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Late Observations

Cameron M. Akbari, MD; Frank B. Pomposelli, Jr, MD; Gary W. Gibbons, MD; David R. Campbell, MD; Michele C. Pulling, BA; Darius Mydlarz, BA; Frank W. LoGerfo, MD

Arch Surg. 2000;135:452-456.

ABSTRACT
Hypothesis  Despite the success of infrainguinal arterial bypass in diabetic limb and foot salvage, optimism remains guarded because of purported high late mortality and limb loss in patients with diabetes.

Design  Inception cohort, with minimum 5-year follow-up.

Setting  Tertiary referral center.

Patients  Eight hundred forty-three consecutive patients undergoing lower extremity arterial reconstruction from July 1, 1990, through July 31, 1993.

Intervention  Infrainguinal arterial bypass with vein graft.

Main Outcome Measures  Graft patency, limb salvage, and survival.

Results  A total of 962 vein grafts (843 patients) were performed; 795 grafts (82.6%) were performed in patients with diabetes (DM group) and 167 (17.4%) in nondiabetic patients (NDM group). Average age was 68.4 years, and was lower in the DM group (66.2 [range, 27-92 years] vs 70.5 years [range, 37-96 years]) (P=.005). In-hospital 30-day perioperative mortality was 1.4%, lower in the DM group (0.9% vs 4.2%) (P=.005). The target vessel was more frequently infrageniculate in the DM group (87% vs 77%; P=.002). Five-year primary and secondary graft patencies were 74.7% (DM group, 75.6%; NDM group, 71.9%; P=.80) and 76.2% (DM group, 77.0%; NDM group, 73.6%; P=.90), respectively. The 5-year overall limb salvage rate was 87.1%, also unaffected by diabetes (DM group, 87.3%; NDM group, 85.4%; P=.80). Survival at 5 years was 58.1% overall and virtually identical in the DM (58.2%) and NDM groups (58.0%).

Conclusions  Diabetes mellitus does not influence late mortality, graft patency, or limb salvage rates after lower extremity arterial reconstruction. Concern for long-term mortality and limb loss in diabetic patients is unwarranted and should not prevent aggressive attempts at limb salvage.

INTRODUCTION

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AWARENESS of the pathophysiological features of vascular disease in diabetes,^1-5 coupled with technical advances in extreme distal arterial reconstruction^6-7 and an aggressive approach to diabetic foot problems,^8-10 has led to improved limb and foot salvage in patients with diabetes.¹¹ Despite this success, there remains a guarded optimism about long-term function and survival in these patients, particularly toward diabetic patients with peripheral arterial disease. Higher rates of lower extremity amputation,¹² increased incidence and severity of coronary artery disease,^13-14 and higher cardiovascular mortality¹⁵ are well-recognized in diabetic patients. The misconception of "diabetic small-vessel disease" has been refuted but still appears in the literature.¹⁶ Considered together, these may suggest poorer outcome in treated patients or, even worse, may completely discourage any aggressive treatment in these patients.

Previous studies from our institution have demonstrated successful limb salvage¹⁷ and functional outcome¹⁸ following distal arterial reconstruction in diabetic patients, with low perioperative morbidity and mortality rates. In an effort to better define the long-term outcome of these patients, we herein present our experience with a cohort of diabetic and nondiabetic patients undergoing lower extremity revascularization, with follow-up of at least 5 years.

PATIENTS AND METHODS

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Since January 1990, data from every patient undergoing vascular surgery at our institution have been entered prospectively into a computerized vascular registry. We reviewed the data on all consecutive patients who underwent infrainguinal arterial bypass with vein graft at the Deaconess Hospital, Boston, Mass, from July 1, 1990, through July 31, 1993.

Patient demographics, associated atherosclerotic risk factors, and indication for operation were entered into the database at the time of surgery. Operative details were recorded by the attending surgeon. Perioperative death and complications were also documented. Follow-up generally consisted of an early postoperative visit (usually at 1 month), then every 3 months for the first year and every 6 to 12 months thereafter. All follow-up visits were recorded into the registry. Graft patency was determined by results of physical and handheld continuous-wave Doppler examinations. Ankle-brachial indices were measured on selected patients during the follow-up visits. Duplex scanning graft surveillance was used in selective cases. Further follow-up was obtained from office records and telephone interviews.

