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A ruptured abdominal aortic aneurysm (AAA) should be considered in any patient with otherwise unexplained abdominal or back pain. The complete triad of pain, hypotension, and a pulsatile mass may not be present.
In a patient with an AAA and acute symptoms such as severe abdominal or back pain or hypotension, rupture is imminent or has already occurred.
A patient with a ruptured AAA and initially normal vital signs can suddenly deteriorate at any time.
The risk of rupture increases substantially with increased aneurysm size, and most ruptured AAAs have diameters greater than 5 cm.
Bedside ultrasound may be used to document an AAA or free fluid and assist in the rapid diagnosis of a ruptured AAA.
The abdominal CT scan is the diagnostic test of choice in the evaluation of the stable patient with suspected ruptured AAA; intravenous contrast is not essential in emergencies.
The patient who has had endovascular repair of an AAA remains at risk for aneurysm rupture.
An abdominal aortic aneurysm (AAA) is a true aneurysm, meaning a localized dilation of the aorta involving all three layers (intima, media, and adventitia) of the arterial wall ( Fig. 72.1 ). A false aneurysm, or pseudoaneurysm , is a collection of flowing blood that communicates with the arterial lumen but is not enclosed by the normal vessel wall and is contained only by the adventitia or surrounding soft tissue. Pseudoaneurysms can arise from a defect in the arterial wall or a leaking anastomosis after AAA repair.
AAA is distinct from aortic dissection, which is sometimes incorrectly referred to as a dissecting aortic aneurysm. In aortic dissection, blood enters the media of the aorta and splits (dissects) the layers of the aortic wall. Aortic aneurysm and aortic dissection are different disease processes with different clinical presentations, complications, diagnostic methods, and treatments.
An aneurysm can develop in any segment of the aorta, but most are infrarenal. The diameter of the normal adult infrarenal aorta is approximately 2 cm, and a diameter of 3 cm or more defines an AAA.
The prevalence of AAA increases with advancing age and is found in 2% to 5% of men older than 50 years. Men are affected more often than women, although recent research suggests AAA may be more common in women than previously suspected, particularly among women who smoke. The patient often has concomitant atherosclerotic occlusive disease, including coronary, carotid, or peripheral vessels, which may influence the clinical presentations, complications, and management.
Several risk factors for the development of an AAA have been established, but risk factors are epidemiologic, not individual characteristics. Age is the most significant risk factor for the development of an AAA. An AAA can be found in 5% to 10% of all older men who are screened with ultrasonography with increasing prevalence in those who have concomitant coronary artery disease or peripheral vascular disease. A family history of an AAA is a powerful risk factor; those with an affected first-degree relative have a markedly increased risk of developing an AAA. Although awareness of high-risk groups can speed the recognition of AAA, the consideration of AAA should not be restricted to patients in these groups. Some evidence suggests that women may experience delays in diagnosis and worse operative mortality after ruptured AAA. Up to half of AAAs in the United States occur in women, nonsmokers, or those younger than 65 ( Table 72.1 ).
Group | Incidence |
---|---|
Men aged 65 years or older | 5% to 10% |
Patients with coronary artery disease or occlusive peripheral vascular disease | 10% to 15% |
Brothers of patients with abdominal aortic aneurysms (AAAs) | 20% to 30% |
AAAs have traditionally been attributed to atherosclerosis, but patients with advanced atherosclerosis have occlusive disease, not aneurysms. Patients with AAA have biochemical abnormalities leading to the loss of elastin and collagen, which are the major structural components of the aortic wall. The propensity to form aneurysms may have a genetic basis, but the exact mode of inheritance is uncertain. The Society for Vascular Surgery has recommended labeling the typical degenerative AAA as “nonspecific,” rather than “atherosclerotic,” to reflect this uncertainty surrounding the etiology.
AAAs may also have specific etiologies, such as infection, trauma, connective tissue diseases, and arteritis. Such aneurysms are rare, however, compared with nonspecific degenerative aneurysms.
AAAs progressively enlarge, ultimately resulting in rupture of the aneurysm and potentially fatal hemorrhage. Although other complications are possible, by far the most common and most clinically significant is rupture.
The most important factor determining the risk of rupture is the size of the aneurysm. The risk of rupture increases substantially with increased aneurysm size, and most ruptured AAAs have diameters greater than 5 cm. The growth rate of the AAA, in addition to other anatomic factors, may also be important in determining the risk of rupture. Although rupture of aneurysms smaller than 4 cm is rare, no aneurysm is completely “safe.” Any aneurysm can rupture and cause significant consequences.
