Methods: We retrospectively reviewed 587 patients who underwent CABG surgery with concomitant CE (CABG+CE group) and patch plasty between March 2000 and April 2010. We compared these patients with randomly selected 600 patients who had undergone CABG surgery without CE (CABG only group) in the same period. A comprehensive evaluation of the groups was achieved by subgroup analysis with large series of parameters from patient files.
Results: The patients in the CABG+CE group were older than the patients in the CABG only group (59.6±10.3 vs. 61.3±7.3; p<0.001). The incidence of atherosclerotic risk factors, triplevessel disease, and complaints of unstable angina pectoris were slightly higher in CABG+CE group (p<0.05). Concomitant CE prolonged cross-clamp and cardiopulmonary bypass time. Also, postoperative total entubation time (12±10.3 vs. 12±7.4 hours; p<0.05) was significantly longer (p<0.05). The rates of myocardial infarction (p=0.006) and intra-aortic balloon pump requirement (p<0.001) were significantly higher in the CABG+CE group. The mortality rate did not differ between the two groups.
Conclusion: Indication for CE must still be handled restrictively. Endarterectomy should be performed only on occluded, nearly occluded, and/or severely calcified vessels with long-range stenosis if regular anastomoses to these vessels seem to be technically impossible. Endarterectomy should not be considered as a substitute for CABG, and should be performed by an experienced surgical team. However, CE might not be associated with additional mortality compared to conventional coronary bypass surgery.
In 1957, Bailey was the first to describe the use of CE in humans without a cardiopulmonary bypass (CPB) or an associated procedure.[2] Despite its success in relieving angina, there was also substantial morbidity and mortality.[3] Perhaps this is why surgeons are still performing this technique on a highly selective basis when no other alternatives are present. It is difficult to precisely define the ideal patient to undergo CE, and this results in variable indications and the occasional indiscriminate use of this surgical procedure. Thus, CE has been characterized as a risk factor for mortality and morbidity associated with myocardial revascularization. In other words, the use of CE is still controversial, and its results are highly variable due to a lack of uniformity.[4] The purpose of our study was to investigate the impact of comorbidity factors and CE on morbidity and mortality in patients who underwent concomitant CABG and CE and retrospectively compare the results with those for whom only CABG was performed.
Table 1: Demographic characteristics
Surgical indications and procedure
Although a preoperative prediction for CE can
be obtained from the coronary angiogram, the final
decision is made intraoperatively on the basis of
technical considerations. We did not consider complete
occlusion on the angiogram as a definite indication for
CE. Furthermore, we occasionally were confronted
with coronary arteries that could not be revascularized
with a plain CABG procedure after performing an
arteriotomy, even when a preoperative angiography
showed a graftable vessel.
Coronary endarterectomies were considered when the vessel supplying a viable myocardium was suitable for grafting and when multiple, discrete obstructing lesions or diffuse atherosclerosis that was significantly compromising the internal lumen was exhibited (<1 mm).
All of the operations were performed using CPB and mild-to-moderate systemic hypothermia (28-32 °C) via a standard median sternotomy. In addition, full heparinization was performed to achieve an activated clotting time (ACT) goal of >400 seconds. Furthermore, myocardial protection was achieved using the combination of antegrade and retrograde cardioplegia, and topical myocardial cooling was used in all cases. According to the preoperative planning regarding the number of vessels to be bypassed, the grafts were prepared by considering the age of the patient and the location of the lesion. The grafts used for CABG in order of frequency were the left internal mammary artery (LIMA), the saphenous vein (SVG), the right internal mammary artery (RIMA), and the radial artery (RA). The gastroepiploic artery was also used in one patient in the CABG + CE group. The CEs were performed on the left anterior descending artery (LADA) and the right coronary artery (RCA) as well as the diagonal (D), posterolateral (PL), posterior descending (PD), obtuse marginal (OM), circumflex (Cx), and right marginal branch of right coronary artery.