Statistical analysis was performed using a commercially available computer program (Stat View; Abacus Systems, Berkeley, Calif). Primary patency (grafts patent from initial surgery without any subsequent intervention), secondary patency (all grafts remaining patent), limb salvage (all or part of the foot remaining), and survival rates were calculated using the actuarial life table method.¹⁹ Differences were calculated using the log-rank test. Categorical variables were compared using the ² test, and continuous variables were compared using the t test. Statistical significance was considered at P<.05.

RESULTS

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A total of 962 vein grafts were performed on 843 patients; 795 grafts (82.6%) were performed in patients with diabetes (DM group) and 167 (17.4%) in nondiabetic patients (NDM group). Patient demographic data and concomitant cardiovascular risk factors are presented in Table 1. Patients in the DM group were younger at presentation than those in the NDM group, and coexisting coronary artery disease and a history of heart failure were also more common among DM group patients. A greater proportion of NDM group patients were active or previous cigarette smokers, and revision bypass grafts were also more common in NDM group patients.

View this table: [in this window] [in a new window] Table 1. Demographics*

Tissue loss (gangrene or ulcer) was the predominant indication for operation in both groups (Table 2), but was more common among the DM group. In fact, in the DM group, claudication or rest pain was an indication in only 6.5%. Asymptomatic failing grafts were also uncommon among both groups, presenting in only 5.5% of the entire group.

View this table: [in this window] [in a new window] Table 2. Indications for Operation*

Operative details regarding graft location and type of conduit are presented in Table 3. In-hospital perioperative mortality was 1.4%, and was lower in the DM than in the NDM group (0.9% vs 4.2%; P=.005). Grafts originating from the popliteal artery were more common in the DM group, consistent with the pattern of arterial vascular disease in diabetes. The dorsalis pedis artery was used as the outflow site in nearly one third of DM group patients, again reflecting the differing patterns of disease in both groups. Overall, bypass grafts to the infrapopliteal and inframalleolar arteries were more common among DM group patients (P<.01). A variety of venous conduits and configurations were used in both patient populations (Table 3).

View this table: [in this window] [in a new window] Table 3. Graft Location and Type of Conduit*

Follow-up continued at least 5 years on all patients. Cumulative 5-year primary graft patency was 74.7% overall, with no difference between groups (DM group, 75.6%; NDM group, 71.9%; P=.80) (Figure 1). The secondary graft patency rate was 76.2% for the entire cohort, and was also similar between groups (DM group, 77.0%; NDM group, 73.6%; P=.90) (Figure 2).

View larger version (11K): [in this window] [in a new window] Figure 1. Cumulative primary patency rates of vein grafts in diabetic (DM group) and nondiabetic patients (NDM group).

View larger version (11K): [in this window] [in a new window] Figure 2. Cumulative secondary patency rates of vein grafts in diabetic (DM group) and nondiabetic patients (NDM group).

Primary graft patency varied according to outflow site. Five-year patency was 86.1% for grafts placed to the popliteal artery, 76.9% for tibial (anterior and posterior tibial artery) and peroneal grafts, 69.7% for dorsalis pedis grafts, and 56.8% for grafts placed to the tarsal and plantar arteries (P=.003 for popliteal vs dorsalis pedis and tarsal-plantar grafts). The conduit also had a dominant effect on primary patency, with arm vein (AV) grafts having lower patency rates compared with in situ (ISSV), translocated nonreversed (NRSV), and reversed saphenous vein (RSV) grafts. Primary patency rates were 55.4% for AV, 78.1% for ISSV, and 82.1% for NRSV-RSV grafts (P=.002 for AV vs ISSV and NRSV-RSV grafts).

Five-year limb salvage and survival rates were virtually identical in both groups (Figure 3 and Figure 4). The overall limb salvage rate was 87.1% (DM group, 87.3%; NDM group, 85.4%; P=.80). Survival at 5 years was 58.1% in the entire cohort (DM group, 58.2%; NDM group, 58.0%; P=.94).

