Management of acute lower limb ischaemia

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Management of acute lower limb ischaemia




Introduction




Presentation is usually less than 2 weeks’ duration. However, some overlap with chronic critical leg ischaemia is inevitable. The severity of ischaemia is best defined according to the SVS/ISCVS guidelines (Table 8.1),2 which group patients into the following categories:




Data on the incidence of acute limb ischaemia are sparse. Epidemiological surveys would suggest that the incidence is in the region of 140 per million of the general population and this figure appears to be increasing.1 There is evidence that the outcome is improved when patients are managed by a vascular service providing 24-hour cover.3 ALI is associated with a high cost to the community because of the risk of amputation (10–30% at 30 days) and prolonged hospitalisation. Costs are minimised and outcome optimised by accurate clinical assessment and an understanding of the available therapeutic options.



Aetiology


ALI is the result of occlusion of a native artery or vascular/endovascular prosthesis. In situ thrombosis or embolism can cause native arterial occlusion (Box 8.1).




Embolism


Until about 30 years ago, embolism was the underlying cause of most cases of ALI. Emboli large enough to occlude major vessels usually arise in the heart. Rheumatic mitral valve disease was the most common cause, with large emboli forming in a dilated left atrium. Atrial fibrillation due to ischaemic heart disease is now the cardiac origin in 80% of embolic cases; mural thrombus following acute myocardial infarction causes most of the remainder.4 Less commonly, embolisations from mural thrombi of the aorta, aortic aneurysms and iliac arteries are observed. Large emboli typically lodge at an arterial bifurcation, particularly in the common femoral or popliteal arteries (Fig. 8.1). Patients with cardiac embolism may also suffer from peripheral vascular disease as a result of the underlying process of atherosclerosis. This increases the difficulty in establishing the cause of the ischaemia and in planning revascularisation. In 20% of patients with ALI, a source for the embolus cannot be found.




Atheroembolism


Less common sources of emboli include proximal aneurysms or atherosclerotic plaques, usually located in the thoracic or abdominal aorta. Whereas cardiac embolism usually consists entirely of platelet thrombus, embolism from proximal arteries can include atherosclerotic plaques or cholesterol-rich emboli. This has a much worse prognosis than cardiac embolism because embolectomy is less effective. Small particles of atheroembolism can pass to very distal vessels in the foot. This digital embolism can result in the ‘acute blue toe syndrome’. In this condition, the embolic source should be identified and treated if possible. Often this is a proximal arterial plaque that has ruptured and the emboli are a mixture of platelet thrombus and cholesterol (Fig. 8.2). Embolisation of cholesterol-rich atheroma can occur spontaneously, but also follows intravascular manipulation by endovascular intervention, or occasionally surgery (trash foot). This can be disastrous, since both large and small arteries are occluded and cannot be reopened with either surgery or thrombolysis. This often results in limb or end-organ damage, and is sometimes fatal (Fig. 8.3).





Thrombosis


In situ thrombosis in a native artery is now the commonest cause of ALI. It may be the result of rupture of an atherosclerotic plaque or critical flow arrest at the site of an atherosclerotic stenosis. The advancing age of the population and the commensurate increase in atherosclerosis explain the rising incidence of ALI. Acute native vessel arterial occlusion may be compounded by surgery (e.g. knee replacement destroying geniculate collateral vessels formed around a popliteal occlusion), heart failure or a thrombotic tendency (polycythaemia, dehydration, malignancy, etc.). Acute thrombosis of a popliteal aneurysm poses the highest risk to the leg. Typically, this occurs in elderly men in association with aneurysms elsewhere (50% have an aortic aneurysm) or generalised arterial ectasia. Popliteal aneurysms usually commence in the above-knee popliteal artery and extend distally to the tibial trifurcation. As they enlarge they can fill with lamellar thrombus, which may cause either acute thrombosis or distal embolisation that occludes the tibial vessels. The latter will place the leg in extreme jeopardy (50% limb loss).



Other causes


The increasing use of both open and endovascular techniques to revascularise ischaemic limbs means that surgeons often have to deal with acute thrombosis of bypass grafts and arteries that have previously undergone endovascular treatment. Grafts occlude for a variety of reasons. Graft occlusion within 1 month of insertion is usually the result of technical problems at the time of surgery or poor distal run-off. Graft occlusion within 1 year of placement is often caused by myointimal hyperplasia at an anastomosis or the development of stenoses within a vein graft. Occlusion after 1 year is usually due to progression of distal atherosclerosis. Prosthetic grafts have a higher occlusion rate than autogenous vein grafts (see Chapters 3 and 7).


