Article

lock Open Access lock Peer-Reviewed

1

Views

ARTIGO ORIGINAL

Patologia do enxerto no momento da coleta: impacto na sobrevida a longo prazo

Shi-Min YuanI; Yun LiII; Yan Hong BenIII; Xiao Feng ChengIV; Da Zhu LiV; De Min LiVI; Hua JingIV

DOI: 10.5935/1678-9741.20140118

RESUMO

OBJETIVO: Este estudo tem como objetivo apresentar a patologia do enxerto no momento da coleta e do impacto na sobrevida a longo prazo.
MÉTODOS: Os remanescentes de pontes de safena de 66 pacientes consecutivos com doença arterial coronária que receberam uma cirurgia de revascularização coronariana foram investigados patologicamente, e os fatores de risco preditivos e a sobrevivência foram analisados.
RESULTADOS: Alterações degenerativas da artéria medial, com ou sem proliferação da íntima estavam presentes em 36,8%, 37,8% e 35,6% de pontes da artéria torácica interna esquerda (ATIE), artéria radial e veia safena. Houve dois (3,0%) óbitos hospitalares e nove (14,1%) óbitos tardios. A regressão logística multinomial revelou que alterações patológicas na ATIE, dislipidemia, história de angioplastia/stent implantação coronariana transluminal percutânea e Y-enxerto foram significativos fatores de risco preditivos que influenciam negativamente a sobrevivência a longo prazo dos pacientes. Análise de sobrevida de Kaplan-Meier revelou que a sobrevivência a longo prazo de pacientes com alterações patológicas da ATIE foi significativamente reduzida em comparação com aqueles sem (74,1% vs. 91,4%, P=0,002), considerando que não foram observadas diferenças na sobrevivência de longo prazo entre pacientes com e sem alterações patológicas dos enxertos da artéria radial ou de veia safena.
CONCLUSÃO: As alterações patológicas podem se desenvolver na revascularização no momento da coleta. As modificações ultraestruturais sutis e as expressões de reguladores do tônus vascular podem ser responsáveis pela patência tardia do enxerto. As alterações patológicas da ATIE no momento da coleta, em vez do enxerto da artéria radial ou da veia safena, podem afetar significativamente a sobrevida de longo prazo. Manobra não traumática da ATIE na coleta, bom controle da dislipidemia e para evitar uso de enxertos compostos pode ser útil na manutenção da arquitetura dos enxertos.

ABSTRACT

OBJECTIVE: This study aims to present the graft pathology at the time of harvest and its impact on long-term survival.
METHODS: The remnants of the bypass grafts from 66 consecutive patients with coronary artery disease receiving a coronary artery bypass grafting were investigated pathologically, and pertinent predictive risk factors and survival were analyzed.
RESULTS: Medial degenerative changes with or without intimal proliferation were present in 36.8%, 37.8% and 35.6% of left internal mammary artery (IMA), radial artery and saphenous vein grafts. There were 2 (3.0%) hospital deaths and 9 (14.1%) late deaths. Multinomial logistic regression revealed left IMA pathological changes, dyslipidemia, history of percutaneous transluminal coronary angioplasty/stent deployment and Y-graft were significant predictive risk factors negatively influencing the patients' long-term survival. Kaplan-Meier survival analysis revealed that the long-term survival of patients with left IMA pathological changes were significantly reduced compared with those without (74.1% vs. 91.4%, P=0.002); whereas no differences were noted in long-term survivals between patients with and without pathological changes of the radial arterial or saphenous vein grafts.
CONCLUSION: Pathological changes may be seen in the bypass graft at the time of harvest. The subtle ultrastructural modifications and the expressions of vascular tone regulators might be responsible for late graft patency. The pathological changes of the left IMA at the time of harvest rather than those of the radial artery or saphenous vein graft affect significantly long-term survival. Non-traumatic maneuver of left IMA harvest, well-controlled dyslipidemia and avoidance of using composite grafts can be helpful in maintaining the architecture of the grafts.