View larger version (11K): [in this window] [in a new window] Figure 3. Limb salvage up to 5 years among patients with (DM group) and without diabetes (NDM group).

View larger version (11K): [in this window] [in a new window] Figure 4. Five-year diabetic (DM group) and nondiabetic patient (NDM group) survival rates.

COMMENT

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Previous clinical and epidemiological studies have confirmed that diabetes mellitus is a strong risk factor for atherosclerotic coronary,²⁰ cerebrovascular,²¹ and peripheral vascular disease,²² as well as a higher cardiovascular mortality rate,²³ compared with the general population. In addition, the relative risk for lower extremity amputation is 40 times higher among patients with diabetes.²⁴ It may appear, therefore, that long-term prognosis is worse among diabetic patients with overt peripheral vascular disease when compared with their nondiabetic counterparts. In our study, however, we have demonstrated long-term bypass graft patency, limb salvage, and survival rates to be comparable between DM and NDM groups with peripheral vascular disease.

Despite a higher incidence of coexisting coronary disease and congestive heart failure, in-hospital mortality was approximately 1% in the DM group. This may result from our recognition of the patterns of cardiac disease in diabetes, specifically, a higher incidence of silent coronary ischemia²⁵ and a predisposition to congestive heart failure.²⁶ We therefore have adopted an aggressive approach toward invasive perioperative cardiac monitoring in this population and continue to advocate its use.

The anatomic pattern of vascular disease in diabetes has been well described²⁷ and is characterized by atherosclerosis of the infrageniculate arteries with relative sparing of the pedal arteries, which has allowed for successful arterial reconstruction to these vessels. Our study confirms this finding. The dorsalis pedis artery was the most common outflow site among the DM group, and short bypass grafts originating from the popliteal artery were also more common among the DM group.

Five-year primary and secondary graft patency rates were similar between groups. In addition, there was virtually no difference between the primary patency rate (74.7%) and the secondary patency rate (76.2%) for all grafts. This likely results from the fact that most grafts did not undergo routine duplex surveillance. Because stenoses in some grafts may not have been detected because of our selective surveillance routine, secondary patency rates might have been higher if routine duplex scanning of all grafts had been performed regularly. However, despite a selective (not routine) surveillance, primary and secondary graft patency rates were comparable to those of other reports.²⁸ In addition, the 5-year primary patency rate of the dorsalis pedis grafts (69.7%) was virtually identical to the patency rate (68%) previously reported from our institution.¹⁷

Arm vein grafts had lower patency rates when compared with saphenous vein grafts. This is consistent with previous reports,²⁹ including the experience reported from our institution.³⁰ The reasons for this difference are multiple and probably not related to any flaw in the intrinsic biology of arm veins.³¹ The arm veins have often received previous venipunctures or cannulations, with resultant injury and scarring. Angioscopy and careful preparation of the conduit can detect and diminish the sequelae of these injuries, which probably contribute to acute and delayed graft failure. Despite this lower patency, however, patency rates are superior to those of prosthetic grafts, and we continue to advocate AV grafts as the first alternative to ipsilateral saphenous vein, particularly in diabetic patients. Contralateral saphenous vein has been seldom used in our largely diabetic population for several reasons. In our previous series, we found that contralateral saphenous vein is present in only 38% of the patients who required AV grafts. More important, we and others³² have found diabetes to be a strong risk factor for subsequent contralateral bypass, approaching 60% at 3 years, and have therefore reserved its use for subsequent need.

Although more than 90% of the DM group presented with tissue loss, limb salvage was 87.3% at 5 years, similar to that achieved in the NDM group. This results from our continued adherence to the fundamentals of diabetic foot management: prompt control of infection and surgical drainage, evaluation for ischemia, prompt arterial reconstruction, and subsequent secondary procedures on the fully vascularized foot.¹ Success with extreme distal arterial reconstruction has enhanced our ability to perform direct foot-sparing surgery,¹¹ such as metatarsal resections and osteotomies, and has allowed for direct soft tissue coverage or even free-flap procedures in select cases.