Iliac limb occlusions are observed after aortobifemoral bypass surgery if limbs become kinked or have poor outflow and after for similar reasons endovascular stent grafts are used to repair abdominal aortic aneurysms. Occlusion is more common when the iliac limb of the stent graft is extended in to the external iliac artery. Occlusion may occur any time after implantation in up to 5% of patients.5


A special group of iatrogenic occlusion of external iliac and femoral vessels is related to the maldeployment or failure of arterial closure devices. These achieve closure of arteries after endovascular intervention using percutaneously delivered sutures or plugs. Inadvertently they can cause arrest of flow through direct closure or stenosis of the artery, or by dissection of the vessel. Presentation is usually in the early post-intervention period but may be delayed.


Spontaneous native arterial thrombosis occasionally occurs without an underlying flow-limiting stenosis and these patients should be investigated for an intrinsic clotting abnormality/thrombophilia, e.g. antiphospholipid syndrome, activated protein C deficiency or malignancy.


Occasionally, acute arterial occlusion may be due to arterial dissection, trauma, extrinsic compression or illicit drug use (cocaine and ‘crack’ cocaine). In a young patient with acute popliteal artery occlusion, either popliteal entrapment or cystic adventitial disease should be considered (see chapter on chronic limb ischaemia).



Recent changes


A number of factors may have changed the presentation of ALI. For example, many patients are now treated with risk factor-modifying drugs such as antiplatelet therapy and statins. Antiplatelet therapy probably reduces the risk of limb deterioration and the need for limb revascularisation in those patients with established peripheral arterial disease (PAD).6 It is not yet clear whether this has had an effect on the incidence of ALI. Similarly, patients with atrial fibrillation are currently treated with prophylactic warfarin to prevent stroke according to their CHADS(2) risk score.7 Whilst this does not entirely prevent peripheral embolisation, it can make the acute ischaemia easier to deal with, since there is less secondary thrombosis, particularly affecting small distal arteries.



Clinical features


The severity of ischaemia at presentation is the most important factor affecting outcome of the leg.8,9 Complete occlusion of a proximal artery in the absence of preformed collateral vessels (as in cardiac embolism) results in the classical clinical presentation of pain, paralysis, paraesthesia, pallor, pulselessness and a perishingly cold leg. The pain is severe and frequently resistant to analgesia. Calf pain and tenderness with a tense muscle compartment indicates severe muscle ischaemia or necrosis and often irreversible ischaemia. Sensorimotor deficit including muscle paralysis and paraesthesia is indicative of muscle and nerve ischaemia with the potential for salvage if treated promptly. Initially the leg is white with empty veins but after 6–12 hours vasodilatation occurs, probably caused by hypoxia of the smooth muscle. The capillaries then fill with stagnant deoxygenated blood, resulting in a mottled appearance that blanches on digital pressure (Fig. 8.4). If flow is not restored rapidly, the arteries distal to the occlusion fill with propagated thrombus and the capillaries rupture, resulting in a fixed blue staining of the skin that is a sign of irreversible ischaemia. These features are typical of an acute arterial occlusion in the absence of existing collaterals and suggest an embolic cause. When arterial occlusion occurs as part of a chronic process where collaterals have developed, typically the leg is less severely ischaemic. Patients with peripheral atherosclerosis deteriorate in a stepwise fashion as thrombosis supervenes on an existing arterial plaque. Patients often report a sudden change in symptoms, which progress over a few days: the foot often has a dusky hue with slow capillary return. Previous claudication or absent pulses in the contralateral foot help make a clinical diagnosis of in situ thrombosis. Palpation of a mass in either popliteal fossa suggests thrombosis of a popliteal aneurysm. Young patients (<50 years), those with an atypical history (e.g. severe back pain associated with aortic dissection) or recent endovascular intervention raise the possibility of non-atherosclerotic/embolic ALI.




Initial management


Patients presenting with ALI are often in poor general health, which contributes to the observed high mortality rate from associated cardiovascular disease. Dehydration, cardiac failure, hypoxia and pain should all be managed in the standard way. An intravenous infusion is required for rehydration and is also often the best means of providing analgesia with an infusion pump. If thrombolysis is an option, intramuscular analgesia should be avoided because of the risk of bleeding. Intravenous calcium heparin (5000 units) should be given immediately, followed by systemic heparinisation, principally to restrict propagation of thrombus, although there is also evidence that it improves the prognosis.10 In many units low-molecular-weight heparins have replaced calcium heparin because of their more reliable effect on anticoagulation. Anticoagulation should be delayed if the patient is likely to need epidural anaesthesia. The short half-life of the latter, however, is helpful in this situation. In order to improve oxygenation, 24% oxygen should be given by face mask.


Venous blood should be taken for full blood count, urea, electrolytes and glucose. An electrocardiogram (ECG) and chest radiograph may be of value in diagnosing and managing cardiac arrhythmias and heart failure. If a primary thrombotic tendency is suspected, investigation of this should be delayed as the diagnostic tests are inaccurate in the face of fresh thrombus.



Revascularisation


The clinical assessment of the severity of limb ischaemia will largely dictate the most appropriate form of therapy (Fig. 8.5).