ABREVIAÇÕES E ACRÔNIMOS

CABG: Coronary artery bypass grafting

eNOS: Endothelial nitric oxide synthase

IMA: Left internal mammary artery

LAD: Left anterior descending coronary artery

RA: Radial artery

SVG: Saphenous vein graft

INTRODUCTION

The left internal mammary artery (IMA) has gained popularity as an arterial graft for coronary artery bypass grafting (CABG) as it provides the gold standard left IMA-left descending coronary artery (LAD) bypass[1]. The radial artery (RA) has become a graft of choice for CABG since its first clinical use by Carpentier in 1971[2]. The graft flow patterns have been evaluated in several studies intraoperatively[3] or postoperatively[4]. Even though the RA graft showed better flow than the IMA and saphenous vein graft (SVG)[3], the patency of the RA graft was inferior to that of the IMA and SVGs[5]. The RA has been recommended to be anastomosed to the circumflex artery or right coronary artery[6]. Use of the RA graft may improve patients' survival and decrease the incidence of cardiac-related events within the first postoperative years[7]. The low morbidity rate associated with the RA has urged the use of this conduit as a supplement of the right IMA in the IMA-to-LAD bypass[7]. However, controversies still exist on the graft choices in CABG. The pathological changes of bypass grafts at the time of harvest have not been frequently investigated and the relations between the pathology and graft patency and long-term survival are scanty. The present study was designed to evaluate the graft pathology at the time of harvest and its impact on long-term survival.

 

METHODS

Patients' information

From 2004 to 2011, 66 patients with coronary artery disease receiving CABG had their remnants of bypass grafts for pathological inspections. There were 55 males and 11 females with a mean age of 68.3±8.1 (range: 50-84; median, 73)years. No difference was found in patient age between males and females (68.8±7.9 years, vs. 65.8±9.0 years, P=0.2608). The patient demographics and the extents of coronary lesions by coronary angiography were listed in Tables 1 and 2.

 

 

 

 

Harvesting

Conventional harvesting of the IMA (pedicled), RA and SVG were applied in all patients.

Specimens

The remnants of the grafts were collected at the completion of CABG from these 66 consecutive patients. The samples were cut into 1 mm3 in size and immersed in 10% methanal solution in appropriate bottles for pathological inspections. Hematoxylin and Eosin staining was performed on 4 μm paraffin-embedded sections. The pathological changes of the grafts were observed and evaluated by an experienced pathologist.

Definitions

Pathologies of the grafts are classified as: normal, proliferation and degeneration (of the smooth muscle cells), degeneration (of the intima), atherosclerosis, calcification, vascular wall hemorrhage and inflammatory cell infiltration, uneven vascular wall thickness and varicose (of the SVG). Proliferation is defined as remarkable growth of vascular cells either in the intima or smooth muscle cells. Destructive changes present in the vascular cells are termed as degeneration. A form of arteriosclerosis is characterized by the deposition of atheromatous plaques containing cholesterol and lipids on the innermost layer of the vessel walls. Vessels permeated with calcium are defined as calcification.

Ethics

This study complies with the Declaration of Helsinki. Informed consent was obtained from each patient and the Institutional Ethics Committee has approved the research protocol.

Statistics

Data were expressed as mean ± standard deviation. Unpaired t-test was made for intergroup comparisons of the quantitative data. Fisher exact test and logistic regression analysis were performed for the postoperative outcomes and the pathology of the grafts. Patients' survival was evaluated with Kaplan-Meier survival analysis. A two-tailed P value of <0.05 was considered of significance.

 

RESULTS

The CABG procedures were performed under CPB in 55 (83.3%), off-pump in 10 (15.2%) and a stepped off-pump and beating heart revascularization under CPB in 1 (1.5%) patient, respectively. Ten (15.2%) patients had a secondary procedure during the operations including mitral valve replacement or repair in 5 (50%), aortic valve replacement, left ventricular pseudoaneurysmectomy, left ventricular pseudoaneurysmectomy with mitral valve repair, left ventricular pseudoaneurysmectomy with the aid of intraaortic balloon pump and intraaortic balloon pump alone in 1 (10%) patient each.