Most important, we have found that patients with diabetes and peripheral vascular disease have the same survival rate at 5 years as nondiabetic patients with peripheral vascular disease. Although multiple reports have noted 5-year survival of 30% to 60% among all patients with critical leg ischemia,³³ our study suggests that survival rates after revascularization are identical between both groups. The comparable long-term graft patency, limb salvage, and survival rates all strongly emphasize that patients with diabetes and peripheral vascular disease should expect the same quantity and quality of life as nondiabetic patients with peripheral vascular disease, and the presence of diabetes should never deter aggressive attempts at limb salvage.

AUTHOR INFORMATION

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Presented at the 80th Annual Meeting of the New England Surgical Society, Newport, RI, September 25, 1999.

Corresponding author: Cameron M. Akbari, MD, 110 Francis St, Suite 5B, Boston, MA 02215 (e-mail: cakbari{at}caregroup.harvard.edu).

From the Division of Vascular Surgery, Department of Surgery, Beth Israel, Deaconess Medical Center, Harvard Medical School, Boston, Mass.

REFERENCES

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1. Akbari CM, Logerfo FW. Diabetes and peripheral vascular disease. J Vasc Surg. 1999;30:373-384. FULL TEXT | ISI | PUBMED 2. Cameron NE, Cotter MA. The relationship of vascular changes to metabolic factors in diabetes mellitus and their role in the development of peripheral nerve complications. Diabetes Metab Rev. 1994;10:189-224. ISI | PUBMED 3. LoGerfo FW, Coffman JD. Vascular and microvascular disease of the foot in diabetes. N Engl J Med. 1984;311:1615-1619. ISI | PUBMED 4. LoGerfo FW. Vascular disease, matrix abnormalities, and neuropathy: implications for limb salvage in diabetes mellitus. J Vasc Surg. 1987;5:793-796. FULL TEXT | ISI | PUBMED 5. Cohen RA. Dysfunction of vascular endothelium in diabetes mellitus. Circulation. 1993;87:V67-V76. 6. Pomposelli FB Jr, Jepsen SJ, Gibbons GW, et al. Efficacy of the dorsalis pedis bypass for limb salvage in diabetic patients. J Vasc Surg. 1990;11:745-752. FULL TEXT | ISI | PUBMED 7. Akbari CM, LoGerfo FW. Saphenous vein bypass to pedal arteries in diabetic patients. In: Yao JST, Pearce WH, eds. Techniques in Vascular and Endovascular Surgery. East Norwalk, Conn: Appleton & Lange; 1998:227-232. 8. Caputo GM, Cavanagh PR, Ulbrecht JS, Gibbons GW, Karchmer AW. Assessment and management of foot disease in patients with diabetes. N Engl J Med. 1994;331:854-860. FREE FULL TEXT 9. Mills JL, Beckett WC, Taylor SM. The diabetic foot. South Med J. 1991;84:970-974. ISI | PUBMED 10. Akbari CM, Pomposelli FB Jr. The diabetic foot. In: Perler B, Becker G, eds. A Clinical Approach to Vascular Intervention. New York, NY: Thieme-Stratton Inc; 1998:211-218. 11. LoGerfo FW, Gibbons GW, Pomposelli FB Jr, et al. Trends in the care of the diabetic foot: expanded role of arterial reconstruction. Arch Surg. 1992;127:617-621. ABSTRACT 12. American Diabetes Association. Diabetes: 1993 Vital Statistics. Washington, DC: American Diabetes Association; 1993. 13. Kannell WB, McGee DL. Diabetes and cardiovascular disease: the Framingham Study. JAMA. 1979;241:2035-2038. ABSTRACT 14. L'Italien GJ, Cambria RP, Cutler BS, et al. Comparative early and late cardiac morbidity among patients requiring different vascular surgery procedures. J Vasc Surg. 1995;21:935-944. FULL TEXT | ISI | PUBMED 15. Smith JW, Marcus FI, Serokman R. Prognosis of patients with diabetes mellitus after myocardial infarction. Am J Cardiol. 