Infrainguinal Occlusive Disease

Sumaiya Hafiz; Saran Lotfollahzadeh

Infrainguinal Occlusive Disease

Earn CME/CE in your profession:

Free Review Questions

Continuing Education Activity

Infra inguinal occlusive diseases are amongst the commonest vascular diseases, worldwide. This activity outlines the evaluation, treatment and management of patients suffering from the disease and highlights the role of the inter-professional team in improving care for patients with this condition.

Objectives:

Describe the pathophysiology of infrainguinal occlusive diseases.
Review the risk factors for developing infrainguinal occlusive diseases.
Outline the common presentation and physical examination findings of patients with infrainguinal occlusive diseases.
Explain the different treatment modalities and management of patients with infrainguinal occlusive diseases.

Introduction

Infrainguinal occlusive diseases are one of the commonest diseases faced by patients worldwide. The comorbidities, and atherosclerotic etiology of most, result in an increased chance of limb loss, cerebrovascular and cardiovascular complications.[1] They may also be known as arterial occlusive disease or chronic limb ischemia.

Some of the less common diseases which cause lower extremity arterial insufficiency symptoms are atheroembolism and Buerger disease.

Arterial occlusive diseases produce signs and symptoms based on the site of artery stenosis or occlusion. In the lower limb, the most common symptoms are intermittent claudication, rest pain, and gangrene.

These are classified according to different stages, using various established classifications, including Fontaine, Rutherford, Wagner, UT, PEDIS, SVS WIfI.[2]

The arteries involved are mainly those inferior to the inguinal ligament, which include,

Femoral artery branch of the external iliac artery
Popliteal artery
Infrapopliteal arteries, including posterior tibial and dorsalis pedis artery

Etiology

The most common risk factor of arterial occlusive diseases is atherosclerosis. This condition may result from increasing age, smoking, diabetes mellitus, hypercholesterolemia, hypertension.

Other causes include increased C-reactive protein levels, homocysteinemia, thrombophilia, inflammation, and trauma.

Having more than one risk factor increases the degree of occlusion and severity.

Epidemiology

An estimated 20% of adults above the age of 55 years present with the disease.[3]

The disease affects almost 5 million people in the United States. Ethnicity and gender play a significant role; the condition is common in African Americans and people of Hispanic origin.[4]

Smoking is one of the main modifiable risk factors and increases the risk of developing the disease fourfold.[5]

Pathophysiology

Atherosclerosis causes occlusion of the arteries. Depending on the site of occlusion and involvement of the artery, collateral pathways can form. However, over time, the oxygen demand during exercise increases, which is insufficiently compensated, leading to intermittent claudication, i.e., calf pain and fatigue on walking or activity. As the severity of occlusion increases, the symptoms may present even at rest, leading to ischemic rest pain, minor and significant tissue loss, which includes ulcers and gangrene.

Acute occlusion is common in the infra-inguinal arteries. This condition leads to the atherosclerotic phenomenon of thrombosis and embolus. Thrombus is a localized clot that leads to impaired circulation. Emboli may travel to bifurcations and cause occlusion and present more acutely with no collaterals. The most common site of embolus is the distal common femoral artery and popliteal arteries. The level of impalpable pulses helps locate the site of occlusion.

The six P's characteristic of arterial occlusion includes pain, pallor (color change), poikilothermia (coldness), pulselessness, paresthesia, and paralysis.

Histopathology

The most frequent histopathological findings are thickening of intima, fibroatheroma, fibro-calcification. Atheromatous plaques are composed of collagen and calcification.

Luminal occlusion is also observed in chronic limb ischemia, without significant atherosclerosis, potentially due to the athero-thrombo-embolic phenomenon.[6]

History and Physical

The disease is more common in males. The patient is usually above the age of 50 years; if younger, other differentials may be explored, such as Buerger disease and autoimmune conditions such as vasculitis.

The central aspect of the history would be the complaints to progressive difficulty walking and pain—intermittent claudication, which is a pain in the calf precipitated by walking and relieved by rest. Rest pain is characteristically worse at night and is aggravated by lying supine and elevating the foot and is relieved by hanging the foot off the bed and sleeping in a chair.

Ulcers most commonly present on digits, as well as gangrene.

The severity requires evaluation, and the site of pain to help determine the location of the occlusion. The most common sites to ask about are mainly buttocks, knees, calves, and digits. Complaints of impotence also merit attention and abdominal pain after eating to rule in or out mesenteric ischemia. The previous history of stroke and transient ischemic attack is essential.

The examiner should query risk factors, such as the previous history of diabetes, hypertension, hyperlipidemia, and, if present, medication dosage, and compliance require assessment.

On examination, the main points are the built and general appearance of the patient to look for cachexia and muscle wasting, eyes for pallor (anemia) or jaundice, palpate all pulses including femoral, popliteal, posterior tibial, dorsalis pedis artery. Examine the abdomen for abdominal aortic aneurysm and auscultate for bruits. Asses the gait, and do special tests to determine the severity, Buerger's test to determine the angle, check for dependent erythema, ulcers, skin texture, loss of hair, pigmentation, dependent rubor, amputated digits. Check for sensation and numbness.