There were totally 236 grafts bypassed in 66 patients with a mean of 3.6±0.9 (range: 2-5; median, 3) grafts per patient including 103 (43.6%) SVGs, 57 (24.2%) RAs, 74 (31.4%) left IMAs (inclusive of all distal anastomoses of the sequential grafts) and 2 (0.8%) right IMAs. A sequential graft was performed in 34 (51.5%) patients, a Y-graft in 2 (3.0%) patients and only independent grafts in the remaining 30 (45.5%) patients. The donor vessels for the LAD were left IMA in 63 (96.9%), RA in 1 (1.5%) and SVG in 1 (1.5%), respectively (χ2=177.4, P=0.0000). The coronary arteries receiving an SVG were left main coronary artery in 1 (1.0%), LAD in 1 (1.0%), the first diagonal branch in 21 (20.4%), intermediate artery in 3 (2.9%), circumflex artery in 1 (1.0%), obtuse marginal branch in 41 (39.8%), right coronary artery in 5 (4.9%), posterior descending artery in 26 (25.2%) and posterior left ventricular branch in 4 (3.9%), totaling 103 grafts. Apart from one (1.0%) bypassed to the left main coronary artery, there were 25 (24.3%), 42 (40.8%) and 35 (34.0%) SVGs grafted to the LAD, circumflex and RCA systems, respectively (χ2=6.4, P=0.0399). The receipt vessels of the left IMA were LAD in 56 (75.7%), the first diagonal branch in 1 (1.4%), sequentially LAD and first diagonal branch in 8 (10.8%) and the great cardiac vein for the purpose of venous arterialization in 1 (1.4%) patient, respectively. An RA graft was used in 51 (77.3%) patients, bypassed to the first diagonal branch in 6 (11.8%), LAD in 1 (2.0%), intermediate artery in 1 (2.0%), circumflex artery in 1 (2.0%), obtuse marginal branch in 23 (45.1%) and posterior descending artery in 19 (37.3%) patients, respectively. They were in a sequential fashion in 4 (7.8%) patients (one RA graft for two distal anastomoses in each patient), a Y-graft in 2 (3.9%) patients and an independent graft in 41 (80.4%) patients. The 2 right IMA grafts were bypassed to the intermediate artery and right coronary artery, respectively.

Of the 236 grafts, 161 (68.2%) remnants were collected and inspected pathologically. There were 57 (35.4%) left IMAs, 45 (28.0%) RAs and 59 (36.7%) SVGs. Types of grafts used did not differ between gender.

The dimensions of the lumens of the three grafts were all within normal ranges. The lengths and lumen diameters of the SVG were larger than those of the IMAs and RAs, however, no statistical differences were noted (Table 3).

 

 

Of this patient setting, half of the patients had normal graft vessels as evidenced by histological observations (Table 4). The prevalence of pathological changes did not reach a statistical significance between the IMA, RA and venous grafts (47.4% vs. 46.7% vs. 45.8%, χ2=0.0, P=0.985). The prevalence of the medial degeneration did not differ between the three grafts, either (36.8% vs. 37.8% vs. 35.6%, χ2=0.1, P=0.973). The microscopic views of the grafts were shown in Figure 1.

 

 

 

 

There were 2 hospital deaths with an early mortality of 3.0%. Two patients were lost for follow-up. The remaining 62 patients were followed up for an average of 30.2±8.8 (range, 6.9-55; median, 15.8) months.

Twenty-four patients had coronary angiography examined during follow-up, 1 (4.2%) patient had left IMA and 1 (4.2%) patient had RA graft occlusion requiring reoperations and 2 (8.3%) patients had SVG occlusion warranting a reintervention by percutaneous angioplasty. There were 9 (14.1%) late deaths due to heart dysfunction (n=3), acute myocardial infarction (n=2), renal failure (n=2), malignant cancer (n=1) and unknown reason (n=1).

Multinomial logistic regression revealed that pathology of the left IMA (P=0.017), the presence of dyslipidemia (P=0.033), history of percutaneous transluminal coronary angioplasty/stent deployment (P=0.001) and Y-graft (P=0.006) were significant predictive risk factors of long-term survival.

Kaplan-Meier survival analysis revealed that the long-term survival of the patients with left IMA pathological changes was significantly reduced in comparison with those without (74.1% vs. 91.4%, P=0.002) and that the pathological changes of the radial arterial or saphenous vein graft were unlikely to significantly affect patients' long-term survival (Figures 2-4).