1984;54:718-721. FULL TEXT | ISI | PUBMED 16. Petersen CM, Kaufman J, Jovanovic L. Influence of diabetes mellitus on vascular disease and its complications. In: Moore WS, ed. Vascular Surgery: A Comprehensive Review. 5th ed. Philadelphia, Pa: WB Saunders Co; 1998:146-167. 17. Pomposelli FB Jr, Marcaccio EJ, Gibbons GW, et al. Dorsalis pedis arterial bypass. J Vasc Surg. 1995;21:375-384. FULL TEXT | ISI | PUBMED 18. Gibbons GW, Burgess AM, Guadagnoli E, et al. Return to well-being and function after infrainguinal revascularization. J Vasc Surg. 1995;21:35-45. FULL TEXT | ISI | PUBMED 19. Rutherford RB, Baker JD, Ernst C, et al. Recommended standards for reports dealing with lower extremity ischemia: revised version. J Vasc Surg. 1997;26:517-538. FULL TEXT | ISI | PUBMED 20. Ruderman NB, Haudenschild C. Diabetes as an atherogenic factor. Prog Cardiovasc Dis. 1984;26:373-412. FULL TEXT | ISI | PUBMED 21. Jorgensen H, Nakayama H, Raaschou HO, Olsen TS. Stroke in patients with diabetes: the Copenhagen Stroke Study. Stroke. 1994;25:1977-1984. ABSTRACT 22. Brand FN, Abbott RD, Kannel WB. Diabetes, intermittent claudication, and risk of cardiovascular events: the Framingham Study. Diabetes. 1989;38:504-509. ABSTRACT 23. Kleinman JC, Donahue RP, Harris MI, Finucane FF, Madans JH, Brock DB. Mortality among diabetics in a national sample. Am J Epidemiol. 1988;128:389-401. FREE FULL TEXT 24. Nathan DM. Long-term complications of diabetes mellitus. N Engl J Med. 1993;328:1676-1685. FREE FULL TEXT 25. Nesto RW, Watson FS, Kowalchuk GJ, et al. Silent myocardial ischemia and infarction in diabetics with peripheral vascular disease: assessment by dipyridamole thallium-201 scintigraphy. Am Heart J. 1990;120:1073-1077. FULL TEXT | ISI | PUBMED 26. Jaffe AS, Spadaro JJ, Schectman K, Roberts R, Geltman EM, Sobel BE. Increased congestive heart failure after myocardial infarction of modest extent in patients with diabetes mellitus. Am Heart J. 1984;108:31-37. FULL TEXT | ISI | PUBMED 27. Menzoian JO, LaMorte WW, Paniszyn CC, et al. Symptomatology and anatomic patterns of peripheral vascular disease: differing impact of smoking and diabetes. Ann Vasc Surg. 1989;3:224-228. PUBMED 28. Whittemore AD. Infrainguinal bypass. In: Rutherford RB, ed. Vascular Surgery. 4th ed. Philadelphia, Pa: WB Saunders; 1995:794-814. 29. Gentile AT, Lee RW, Moneta GL, Taylor LM, Edwards JM, Porter JM. Results of bypass to the popliteal and tibial arteries with alternative sources of autogenous vein. J Vasc Surg. 1996;23:272-280. FULL TEXT | ISI | PUBMED 30. Holzenbein TJ, Pomposelli FB Jr, Miller A, et al. Results of a policy with arm veins used as the first alternative to an unavailable ipsilateral greater saphenous vein for infrainguinal bypass. J Vasc Surg. 1996;23:130-140. FULL TEXT | ISI | PUBMED 31. LoGerfo FW, Akbari CM. Arm vein grafts for lower extremity arterial reconstruction. In: Ernst CB, Stanley JC, eds. Current Therapy in Vascular Surgery. 4th ed. St Louis, Mo: Mosby–Year Book. In press. 32. Tarry WC, Walsh DB, Birkmeyer NJO, Fillinger MF, Zwolak RM, Cronenwett JL. Fate of the contralateral leg after infrainguinal bypass. J Vasc Surg. 1998;27:1039-1048. FULL TEXT | ISI | PUBMED 33. Dormandy J, Heeck L, Vig S. The fate of patients with critical leg ischemia. Semin Vasc Surg. 1999;12:142-147. PUBMED