The operative technique used for the CE was identical for all of the vessels. Each endarterectomy were performed manually, and the arteriotomy was one and a half times the diameter of the target vessel. However, in a few cases, the incision was extended by up to 35 mm. Moreover, the incision in the conduit was extended to match the arteriotomy, and the conduit was anastomosed to the endarterectomized artery in an end-to-side fashion. We refrained from repairing the arteriotomy with a vein patch. The CE was performed by opening the diseased vessel directly over the plaque and then carefully dissecting the plaque from the arterial wall using a fine dissector to develop a plane between the adventitia and the plaque. The atheroma was then held with a pair of blunt forceps from the middle, and gentle-sustained traction was applied cranially.[5,6] Only 1-2 cm of the proximal core was dissected, and the atheroma was divided at this level in order to not compromise the blood flow through the graft because of the competitive flow between the graft and the native vessel. Adequate distal clearance was ensured by a tapered, thinned-out distal segment of the intima at the end of the atheroma. However, when this was not possible, the arteriotomy was extended distally until a satisfactory result was obtained. After extraction, retrograde cardioplegia was used to flush out any debris that might have embolized distally. A visible flow of retrograde cardioplegia indicated a successful endarterectomy. In addition, we did not introduce a probe distally to avoid dissection at the site where the endarterectomy was terminated.
Definitions, postoperative care, and follow-up
We compared the two groups in terms of
postoperative MI, total intubation time, length of ICU
and hospital stays, and complications (e.g., bleeding,
reoperation, and the necessity for cardiopulmonary
resuscitation).
We used the term “arrhythmia” to refer to postoperative atrial fibrillation or flutter, heart blockage that required a pacemaker, and ventricular arrhythmias. “Renal failure” was defined as postoperative renal insufficiency that was managed medically. The term was also used for patients with no prior history of renal disease that required dialysis or for those with renal disease that worsened after the surgery. Neurological complications that were encountered included cerebrovascular hemorrhage, transient ischemic attacks, and permanent strokes, whereas sternal/leg wound infections requiring antibiotics and/or surgical intervention, mediastinitis, and sepsis were classified as infective complications. We also saw respiratory complications such as pneumonia, acute respiratory distress syndrome (ARDS), tracheostomy insertions, pleural effusion requiring drainage, and reintubation as well as gastrointestinal system complications like mesenteric ischemia and gastrointestinal bleeding in the study participants. In addition, we defined “in-hospital mortality” as all mortalities within the same postoperative admission period regardless of the length of hospital stay.
Our anticoagulation protocol was to reverse the heparin completely at the end of the operation, and all patients were given low-molecular-weight heparin (LMWH) subcutaneously six hours later in the ICU if the amount of chest tube drainage was less than 100mL/hr prior to discharge. Postoperatively, all of the patients received acetylsalicylic acid (300 mg daily), and for those who had an endarterectomy, clopidogrel was also administered (75 mg daily) on the first postoperative day to prevent the early initiation of coagulation cascade that often occurs with CEs.[7]
Statistical analysis
The data was analyzed via the SPSS for Windows
version 11.5 software program (SPSS Inc., Chicago,
IL, USA). The Shapiro-Wilk test was used to
assess the normality of the continuous variables,
and the statistics for these variables were given as
mean ± standard deviation (SD) or median (minimummaximum).
The categorical variables were shown
as the number of cases and percentages. In addition,
Student’s t-test was used to evaluate the significance
of the differences in normal distribution between the
two groups, and the Mann-Whitney U test was used
to analyze the statistical differences of the changing
variables between the groups since these were not
normally distributed. Furthermore, the categorical
variants were evaluated using Pearson’s chi-square or
Fisher’s absolute value chi-square test, and the results
were considered to be statistically significant with a
p value of <0.05.
Regarding the coronary angiographic distribution of the lesions among the coronary arteries, no differences were detected between the two groups (p>0.05) However, the incidence of three-vessel disease was markedly higher in the CABG alone group (p<0.05), whereas the number of totally (100%) occluded LADAs and RCAs were higher in the CABG + CE group. In addition, a preoperative echocardiographic evaluation showed that there were no statistically significant differences in the left ventricular ejection fraction (LVEF) rates between the two groups (p=0.093) (Table 2).