 

 

 

 

 

 

DISCUSSION

The left IMA-LAD graft is appraised for its promising patency rate and patients' long-term survival[8]. The left IMA is usually used to bypass the anterior circulation and the RA graft, to bypass the coronary arteries of the inferior or the lateral territory[9]. Recent randomized ROOBY trial proved that off-pump CABG was associated with lower patency for arterial and venous graft conduits than on-pump CABG[10]. Superior long-term survival rate was observed in the on-pump CABG than in the off-pump CABG patients[11-13].

Clinical observations revealed that the RA grafts had a lower patency rate (51.3%) than the left IMAs (90.3%) or the SVGs (64.0%)[4]. At a mean of 7.7±1.5 year follow-up after CABG, RAs had much lower functional (12.0% vs. 19.7%, P=0.03) and complete graft occlusion rates (8.9% vs. 18.6%, P=0.002) compared with the SVGs[14]. Hata et al.[15] reported that the cumulative graft patency rates at 8 years were 74.3% for the RA and 64.7% for the SVG, respectively. RA patency rate varied with territory and bypass modes, with 79.4% in the left circumflex coronary artery, 72.7% in the LAD and 50% in the right coronary artery; the occlusion rate was 20.0% among free grafts, 18.2% among sequential grafts and 20.0% among composite grafts[16]. The RA patency rate showed a gender predilection, which was higher in men than in women (38.9% vs. 56.1%, P=0.025) at a mean follow-up of 565±511 days[17].

Non-severe stenosis of the target coronary arteries can be a potential risk factor leading to a higher diffuse narrowing rate of the RA grafts in comparison to the SVGs[9]. Several studies agreed that the history of open heart surgery or percutaneous coronary intervention can be a significant risk factor of increased mortality[18,19]. Severe congestive heart failure, advanced age, postinfarction myocardial rupture, cardiogenic shock, CPB, pulmonary hypertension and increased creatinine can be the risk factors of in-hospital mortality[20]. Long-term mortality was also associated with female gender, non-Hispanic black race, small body surface area, extreme body mass index values, left main coronary disease, multivessel disease, reduced ejection fraction, history of myocardial infarction, unstable hemodynamic state/shock and the presence of comorbidities[21].

The research of graft pathology started from the 1970's. By light microscopy, minimal to moderate mediointimal fibrosis and graft occlusion due to recent thrombosis were noted in 31.7% (13/41) grafts early (<20 days) and old thrombus, intimal leiomyocellular proliferation, or intimal phlebosclerosis were noted in 19.5% (8/41) patients in the late group (3-39 months); whereas a vein graft showed atherosclerotic changes[22].

A histological study of the SVGs showed grade 1 to 2 intimal proliferation in the early group (14 days) and grade 2 to 3 or even grade 4 intimal proliferation in the late group (34 months) in all grafts[23]. In a prospective study involving 365 consecutive patients undergoing isolated CABG, significant lesions in the SGVs were observed in 71 (19.5%) patients[24]. Structures of the SVG, particularly the tunica media and smooth muscle cells had a significant impact on the late outcome after CABG[25]. In patients with postoperative coronary artery disease progression and severe venous graft disease, tunica media thickening was noted, and it was taken as a risk factor for late venous graft failure[25].

In recent years, graft pathology has been carried out in deep-going ways concerning ultrastructural and signaling pathway studies. Saphenous tunica media thickening and chunky smooth muscle cell nuclei were identified as independent risk factors for graft disease[24]. High lipid exposure may be prone to early graft failure especially of the vein graft[26]. Morphometric studies of the RA disclosed mild or moderate intimal hyperplasia but no medial calcification in both young and elderly patients[27]. Matrix vesicles and calcifications were frequently present in the media of both the RA and IMA[28]. Fewer endothelial denudations, similar medial lipid deposition and submicroscopic calcification were observed in the RA comparing to other arteries[28].

The higher proliferative potential of the smooth muscle cells and more actively secretory status of endothelial cells of the RA enhance the remodeling process and predispose a reduced long-term patency[28]. In diabetic patients, the foam cells and tendency of migration from the smooth muscle cells to the intima were more frequently observed in the RA than in non-diabetic patients as observed by electron microscopy[29].