Discussion

David B. Pilcher, MD, Burlington, Vt: This is a careful analysis of one of the largest bypass series studied, perhaps only surpassed by Leather's 1853 in situ grafts. In 1971 the group from the Deaconess presented a smaller series, and concluded graft patency rates and symptomatic improvement are similar in diabetic and nondiabetic patients. The same thing we heard today, a much smaller group. They also concluded that the operative and long-term survival was worse in the diabetic patients, something that we're told today has changed.

Many series have supported the view that graft patency is not adversely affected by diabetes. Perhaps we're trading off the iliac and proximal femoral disease in the nondiabetics for the distal pattern frequently ending above the ankle, evident in diabetics. In that 1971 group from the Deaconess, late survival at 7 years was 37% in the diabetics compared to 50% in nondiabetics. The diabetics had a 41% rate of myocardial infarctions, and that's a place where we've made a significant benefit in the survival rate. And we're told that since now the survival rate is the same between the diabetics and the nondiabetics at 58%, that therefore we shouldn't be concerned. But you know, if you look at the life table for insurance statistics, 68-year-old people (the average age of your group) should have a 17-year life expectancy. Certainly different than your 42% mortality. What you're saying, more appropriately, is that we should be concerned about the mortality in both the diabetic and the nondiabetic groups and that there is room for improvement there.

The limb salvage rates you have are excellent in these difficult patients. This would particularly be so in a group of diabetics who were dialysis dependent, where the group of Veith showed a 25% amputation rate. How many of your patients were on dialysis, and do you think that dialysis-dependent diabetic patients are a different animal than just the diabetic patient?

In summary then, I agree that you've shown what many others have shown: that diabetes does not influence the graft patency and late mortality compared to nondiabetics who are undergoing vascular bypasses. There is room for improvement in both the diabetic and the nondiabetic patients when the 5-year mortality that you're talking about is 42%.

Carl E. Bredenberg, MD, Portland, Me: The results are excellent. Parenthetically, I wish I had a better understanding of the interrelationship of atherosclerosis and diabetes and, for example, why this more peripheral distribution of the occlusive process in the infrageniculate arteries that characterize it. My specific question, however, is the very difficult group of diabetic patients who are renal dialysis patients and how many of your patients were on dialysis that required limb salvage, reconstruction, or, briefly, what is your approach to those patients, and how aggressive are you in that very difficult group?

Dr Akbari: First, insofar as long-term survival is concerned, it is remarkably similar in the 2 groups, and despite quite a few advances in the treatment of cardiovascular disease, the heart remains as the No. 1 cause of death in these patients. Reports still document anywhere from a 30% to 60% long-term 5-year mortality in patients undergoing lower extremity revascularization, which points to the nature of the disease, that is, atherosclerosis affecting all vessels. What is important—and the take-home message here—is that patients with diabetes don't differ significantly from patients without diabetes who require lower extremity revascularization. We clearly know that the odds are stacked against these patients from the get-go, insofar as they do have vascular disease, a systemic process.

What about the patients with renal failure and on hemodialysis? Renal failure patients continue to constitute anywhere from 10% to 15% of our practice. And multiple studies have shown that graft patency rates are not influenced by the presence of renal failure, but long-term survival and wound healing rates are. What do we do with the difficult patient who has a very, very large defect in the foot and is on dialysis? Well, obviously if that patient has no chance for rehabilitation, with no chance for wound healing, then consideration should perhaps be given to an amputation. But more and more, we're seeing patients with renal failure which includes patients who have previously undergone kidney transplantation. The disease is the same, and if in those patients we're talking about a small ulcer on the foot, then every effort should be made towards limb salvage.

The real consideration should be given to young patients with diabetes whom we might be looking at with grim eyes and saying their chance for long-term survival is poor. It's just not the case. Most of these patients have the exact same prognosis as patients without diabetes who need revascularization.

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