Table 2: Number of diseased vessels as seen on preoperative coronary angiography
The most common artery to undergo CE was the RCA (n=309; 52%) followed by the LADA (n=185; 31.5%) (Table 3).
Table 3: Arteries which received coronary artery endarterectomies
We also found that the postoperative total intubation times were longer in the CABG alone group than the CABG + CE group (12±10.3 vs. 12±7.4 hours, respectively; p<0.05), but the cross-clamp and CPB times were significantly longer in the patients who underwent both procedures (p<0.05). Furthermore, more patients in the CABG alone group underwent emergency CABG, but the difference between the two groups was not statistically significant (p>0.05). We also found that the duration of ICU and hospital stays were longer in CABG alone group (Table 4).
Table 4: Operative and postoperative variables
The postoperative complications are listed in Table 5. The MI rate (p=0.006) and the number of patients who needed an intra-aortic balloon pump (IABP) (p<0.001) were significantly higher in the CABG alone group. Six patients (1%) in this group also experienced cardiac arrest due to low cardiac output in the ICU. Unfortunately, they did not respond to cardiopulmonary resuscitation and they did not survive. In addition, eight (1.3%) patients in the CABG + CE group died following multi-organ failure (MOF) in the postoperative period. However, the mortality rate did not differ between the two groups.
Since the first application of CE by Bailey et al.[2] in 1957, the interest in this procedure has dramatically increased in spite of the unsatisfactory initial results, and the concomitant application of CABG and CE has proven to be beneficial for certain types of patients.[8,9] Traditionally, CE is the preferred method for the extraction of occluding atheromatous material and is defined as the removal of the intima and most of the media from the coronary artery surface to restore an intact lumen for the continuity of the blood flow.[10-12] However, there h as been an ongoing controversy regarding the applicability and indications for CE as an adjunct to CABG. While CE is theoretically simple, the higher rates of morbidity and mortality have provoked frequent criticism, leading to a secondary role of importance for this procedure.[13,14] Despite technological developments in alternative techniques such as transmyocardial laser revascularization and angiogenic growth factor therapies, CE is still the preferred method for treating diffusely diseased vessels as an adjunct to conventional CABG.
The frequency of patients undergoing CABG together with CE varies in the literature between 3.7% and 42%[4,15] This wide r ange is mainly due to the absence of certain indications for the CE procedure. In our department, the combination of CE and CABG was performed in 587 patients over approximately a 10-year period, meaning that 4.56% of all patients underwent this type of surgery. The indication for CE was handled restrictively as we agree with LaPar et al.[16] that CE should be considered when the vessel supplying a viable myocardium is suitable for grafting with a minimum diameter of 2 mm or when multiple, discrete obstructing lesions or diffuse atherosclerosis significantly compromise the internal lumen (<1 mm).
The aortic cross-clamp and CPB times were longer in the CABG + CE group in our study, which can be explained by several factors, such as the severity of atherosclerosis, localization, and high rate of calcification. As shown in Table 2, the majority of the patients for whom both CABG and CE were performed suffered from three-vessel disease, which resulted in almost four bypass grafts per patient. Furthermore, as seen in Table 3, a right coronary endarterectomy was performed in 52.6% of the patients in the CABG + CE group, which is usually considered to be the most technically challenging and time-consuming localization. As previously mentioned, CE was only performed when standard anastomosis was impossible. In other words, it was the last resort for revascularizing the ischemic myocard. Furthermore, the need for CE also pointed out the presence of end-stage CAD in the CABG + CE group.