Chronic hypoxia increases the activity of vascular endothelial growth factor, a potent mitogenic molecule for the smooth muscle cells[30]. Li et al.[31] discovered that platelet-derived growth factor, another potent mitogenic molecule, is active exclusively in the epithelioid-like smooth muscle cells isolated from the human IMA but not in the spindle-like cells. Endothelial nitric oxide synthase (eNOS) type III was expressed in the intima of the IMA, RA and SVG and in the media of the IMA and RA. However, the IMA showed a higher intensity of eNOS type III expression, particularly within the media. This may provide an histologic explanation for the better results of the IMA graft[32]. Increased expressions of eNOS in the intima and media were also observed in the RA grafts irrespective of patients' age[27].

A recent study revealed that Gas6/Axl pathway cytokines are more expressed in the left IMA than in other arteries, indicating that the IMAs were more resistant to atherosclerotic changes[33]. Independent predictors of late RA graft failure were native coronary stenosis <75% and peripheral vascular disease. Independent predictors of late SV graft failure were use of only one anti-platelet agent and low-density/high-density lipoprotein cholesterol ratio >2.5[15].

The vasa vasorum of the veins is more pronounced than in the arteries and hence the vasa vasorum plays an important role in enhancing SVG patency when harvested along with surrounding tissue for restoring medial blood flow from the nutrient microvessels[34]. Upregulated inflammation biomarkers including scavenger receptors A and B, toll-like receptors 2 and 4, platelet endothelial cell adhesion molecule, vascular cell adhesion molecule and intercellular cell adhesion molecule have been noted in the SVGs and were thus taken as a possible mechanism of graft failure[35]. An increased expression of cytokeratin 8 and weak expressions of calponin in the tunica media of the SVGs might be useful markers of unfavorable long-term prognosis in CABG patients[36].

The skeletonization of the IMA with an ultrasonic scalpel had no deleterious effect on the endothelium. All IMA specimens showed a completely confluent endothelium, and no endothelial injury was observed by a scanning electron microscopic study[37]. A metal clamp can cause serious intimal injury which disrupts the internal elastic lamina, and thus should be avoided for the temporary clamping of the skeletonized IMA. A fibrous jay clamp, however, hardly ever causes intimal injury, and its clinical use for the temporary clamping of the ultrasonically skeletonized IMA is therefore recommended[37].

Retention of perivascular tissue on the SVG prepared for CABG by "no-touch" technique protects against distension-induced damage, preserves vessel morphology and maintains eNOS activity[38]. In no-touch vessels, eNOS is highly expressed as compared with conventionally harvested ones[39]. The RAs harvested by "no-touch" technique are associated with better preservation of the endothelial cells warranting a long-term patency[28].

In the present study, the dimensions of the lumens of the three grafts were within normal ranges, with reference to their normal limits of 3.1 to 8.5 mm[40], 2.1 mm[41] and 2.6 mm[42] for the SVG, IMA and RA, respectively, as reported in the literature. Pathologically, over half of the patients had normal graft vessels; while others showed medial degenerative changes with or without intimal proliferation accounting for 35.6%, 36.8% and 37.8% in three grafts, respectively. In line with previous reports[11,19], the present study revealed left IMA pathological changes, dyslipidemia, history of PTCA/stent and Y-graft were significant predictive risk factors negatively influencing the patients' long-term survival.

The nonrandomized nature and the limitations in patient selection were likely to be the major drawbacks of this study. A multicenter study in the future would be helpful in obtaining more accurate results.

 

CONCLUSION

Pathological changes may develop in bypass graft at the time of harvest. The subtle ultrastructural modifications and the expressions of the vascular tone regulator might be the underlying causes responsible for late graft patency. The pathological changes of the left IMA at the time of harvest rather than those of the RA or SVG affect significantly patients' long-term survival. Non-traumatic maneuver of IMA harvest, well-controlled dyslipidemia and avoidance of using composite grafts can be helpful in maintaining the architecture of the IMA graft and may therefore improve the long-term outcomes of the patients.

