society, in 48% three-vessel disease was demonstrated at coronary angiography, and in 12% left main coronary artery disease was also present. In 21% of the study group left ventricular function was moderately or severely diminished. In 26% of the patients unstable angina pectoris was the indication for surgical therapy.

Our study population was divided into three groups according to the grafts used during the operation: patients with single vein grafts only (group I, n = 188), patients with sequential vein grafts only (group II, n = 60), and patients with combined single and sequential vein grafts (group III, n = 180).

Surgical technique.
Intermittent aortic occlusion with moderate hypothermia (25° to 28° C) alternating with deep hypothermia (20° to 22° C) at clamping was used for the operations. Single coronary artery bypass grafts with or without sequential grafts were placed. Only the lower leg saphenous vein was used for the grafts. Side-to-side anastomoses were used in this early experience of sequential grafting—longitudinal side-to-side vein-to-artery anastomoses in 51%, diamond-shaped anastomoses in 22%, oblique anastomoses in 19%, and other types of anastomoses in 8%. All end-to-side anastomoses were constructed longitudinally. An average of 3.2 coronary anastomoses per patient was made. A left ventricular aneurysm resection was performed in 25 patients. Complete revascularization, defined as revascularization of all coronary arteries with a diameter of at least 1 mm and a stenosis of 50% or more supplying a vital left ventricular wall segment, was achieved in 78% of the study group.

Follow-up and data collection.
Several follow-up methods were used simultaneously to provide the most complete information possible. All patients were followed up at the hospital's outpatient clinic or the outpatient clinic of the referring cardiologists (or at both sites) on the anniversary of the operation. The common "closing data" method was used in 1992 to close follow-up of all patients. Because of the combined follow-up methods, all patients except one, who went abroad and was lost to follow-up 7 years after operation, were traced for the common closing date of April 1, 1992. Exact information about the clinical events studied was obtained in all patients. Our follow-up was 99.8% complete. The mean duration of follow-up for the survivors was 15.4 years.

Statistical analysis.
The following clinical events were studied: overall mortality, acute myocardial infarction, and reintervention (reoperation or percutaneous transluminal coronary angioplasty, or both). Patients not surviving the operation were excluded from statistical analysis. Therefore 415 patients were followed up. Perioperative myocardial infarction was likewise not included in statistical analysis of myocardial infarction during follow-up.

To identify prognostic covariates that might have explained differences among the groups, we estimated survival curves by the method described by Kaplan and Meier ⁵ from the baseline variables as described in Table I. Postoperative events are calculated from life-table analysis and presented as percentages ± standard deviation. Differences in survival times between groups were calculated by the log rank and the Wilcoxon tests (SAS. PROC.LIFETEST, SAS Institute, Inc., Chicago, Ill.). All variables with a significance level of p < 0.10 in at least one of these univariate tests were selected for entry in a multivariate proportional hazards model as proposed by Cox ⁶ (COX.PROC.PHREG, SAS Institute, Inc., Chicago, Ill.). The variables age and gender but also all other important clinical variables were always included. Proportionality of hazards was checked by means of the log cumulative hazard plot (log cumulative hazard plotted against log time) for each of the variables entered in the model. This plot will convert the vertical proportionality of the original plots into a vertical equidistance, therefore permitting visual assessment. All curves were approximately parallel and equidistant vertically for the various levels of the variable. We concluded that the underlying hazards were proportional and the Cox model was appropriate. ⁷ Subsequently, we were able to predict the independent influence of the single or sequential technique on different cardiac events in this population. The risk of one group having a clinical event compared with the risk in another group is reflected by the hazard ratio.

General results.
In Table I the presence of the different baseline variables in the three patient groups and the results of the univariate analysis among these three groups are given. In group I (patients with single vein grafts only) the lowest mean number of distal anastomoses per patient was found. In group II (patients with sequential vein grafts only) the highest percentage of patients had complete revascularization. In group III (patients with single and sequential vein grafts) a more severe degree of coronary atherosclerosis was present at operation, because a high percentage of patients had three-vessel disease and left main coronary artery disease. There was a significant difference in the mean extracorporeal circulation time and in the mean extracorporeal circulation time per distal anastomosis among the three groups.