One of the most crucial parts of the examination and assessment is the ankle-brachial pressure index (ABPI). The normal values are 1 to 1.3. A value of less than 0.9 suggests intermittent claudication, less than 0.5 is associated with rest pain, and less than 0.3 is critical limb ischemia. The ABPI is a highly sensitive test and is essential to form a diagnosis and assess disease severity.

The ABPI may show a value of more than 1.3 in patients with diabetes due to calcification of the vessels. In that case, a segmental waveform analysis or toe-brachial index is an alternative.

Evaluation

Laboratory investigations: Complete blood count, fasting blood sugar, lipid profile, serum creatinine, serum electrolytes, electrocardiogram (EKG),

Radiological investigation: The most appropriate initial investigation is an ultrasound plus doppler, which is a duplex scan to determine the blood flow and localize the clot. It also serves to determine the ankle-brachial pressure index, as described above.

Angiography: Computerized tomography (CT angio)/magnetic resonance angiography (MRA).

Treatment / Management

Conservative management: Lifestyle modification is the most effective, which includes weight loss, exercising, modifying dietary habits, foot care.

Medical management: Low dose aspirin, a statin, cilostazol (vasodilator for intermittent claudication), along with strict control of comorbid illnesses through antihypertensives and anti-hyperglycemic medications, with regimen compliance. Note: beta-blockers may exacerbate claudication.

Endovascular: Involves percutaneous transluminal angioplasty and stenting. Hybrid procedures are being performed by vascular surgeons to improve outcomes and decrease mortality.[7]

Surgical management: This includes bypass and endarterectomy. Amputation may be necessary in cases of unsalvageable tissues.

Bypass, according to the site of obstruction - Superficial femoral artery occlusion - femoropopliteal (above the knee). Five-year patency is fifty to seventy-five percent. A bypass is more effective in proximal major arteries compared to distal.
Infrapopliteal - Femoro-distal (below the knee). Five-year patency is fifty to sixty percent.

Great saphenous vein graft is most patent and has a low rate of infections. If the vein is unavailable, then prosthetic grafts such as ePTFE are used.

In other diseases such as Buerger disease (thromboangiitis obliterans), the first step in management is always smoking cessation.

Differential Diagnosis

Leriche syndrome: Aortoiliac occlusive disease, which presents as a triad of buttock claudication, impotence, lower limb extremity wasting.
Buerger disease: most common in young male smokers, may present with gangrenous digits, pain, and impalpable pulses.
Vasculitis
Deep venous thrombosis: can present with calf pain and swelling. Risk factors may be present.
Osteoarthritis
Popliteal compartment syndrome
Neurogenic claudication: Lumbar stenosis, herniated disc; this can be differentiated as it may not be reproducible with exertion and may not be present at all times. Examination findings such as skin temperature, delayed capillary refill, and absence of pulses will be absent.

Toxicity and Adverse Effect Management

Clinicians should ask patients taking aspirin about any previous history of gastric or duodenal ulcers and, if present, should receive prophylactic proton pump inhibitors to prevent gastrointestinal bleeding and gastric erosions.

Staging

The disease is classified using various established classifications, which include Fontaine, Rutherford, Wagner, UT, PEDIS, SVS WIfI, TASC.[2]

The Rutherford classification is as follows :

0- Asymptomatic,
1- Mild claudication (pain on walking at a certain distance known as the claudication distance),
2- Moderate,
3- Severe,
4- Rest pain,
5- Ischemic ulcers on digits - minor tissue loss,
6- Gangrene or ulcers - significant tissue loss.

TASC classification of femoropopliteal arterial occlusive disease :

Type A single lesions: endovascular treatment
Type B multiple lesions: endovascular treatment
Type C multiple or recurrent stenoses: open revascularization
Type D chronic total occlusion: surgical treatment

Prognosis

Infrainguinal occlusive diseases may lead to limb-threatening ischemia in 5 to 10% of patients.

Management of the disease is mostly by medical treatment with positive outcomes.

Patency of the endovascular approach is less compared to surgical treatment.[8]

The survival rate is 50% for ten years but significantly drops to five years for patients requiring surgical treatment.

Complications

The commonest complication is critical limb ischemia and limb-threatening stenosis, often leading to amputation and increased mortality.

The surgical approach leads to postoperative complications, including infections, bleeding, cardiac, renal, pseudoaneurysm formation, graft rejection, and thromboembolic complications.

There is also an increased probability of 30-day readmission and in-hospital complications and mortality.[9]

Restenosis is the most common late-onset complication.