REFERÊNCIAS

1. Karthik S, Fabri BM. Left internal mammary artery usage in coronary artery bypass grafting: a measure of quality control. Ann R Coll Surg Engl. 2006;88(4):367-9. [MedLine]

2. Carpentier A, Guermonprez JL, Deloche A, Frechette C, DuBost C. The aorta-to-coronary radial artery bypass graft. A technique avoiding pathological changes in grafts. Ann Thorac Surg. 1973;16(2):111-21. [MedLine]

3. Goel P, Dubey S, Makker A, Kohli VM. Evaluation of coronary artery bypass grafts by intraoperative transit time flow measurement. Ind J Thorac Cardiovasc Surg. 2003;19(2):108-12.

4. Pizzuto F, Voci P, Mariano E, Puddu PE, Aprile A, Romeo F. Evaluation of flow in the left anterior descending coronary artery but not in the left internal mammary artery graft predicts significant stenosis of the arterial conduit. J Am Coll Cardiol. 2005;45(3):424-32. [MedLine]

5. Khot UN, Friedman DT, Ellis SG. Radial-artery coronary bypass grafts. N Engl J Med. 2005;352(9):941-2; author reply 941-2.

6. Ennker J, Wanner M, Gehle P, Ennker IC, Rosendahl U. Postoperative evaluation of radial artery grafts for coronary artery bypass grafting by transit-time Doppler flow measurements. Thorac Cardiovasc Surg. 2001;49(6):365-8. [MedLine]

7. Acar C, Cook RC. Letter regarding article by Khot et al, "Radial artery bypass grafts have an increased occurrence of angiographically severe stenosis and occlusion compared with left internal mammary arteries and saphenous vein grafts". Circulation. 2005;111(1):e6-9.

8. Leavitt BJ, O'Connor GT, Olmstead EM, Morton JR, Maloney CT, Dacey LJ, et al. Use of the internal mammary artery graft and in-hospital mortality and other adverse outcomes associated with coronary artery bypass surgery. Circulation. 2001;103(4):507-12. [MedLine]

9. Desai ND, Cohen EA, Naylor CD, Fremes SE; Radial Artery Patency Study Investigators. A randomized comparison of radial-artery and saphenous-vein coronary bypass grafts. N Engl J Med. 2004;351(22):2302-9. [MedLine]

10. Hattler B, Messenger JC, Shroyer AL, Collins JF, Haugen SJ, Garcia JA, et al; Veterans Affairs Randomized On/Off Bypass (ROOBY) Study Group. Off-Pump coronary artery bypass surgery is associated with worse arterial and saphenous vein graft patency and less effective revascularization: Results from the Veterans Affairs Randomized On/Off Bypass (ROOBY) trial. Circulation. 2012;125(23):2827-35. [MedLine]

11. Shroyer AL, Grover FL, Hattler B, Collins JF, McDonald GO, Kozora E, et al; Veterans Affairs Randomized On/Off Bypass (ROOBY) Study Group. On-pump versus off-pump coronary-artery bypass surgery. N Engl J Med. 2009;361(19):1827-37. [MedLine]

12. Kim JB, Yun SC, Lim JW, Hwang SK, Jung SH, Song H, et al. Long-term survival following coronary artery bypass grafting: off-pump versus on-pump strategies. J Am Coll Cardiol. 2014;63(21):2280-8. [MedLine]

13. Filardo G, Grayburn PA, Hamilton C, Hebeler RF Jr, Cooksey WB, Hamman B. Comparing long-term survival between patients undergoing off-pump and on-pump coronary artery bypass graft operations. Ann Thorac Surg. 2011;92(2):571-7.