Mortality.
Thirteen patients died during or within 30 days after the operation, seven patients belonging to group I (4%) and six patients to group III (3%). This difference in hospital mortality among the three patient groups was not statistically significant. (According to Fisher's exact method, two-sided for group I versus group II, group II versus group III, and group I versus group III, the p values are, respectively, 0.20, 0.34, and 1.00.)

In group I the mortality was constant in the first 6 years after operation, with a mean annual mortality rate of 0.7%. After these years mortality increased, especially from the tenth year after operation, with a mean annual mortality rate of 3%. In group II mortality was constant in the first postoperative decade. The annual mean mortality rate was 1.5%. In the twelfth year after operation mortality increased to a yearly mean of 4.5%. Mortality was constant in group III in the first 7 years after operation, with a mean yearly mortality of 1.3%. In the following years the annual mortality rose to a mean of 4.4%. These figures lead to a 15-year survival of 57.3% ± 3.8%. In groups I and II, 15-year survivals were 67.9% ± 3.5% and 65% ± 6.2% (mean ± standard deviation), respectively (Fig. 1).

View larger version (18K): [in this window] [in a new window]   Fig. 1. Actuarial survival of patients with single grafts only, patients with sequential grafts only, and patients with single and sequential grafts.

In the first 5 years after operation the myocardial infarction rate was low in all three patient groups. Thereafter the mean annual myocardial infarction rate increased, especially in group II (to 3.2%). In groups I and III the rates were 2% and 1.4%, respectively. Fifteen years after the operation, 80.6% ± 3.5% of group I, 66% ± 7.1% of group II, and 78.3% ± 3.9% of group III remained free from myocardial infarction. The occurrence of a myocardial infarction 15 years after operation, then, is nearly identical in patients of groups I and III, but an infarction occurs more frequently in patients of group II (sequential grafts only) (Fig. 2).

View larger version (18K): [in this window] [in a new window]   Fig. 2. Actuarial freedom from myocardial infarction in patients with single grafts only, patients with sequential grafts only, and patients with single and sequential grafts.

View larger version (19K): [in this window] [in a new window]   Fig. 3. Actuarial freedom from reintervention in patients with single grafts only, patients with sequential grafts only, and patients with single and sequential grafts. n.s., Not significant.

View larger version (21K): [in this window] [in a new window]   Fig. 4. Actuarial freedom from any event in patients with single grafts only, patients with sequential grafts only, and patients with single and sequential grafts.

View larger version (15K): [in this window] [in a new window]   Fig. 5. Hazard ratio and 95% confidence limits and their statistical significance for different events between patient group with sequential grafts only versus patient group with single grafts only.

On the introduction of sequential coronary grafting, Flemma and associates ¹ considered the decrease in extracorporeal circulation time but also the high flow representing "a most thorough and extensive myocardial revascularization" as the greatest advantages in relation to the surgical technique of single grafts. Flow in a graft is a major determinant of both early and late graft patency. ⁸ Flow and therefore graft patency depend on distal runoff. Thus it is useless to separately revascularize smaller coronary artery branches because in most cases they do not have adequate runoff to support these single grafts. ⁹ If more than one coronary arterial communication is used along the graft course, the peripheral coronary resistance is less and flow should be increased. ¹⁰ Through this higher flow the main bypass trunk stays open and may assist in maintaining patency of side-to-side anastomoses to arteries with a poor runoff. ¹¹ Even with this kind of operation a prophylactic graft might be used to protect a patient if sclerosis progresses. ¹² Although Sewell ¹³ in 1978 doubted whether complete revascularization was useful, other investigators later proved that this approach provided a better survival and a lower myocardial infarction rate, with less angina pectoris. ^14-19

Some of these benefits can be found again in our study. In the patient group in which only sequential vein grafts were used (group II), a significantly shorter extracorporeal circulation time per distal anastomosis was seen. In the same group a significantly higher percentage of patients received complete revascularization.