Immediately threatened (category IIb ischaemia)


The acute white leg with sensorimotor deficit requires urgent intervention to prevent limb loss. Although the differentiation between thrombosis and embolus is often difficult, it is in this group of patients that embolism is more likely. An acute white leg with no prior history of claudication, normal contralateral pulses and a probable embolic source, such as atrial fibrillation, would indicate that embolisation is the likely cause. Urgent surgery is indicated in these patients, after resuscitation. Thrombolysis is inappropriate, given the potential delay in revascularisation using this method. Imaging may help guide revascularisation but should not be allowed to delay revascularisation. Many vascular and trauma centres now have rapid access to computed tomography (CT) angiography, which is a useful investigation especially when the femoral pulse is absent and alternative diagnoses such as aortic dissection are possible. An alternative approach is to perform on-table angiography at the same time as groin exploration. Duplex ultrasound imaging is often unhelpful because of the low-flow state in the limb arteries and the need for expert interpretation in the emergency setting.


Both groins and lower limbs should be prepared in theatre. If inflow cannot be re-established into the groin then a femoral crossover graft can be inserted (or aortic dissection managed according to Chapter 9).



Threatened (category IIa ischaemia)/viable (category I ischaemia)


The majority of patients presenting with ALI have acute onset of rest pain but no paralysis and no, or only mild, sensory loss. The cause is often acute thrombosis of either an atherosclerotic artery or graft. Because the leg is not immediately threatened, time is available to plan appropriate intervention after investigation. Conventionally, acute leg ischaemia was investigated using catheter (Fig. 8.6). The advantage was that imaging could be followed by therapeutic thrombolysis at the same sitting. There are now, however, non-invasive alternatives such as duplex imaging CT and MR angiography, both of which can provide enough information on which to plan intervention. The method of investigation will depend on the time of presentation and the available facilities. The two main alternatives in these patients are intervention with surgery or percutaneous thrombolysis. Thromboembolectomy is unlikely to reopen an artery occluded by thrombus and atherosclerotic plaque; formal arterial bypass is more likely to be needed. Nationwide registries suggest that surgical revascularisation is used three to five times more frequently than thrombolysis in everyday clinical practice for patients with ALI.12 Logistics (multiple angiographies) and experience may account in part for this distribution.



Thrombolysis is arguably less invasive than revascularisation surgery. It has the capacity to open small as well as large arteries. It may also uncover the cause of the in situ thrombosis, such as an arterial stenosis, which can be treated by angioplasty to produce a lasting outcome.


Some patients are admitted to hospital with acute thrombosis of a peripheral artery (usually the superficial femoral) but have only claudication and no ischaemic pain at rest. Thrombolysis might appear an attractive option to treat the claudication, but the risks are as high as in patients with limb-threatening ischaemia.13 Initial anticoagulation followed by expectant management, depending on the progression of ischaemia, reduces the risk to both life and limb.10 Some patients’ symptoms improve and never require revascularisation. In others (especially those with short-distance claudication) it may be more appropriate to angioplasty the occluded arterial segment 6–12 weeks after the acute event, when the thrombus has organised and embolic risk is reduced.



Choice between surgery and thrombolysis: the evidence


There remains considerable controversy about the individual roles of surgery and thrombolysis for ALI. A review of 42 studies (most non-randomised) by Diffin and Kandarpa14 suggested that thrombolysis was associated with substantially better limb salvage and mortality rates than surgery.



image


There are three major randomised studies from which to draw harder evidence.1520 The New York study was the first to show that thrombolysis improves survival in patients with limb-threatening ischaemia of less than 14 days.15 This study was small and the advantage was due to the high incidence of cardiorespiratory deaths following emergency surgery. The STILE study was much larger and included patients with ischaemia for longer than 14 days.16 This study has been much criticised because of the failure to insert a catheter successfully for peripheral thrombolysis in one-third of cases. The study introduced the concept of amputation-free survival but failed to show any significant improvement in this primary end-point between the treatment groups. In the subgroup of patients with ischaemia for fewer than 14 days, thrombolysis reduced the rate of amputation. Subsequent analysis of patients from this study up to 1 year revealed that thrombolysis was a better initial treatment for graft occlusions, whereas surgery was more effective and durable for native vessel occlusions.17,18 However, few of the patients in the STILE study had critical ischaemia. The TOPAS trial was designed, using lessons learned from the above studies, to try to settle this debate. In the first phase, an optimal dose of thrombolytic therapy was selected (urokinase 4000 IU/hour)19 and in phase II this was compared with urgent surgery in 544 patients.20 Amputation-free survival was similar in both groups at 6 months and 1 year (72% and 65% for urokinase vs. 75% and 70% for surgery, respectively), though thrombolysis reduced the need for open surgical procedures.

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Jul 1, 2016 | Posted by in CARDIOLOGY | Comments Off on Management of acute lower limb ischaemia

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