14. Deb S, Cohen EA, Singh SK, Une D, Laupacis A, Fremes SE; RAPS Investigators. Radial artery and saphenous vein patency more than 5 years after coronary artery bypass surgery: results from RAPS (Radial Artery Patency Study). J Am Coll Cardiol. 2012;60(1):28-35. [MedLine]

15. Hata M, Yoshitake I, Wakui S, Unosawa S, Kimura H, Hata H, et al. Long-term patency rate for radial artery vs. saphenous vein grafts using same-patient materials. Circ J. 2011;75(6):1373-7. [MedLine]

16. Crusco F, Antoniella A, Papa V, Menzano R, Di Lazzaro D, Di Manici G, et al. Midterm follow-up of patients receiving radial artery as coronary artery bypass grafts using 16-detector-row CT coronary angiography. Radiol Med. 2007;112(4):538-49. [MedLine]

17. Khot UN, Friedman DT, Pettersson G, Smedira NG, Li J, Ellis SG. Radial artery bypass grafts have an increased occurrence of angiographically severe stenosis and occlusion compared with left internal mammary arteries and saphenous vein grafts. Circulation. 2004;109(17):2086-91. [MedLine]

18. Wu C, Camacho FT, Wechsler AS, Lahey S, Culliford AT, Jordan D, et al. Risk score for predicting long-term mortality after coronary artery bypass graft surgery. Circulation. 2012;125(20):2423-30. [MedLine]

19. Shahian DM, O'Brien SM, Sheng S, Grover FL, Mayer JE, Jacobs JP, et al. Predictors of long-term survival after coronary artery bypass grafting surgery: results from the Society of Thoracic Surgeons Adult Cardiac Surgery Database (the ASCERT study). Circulation. 2012;125(12):1491-500. [MedLine]

20. Mejía OA, Lisboa LA, Tiveron MG, Santiago JA, Tineli RA, Dallan LA, et al. Coronary artery bypass grafting in acute myocardial infarction: analysis of predictors of in-hospital mortality. Rev Bras Cir Cardiovasc. 2012;27(1):66-74. [MedLine] Visualizar artigo

21. Hannan EL, Racz MJ, Walford G, Jones RH, Ryan TJ, Bennett E, et al. Long-term outcomes of coronary-artery bypass grafting versus stent implantation. N Engl J Med. 2005;352(21):2174-83. [MedLine]

22. Thiene G, Valente ML, Miazzi P, Casarotto D, Bortolotti U, Gallucci V. [Pathology of the aorto-coronary bypass by autologous saphenous vein (author's transl)]. G Ital Cardiol. 1979;9(6):549-56. [MedLine]

23. Lawrie GM, Lie JT, Morris GC Jr, Beazley HL. Vein graft patency and intimal proliferation after aortocoronary bypass: early and long-term angiopathologic correlations. Am J Cardiol. 1976;38(7):856-62. [MedLine]

24. Perek B, Malinska A, Stefaniak S, Ostalska-Nowicka D, Misterski M, Zabel M, et al. Predictive factors of late venous aortocoronary graft failure: ultrastructural studies. PLoS One. 2013;8(8):e70628. [MedLine]

25. Davies AH. Vein factors that affect the outcome of femorodistal bypass. Ann R Coll Surg Engl. 1995;77(1):63-6. [MedLine]

26. Zhu YY, Hayward PA, Hare DL, Reid C, Stewart AG, Buxton BF. Effect of lipid exposure on graft patency and clinical outcomes: arteries and veins are different. Eur J Cardiothorac Surg. 2014;45(2):323-8. [MedLine]

27. Shen LZ, Chen XJ, Chen X, Xu M, Wang LM, Jiang YS. [The morphometry and eNOS expression of radial artery in elderly patients with coronary atherosclerotic heart disease]. Zhonghua Wai Ke Za Zhi. 2010;48(11):825-9. [MedLine]

28. Wang HY, Meng Y, Lou XJ, Chu Y, Xu XL, Sun HS, et al. [Comparative study on the ultrastructures of radial and internal mammary arteries used for coronary artery bypass grafting]. Zhonghua Bing Li Xue Za Zhi. 2005;34(8):528-32. [MedLine]

29. Zou L, Chen XJ, Xu M, Chen W, Wang LM, Huang FH, et al. [Comparative study on the ultrastructure of radial artery in elderly patients underwent coronary artery bypass grafting with diabetes mellitus]. Zhonghua Wai Ke Za Zhi. 2011;49(12):1109-13. [MedLine]

30. Hubbell MC, Semotiuk AJ, Thorpe RB, Adeoye OO, Butler SM, Williams JM, et al. Chronic hypoxia and VEGF differentially modulate abundance and organization of myosin heavy chain isoforms in fetal and adult ovine arteries. Am J Physiol Cell Physiol. 2012;303(10):C1090-103. [MedLine]