Many different techniques can be used to perform CE, including the injection of cardioplegia into the endarterectomy region, the application of carbon dioxide (CO2) to elevate the endarterectomy plaque,[17] and open or closed endarterectomies. Our study supports the previous literature[3] which showed no significant differences in postoperative morbidity and mortality for the various surgical techniques, but others have indicated that an open endarterectomy is a safer technique.[14,<1r8>] Following an endarterectomy of the LADA or other vessels, there are many ways of reconstructing the arteriotomy, for example saphenous vein patch plasty. It may seem like a simple and easy technique, but when the LIMA is not used, it is a disadvantage. Another common technique involves the direct partial closure of the arteriotomy and coronary endarterectomy segment with the LIMA anastomosis site remaining open. However, the disadvantage of this procedure is the high degree of thrombogenicity produced by the primarily closed arteriotomy.[18,19] A third surgical option is closing the arteriotomy with patch plasty via the saphenous vein followed by the anastomosis of the LIMA to the saphenous patch. However, this technique is also highly thrombogenic.[16,20]
The need for emergency CABG was higher in the CABG + CE group, but this did not reach a level of statistical significance. However, this finding offers another clue regarding the progressive severity of CAD.
In addition, there were longer ICU and hospital stays in the patients who underwent both CABG and CE because the rates of postoperative MI and IABP were significantly higher in this group. However, considering the presence of severe end-stage atherosclerosis as well as these patients’ increased preoperative risk, the prolonged stays were not surprising.
Walley et al.[7] determined that vessels which undergo CE manifest important changes that lead to the predisposed formation of thrombosis in the first postoperative week. Afterwards, the fibrous mural thrombi and thrombocytes become organized in the region of the CE, resulting in the advancement of the vascularization process. By the 50th postoperative day, the concentric and uniform reformation of the luminal layer and accumulation of collagen rich deposits can be seen. Medical treatment is the best way to avoid this sequence of events. Livesay et al.[21] and Chesebro et al.[22] recommended the use of acetylsalicylic acid and dipyridamol postoperatively, whereas Ferraris et al.[14] prescribed the use of warfarin for three months after the surgery. Gill et al.[23] recommended another treatment option in which intravenous heparin was infused for the first 48 hours postoperatively, which was then followed by the use of thienopyridine derivatives (ticlopidine and clopidogrel). At our facility, we prefer to administer LMWH at the postoperative sixth hour followed by acetylsalicylic acid and clopidogrel on the first postoperative day.
In addition to LIMA patch plasty, which is our preferred surgical approach for CE, the three factors described by Loop et al.[4] represent the mainstay of our strategy. The first factor is that careful dissection is crucial in order to free up the plaque entirely and protect the integrity of the coronary artery. The second factor is that entire extraction of the atherosclerotic plaque is mandatory for better postoperative myocardial perfusion, and the third is that appropriate postoperative medical treatment is necessary to inhibit the formation of postoperative thrombosis.
In support of our findings, the results of Okur et al.[24] were similar to our study in that angiographic studies performed on the patients demonstrated beneficial late results. Furthermore, they found low mortality and high graft patency after concomitant CABG and CE bypass surgery.
Declaration of conflicting interests
The authors declared no conflicts of interest with
respect to the authorship and/or publication of this
article.
Funding
The authors received no financial support for the
research and/or authorship of this article.
1) Frazier OH, Cooley DA, Kadipasaoglu KA, Pehlivanoglu
S, Lindenmeir M, Barasch E, et al. Myocardial
revascularization with laser. Preliminary findings.
Circulation 1995;92:II58-65.
2) Bailey CP, May A, Lemmon WM. Survival after coronary
endarterectomy in man. J Am Med Assoc 1957;164:641-6.
3) Schmitto JD, Kolat P, Ortmann P, Popov AF, Coskun KO,
Friedrich M, et al. Early results of coronary artery bypass
grafting with coronary endarterectomy for severe coronary
artery disease. J Cardiothorac Surg 2009;4:52.
4) Atik FA, Dallan LA, de Oliveira SA, Lisboa LA, Platania
F, Cabral RH, et al. Myocardial revascularization with
coronary endarterectomy. Stratification of risk factors for
early mortality. Arq Bras Cardiol 2000;75:269-80.