Deterrence and Patient Education

Lifestyle modification is an essential aspect of the treatment. Weight loss, smoking cessation, and dietary changes have positive outcomes.
Medical treatment with aspirin, statin, and control of comorbid illnesses prevents the progression of the disease. Avoid beta-blockers.
Statins have a 5-year survival benefit in patients who have undergone bypass for revascularization.[10]
For patients with foot complications, they should receive a referral to a podiatrist should be made, and ulcer management is also necessary.
Regular follow up is crucial, and patients should seek medical care if the pain worsens in severity and claudication distance is reduced further.

Pearls and Other Issues

Infrainguinal occlusive diseases are also known as outflow diseases. The level of durability and success of treatments for infra-inguinal diseases is lesser compared to diseases of arteries above the inguinal ligament knows as inflow diseases.

Enhancing Healthcare Team Outcomes

The treatment and management of infra-inguinal occlusive diseases involve a patient-centered approach which requires assistance and input from various medical professionals including vascular surgeons, cardiologists, family physicians, nurses, podiatrist, diabetic educator, pharmacists, and other healthcare professionals.

As the majority of the patients have treatment with lifestyle modifications and most of the risk factors are modifiable, healthcare professionals need to display compassion and encourage the patients to maintain a healthy lifestyle to decrease the progression of the disease. This approach can also include explaining the risks involved with increased severity and progression of the disease.

The key tools in assessing the disease are history, examination, and the ankle-brachial pressure index. Although history may often lead to a wide range of differentials, with the appropriate to and approach, a management plan is possible which is suitable for the patient.

Details

References

[1]

Pennywell DJ, Tan TW, Zhang WW. Optimal management of infrainguinal arterial occlusive disease. Vascular health and risk management. 2014:10():599-608. doi: 10.2147/VHRM.S50779. Epub 2014 Oct 24 [PubMed PMID: 25368519]

[2]

Azuma N. The Diagnostic Classification of Critical Limb Ischemia. Annals of vascular diseases. 2018 Dec 25:11(4):449-457. doi: 10.3400/avd.ra.18-00122. Epub [PubMed PMID: 30636998]

[3]

Hankey GJ, Norman PE, Eikelboom JW. Medical treatment of peripheral arterial disease. JAMA. 2006 Feb 1:295(5):547-53 [PubMed PMID: 16449620]

[4]

Selvin E,Erlinger TP, Prevalence of and risk factors for peripheral arterial disease in the United States: results from the National Health and Nutrition Examination Survey, 1999-2000. Circulation. 2004 Aug 10; [PubMed PMID: 15262830]

Level 3 (low-level) evidence

[5]

Fowkes FG, Housley E, Riemersma RA, Macintyre CC, Cawood EH, Prescott RJ, Ruckley CV. Smoking, lipids, glucose intolerance, and blood pressure as risk factors for peripheral atherosclerosis compared with ischemic heart disease in the Edinburgh Artery Study. American journal of epidemiology. 1992 Feb 15:135(4):331-40 [PubMed PMID: 1550087]

[6]

Narula N, Dannenberg AJ, Olin JW, Bhatt DL, Johnson KW, Nadkarni G, Min J, Torii S, Poojary P, Anand SS, Bax JJ, Yusuf S, Virmani R, Narula J. Pathology of Peripheral Artery Disease in Patients With Critical Limb Ischemia. Journal of the American College of Cardiology. 2018 Oct 30:72(18):2152-2163. doi: 10.1016/j.jacc.2018.08.002. Epub 2018 Aug 27 [PubMed PMID: 30166084]

[7]

Zhou M, Huang D, Liu C, Liu Z, Zhang M, Qiao T, Liu CJ. Comparison of hybrid procedure and open surgical revascularization for multilevel infrainguinal arterial occlusive disease. Clinical interventions in aging. 2014:9():1595-603. doi: 10.2147/CIA.S66860. Epub 2014 Sep 22 [PubMed PMID: 25284992]

Level 2 (mid-level) evidence

[8]

Komshian SR, Lu K, Pike SL, Siracuse JJ. Infrainguinal open reconstruction: a review of surgical considerations and expected outcomes. Vascular health and risk management. 2017:13():161-168. doi: 10.2147/VHRM.S106898. Epub 2017 May 8 [PubMed PMID: 28507439]

[9]

Khoury H, Morales RR, Sanaiha Y, Rudasill S, Jaman R, Gelabert H, Benharash P. Trends in mortality, readmissions, and complications after endovascular and open infrainguinal revascularization. Surgery. 2019 Jun:165(6):1222-1227. doi: 10.1016/j.surg.2019.03.019. Epub 2019 May 6 [PubMed PMID: 31072666]

[10]

Suckow BD, Kraiss LW, Schanzer A, Stone DH, Kalish J, DeMartino RR, Cronenwett JL, Goodney PP, Vascular Study Group of New England. Statin therapy after infrainguinal bypass surgery for critical limb ischemia is associated with improved 5-year survival. Journal of vascular surgery. 2015 Jan:61(1):126-33. doi: 10.1016/j.jvs.2014.05.093. Epub 2014 Jul 16 [PubMed PMID: 25037607]