31. Li S, Fan YS, Chow LH, Van Den Diepstraten C, van Der Veer E, Sims SM, et al. Innate diversity of adult human arterial smooth muscle cells: cloning of distinct subtypes from the internal thoracic artery. Circ Res. 2001;89(6):517-25. [MedLine]

32. Gaudino M, Toesca A, Maggiano N, Pragliola C, Possati G. Localization of nitric oxide synthase type III in the internal thoracic and radial arteries and the great saphenous vein: a comparative immunohistochemical study. J Thorac Cardiovasc Surg. 2003;125(6):1510-5. [MedLine]

33. Lee CH, Shieh YS, Tsai CS, Hung YJ, Tsai YT, Lin CY. Expression of growth arrest-specific protein 6 and Axl molecules in the left internal mammary artery of patients undergoing coronary artery bypass grafting. J Clin Pathol. 2014;67(6):506-11. [MedLine]

34. Dreifaldt M, Souza DS, Dashwood MR. Comparable patencies of the radial artery and right internal thoracic artery or saphenous vein beyond 5 years: results from the Radial Artery Patency and Clinical Outcomes trial. J Thorac Cardiovasc Surg. 2010;140(3):727-8.

35. Khaleel MS, Dorheim TA, Duryee MJ, Durbin HE Jr, Bussey WD, Garvin RP, et al. High-pressure distention of the saphenous vein during preparation results in increased markers of inflammation: a potential mechanism for graft failure. Ann Thorac Surg. 2012;93(2):552-8. [MedLine]

36. Perek B, Malińska A, Ostalska-Nowicka D, Puślecki M, Ligowski M, Misterski M, et al. Cytokeratin 8 in venous grafts: a factor of unfavorable long-term prognosis in coronary artery bypass grafting patients. Cardiol J. 2013;20(6):583-91. [MedLine]

37. Yoshikai M, Ito T, Kamohara K, Yunoki J. Endothelial integrity of ultrasonically skeletonized internal thoracic artery: morphological analysis with scanning electron microscopy. Eur J Cardiothorac Surg. 2004;25(2):208-11. [MedLine]

38. Dashwood MR, Savage K, Tsui JC, Dooley A, Shaw SG, Fernández Alfonso MS, et al. Retaining perivascular tissue of human saphenous vein grafts protects against surgical and distension-induced damage and preserves endothelial nitric oxide synthase and nitric oxide synthase activity. J Thorac Cardiovasc Surg. 2009;138(2):334-40. [MedLine]

39. Tsui JC, Souza DS, Filbey D, Karlsson MG, Dashwood MR. Localization of nitric oxide synthase in saphenous vein grafts harvested with a novel "no-touch" technique: potential role of nitric oxide contribution to improved early graft patency rates. J Vasc Surg. 2002;35(2):356-62. [MedLine]

40. Fazan VP, Borges CT, Da Silva JH, Caetano AG, Filho OA. Superficial palmar arch: an arterial diameter study. J Anat. 2004;204(4):307-11. [MedLine]

41. Canham PB, Finlay HM, Boughner DR. Contrasting structure of the saphenous vein and internal mammary artery used as coronary bypass vessels. Cardiovasc Res. 1997;34(3):557-67. [MedLine]

42. Han S, Yoon SY, Park JM. The anatomical evaluation of internal mammary vessels using sonography and 2-dimensional computed tomography in Asians. Br J Plast Surg. 2003;56(7):684-8. [MedLine]

No financial support.

Authors’ roles & responsibilities

SMY: Main Author

YL: Carrying out operations and/or experiments

YHB: Carrying out operations and/or experiments

XFC: Carrying out operations and/or experiments

DZL: Carrying out operations and/or experiments

DML: Carrying out operations and/or experiments

HJ: Carrying out operations and/or experiments

Article receive on domingo, 20 de julho de 2014

CCBY All scientific articles published at rbccv.org.br are licensed under a Creative Commons license

Indexes

All rights reserved 2017 / © 2024 Brazilian Society of Cardiovascular Surgery DEVELOPMENT BY