On the long run, we found that the risk of cardiac events during follow-up was greater in patients with combined single and sequential vein grafts, and especially in patients with sequential vein grafts alone. Multivariate analysis shows that the risk of having a myocardial infarction or any event was significantly increased during 15 years of follow-up in patients with sequential vein grafts only. For a long time Bigelow and coworkers ² were the only ones reporting on long-term follow-up of coronary artery bypass with sequential vein grafts. The 3-year survival of 130 patients with sequential and single grafts operated on before June 1972 was 88%. The survival of 71 patients who received multiple single grafts in the same period was 78%. The hospital mortality of 6% for both groups was included in that 3-year survival figure. In our study the numbers are 96% (sequential and single grafts) and 98% (multiple single grafts), not including the hospital mortalities of 4% and 0%, respectively. Recently, long-term results of single versus sequential grafts of the Thoraxcenter in Rotterdam were reported by Meeter and colleagues, ³ who divided their patients into a group with single grafts only and a group with mainly sequential grafts. The overall perioperative mortality was 1.9% and not different between the two groups. The survivals after 10 years in the two groups were 71% and 72%, respectively. In our study these numbers are 85% and 79%, but the Rotterdam study included only patients with three-vessel disease or disease of the left main-stem coronary artery and depressed left ventricular function. As was the case in our study, the mortality in both groups in the Thoraxcentre study increased from the seventh year after operation, but there was no difference in survival between the two groups. Neither the need for reoperation or coronary angioplasty nor the frequency of angina pectoris between the groups was different after 10 years. The occurrence of myocardial infarction was not analyzed in that study. In an unpublished study, Sergeant and associates showed that sequential grafting was an incremental risk factor for survival, postoperative acute myocardial infarction, and the need for reintervention. ²⁰

The results of our multivariate analysis surprised us. In view of the completeness of revascularization achieved in the patient group with sequential grafts only, we had expected their long-term clinical outcome to be better than that of the patients belonging to the other groups. A clear explanation for this result could not be found. It is true that the patients with sequential vein grafts were the first to be operated on with this new surgical technique. Therefore a learning phase for the surgeons could be expected. It is unlikely, however, that this would result only in the occurrence of a myocardial infarction during late follow-up. Moreover, none of the patients with only sequential grafts died during the operation, and only one patient had a perioperative myocardial infarction.

Since the time that our patients were operated on, much information has been published about the relation between the surgical technique of sequential bypass grafting and the angiographic patency. ^8,21-28 However, no direct relation between angiographic patency and clinical event rates has been provided, and no prospective randomized trial comparing coronary artery bypass with single versus sequential vein grafts has been undertaken.

Some critical remarks must be made about our own study. A disadvantage was that the patients in this study were not randomly assigned to receive either a single vein graft or sequential vein grafts. This decision may have been influenced by unknown factors that independently predicted clinical events. Second, clinical characteristics varied among the three groups, but with multivariate analysis we adjusted for these confounding factors. Through this statistical method we were able to show that notwithstanding the completeness of revascularization, significantly more patients with only sequential vein grafts had a myocardial infarction during follow-up compared with the patients belonging to the other two groups. Finally, inasmuch as the sample sizes were too small to allow subgroup analysis, it is possible that some types of sequential grafts provide good function.

In conclusion, our data add new information to the few published reports on the clinical outcome of coronary artery bypass with sequential vein grafts as compared with single vein grafts. We determined that the event rate is higher for the occurrence of myocardial infarction or any other event, although complete coronary revascularization had been achieved more often.

At present, sequential grafts continue to be used. However, the results of this study do not allow conclusions regarding circumstances mandating that sequential vein grafts not be used.

Acknowledgments

We thank Mrs. L. Jacobs, Mr. T. Voskuil, and Mr. C. van Cuyk for their support in the research and data collection.

Footnotes

From the Department of Cardiology, Diaconessenhuis,^a Eindhoven, and the Departments of Cardiology,^b Clinical Epidemiology,^c and Cardiothoracic Surgery,^d St. Antonius Hospital, Nieuwegein, The Netherlands.

References

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