5) Goldman BS, Christakis GT. Endarterectomy of the
left anterior descending coronary artery. J Card Surg
1994;9:89-96.
6) Vohra HA, Kanwar R, Khan T, Dimitri WR. Early and late
outcome after off-pump coronary artery bypass graft surgery
with coronary endarterectomy: a single-center 10-year
experience. Ann Thorac Surg 2006;81:1691-6.
7) Walley VM, Byard RW, Keon WJ. A study of the sequential
morphologic changes after manual coronary endarterectomy.
J Thorac Cardiovasc Surg 1991;102:890-4.
8) Effler DB, Groves LK, Sones FM Jr, Shirey EK.
Endarterectomy in the treatment of coronary artery disease.
J Thorac Cardiovasc Surg 1964;47:98-108.
9) Longmire WP Jr, Cannon JA, Kattus AA. Direct-vision
coronary endarterectomy for angina pectoris. N Engl J Med
1958;259:993-9.
10) Loop FD. Resurgence of coronary artery endarterectomy. J
Am Coll Cardiol 1988;11:712-3.
11) Stevens JH, Burdon TA, Peters WS, Siegel LC, Pompili
MF, Vierra MA, et al. Port-access coronary artery bypass
grafting: a proposed surgical method. J Thorac Cardiovasc
Surg 1996;111:567-73.
12) Trehan N, Mishra A. Endarterectomy complex coronary
reconstructions. In: Buxton B, Frazier OH, Westaby S,
editors. Ischemic heart disease surgical management. New
York: Mosby; 1999. p. 221-8.
13) Tiruvoipati R, Loubani M, Lencioni M, Ghosh S, Jones PW,
Patel RL. Coronary endarterectomy: impact on morbidity and mortality when combined with coronary artery bypass
surgery. Ann Thorac Surg 2005;79:1999-2003.
14) Ferraris VA, Harrah JD, Moritz DM, Striz M, Striz D,
Ferraris SP. Long-term angiographic results of coronary
endarterectomy. Ann Thorac Surg 2000;69:1737-43.
15) Qureshi SA, Halim MA, Pillai R, Smith P, Yacoub MH.
Endarterectomy of the left coronary system. Analysis of a 10
year experience. J Thorac Cardiovasc Surg 1985;89:852-9.
16) LaPar DJ, Anvari F, Irvine JN Jr, Kern JA, Swenson BR,
Kron IL, et al. The impact of coronary artery endarterectomy
on outcomes during coronary artery bypass grafting. J Card
Surg 2011;26:247-53.
17) Barmada B, Diethrich EB. Gas endarterectomy with distal
bypass of the coronary arteries. Heart Lung 1975;4:397-401.
18) Sirivella S, Gielchinsky I, Parsonnet V. Results of coronary
artery endarterectomy and coronary artery bypass grafting
for diffuse coronary artery disease. Ann Thorac Surg
2005;80:1738-44.
19) Shapira OM, Akopian G, Hussain A, Adelstein M, Lazar
HL, Aldea GS, et al. Improved clinical outcomes in patients
undergoing coronary artery bypass grafting with coronary endarterectomy. Ann Thorac Surg 1999;68:2273-8.
20) Sundt TM 3rd, Camillo CJ, Mendeloff EN, Barner HB,
Gay WA Jr. Reappraisal of coronary endarterectomy for the
treatment of diffuse coronary artery disease. Ann Thorac
Surg 1999;68:1272-7.
21) Livesay JJ, Cooley DA, Hallman GL, Reul GJ, Ott DA,
Duncan JM, et al. Early and late results of coronary
endarterectomy. Analysis of 3,369 patients. J Thorac
Cardiovasc Surg 1986;92:649-60.
22) Chesebro JH, Fuster V, Elveback LR, Clements IP, Smith
HC, Holmes DR Jr, et al. Effect of dipyridamole and aspirin
on late vein-graft patency after coronary bypass operations.
N Engl J Med 1984;310:209-14.