AAA most commonly ruptures into the retroperitoneum, where hemorrhage may be temporarily limited by clotting and tamponade at the rupture site, but 10% to 30% involve free intraperitoneal rupture, which is often rapidly fatal. Occasionally, rupture occurs into the gastrointestinal tract or the inferior vena cava.
Complications can also arise from an intact AAA. The walls of an AAA are often lined with clot and atheromatous material, which can embolize and occlude distal vessels. Sequelae of occlusion and embolization may be the only diagnostic clues to AAA. Aortic thrombosis may occur rarely and patients can also have complications caused by impingement of the aneurysm on adjacent structures.
In approximately 5% of AAAs, a dense inflammatory and fibrotic reaction develops in the aneurysm wall and adjacent retroperitoneal tissue. In these “inflammatory” AAAs, periaortic fibrosis may incorporate and obstruct adjacent structures, such as the ureters or duodenum.
The principal concern in the patient with an AAA is the potential for rupture of the aneurysm, which can be prevented only by timely repair.
Because most AAAs do not cause symptoms until they expand or rupture, the prevalence of symptoms in patients with unruptured AAAs is difficult to determine. Patients may have symptoms that lead to the aneurysm’s discovery before rupture. These symptoms can include pain in the abdomen, back, or flank; an awareness of an abdominal mass or fullness; or a sensation of abdominal pulsations. Clinical suspicion of AAA, which includes both the patient’s history and physical examination findings, warrants further investigation with imaging.
The pain associated with stable, intact aneurysms often has a gradual onset and a vague, dull quality. It is usually constant but may be described as throbbing or colicky. Acute or severe pain is an ominous symptom that suggests imminent or actual aortic rupture.
In most cases, an AAA is asymptomatic and is discovered incidentally on physical examination, on a radiologic study done for unrelated issues, or by ultrasonography as part of an aneurysm screening program. Symptoms may not develop until the aneurysm ruptures, and the finding of an AAA may or may not be related to the patient’s current visit. If determined not to be related, follow-up will be necessary even when found incidentally.
The most prominent physical finding is a pulsatile, expansile abdominal mass above the level of the aortic bifurcation. If the iliac arteries are also aneurysmal, the mass may extend below the umbilicus. The right border of an AAA may be palpable to the right of midline, whereas a normal or tortuous aorta is usually not. Most intact AAAs are nontender; tenderness suggests aneurysm expansion or rupture.
Symptomatic aneurysms are usually relatively large and are often palpable with a careful abdominal examination. However, an AAA may be challenging to palpate if the aneurysm is small or the patient is obese. Published reports indicate that 30% to 60% of unruptured aneurysms measuring 3.0 to 3.9 cm on ultrasonography can be detected by abdominal palpation; 50% to 70% of aneurysms measuring 4.0 to 4.9 cm and 75% to 85% of aneurysms 5 cm or larger can be palpated. These reports are based on the examination of patients with intact, asymptomatic aneurysms, with the examination specifically directed at sizing the aorta. The sensitivity is likely much lower when the abdomen is not palpated deeply, in hypotensive patients, or in those with significant abdominal guarding. There is virtually no risk of causing aneurysm rupture by abdominal palpation.
Physical examination may reveal findings consistent with an AAA even when the aorta is of normal size. A tortuous aorta may feel enlarged, and prominent aortic pulsations, especially in a thin patient, may simulate an aneurysm. Pulsations from a normal aorta may be transmitted to an adjacent abdominal mass.
An abdominal bruit is an uncommon finding in patients with AAAs. The presence of a bruit is also nonspecific, because bruits can originate from a stenotic renal, iliac, or mesenteric artery. A loud continuous bruit suggests the diagnosis of arteriovenous fistula, a rare complication of AAAs.
Perfusion distal to an AAA is usually well maintained, and most patients have normal femoral pulses. Diminished femoral pulses may result from iliofemoral occlusive disease or hypotension related to hemorrhagic shock in the patient bleeding from a ruptured aneurysm.
Thromboembolic complications can occur spontaneously or when atheromatous plaques are disrupted during invasive intravascular procedures. Large emboli can acutely occlude major vessels, such as the iliac, femoral, or popliteal artery, causing painful lower extremity ischemia with absent distal pulses. Rarely, the aneurysm itself can thrombose, rendering both lower extremities acutely ischemic. More commonly, microemboli consisting of cholesterol crystals or clot obstruct small distal vessels, such as the digital arteries of the toes and arterioles and capillaries of the skin. These patients can present with livedo reticularis; one or more cool, painful, cyanotic toes; and palpable pedal pulses. This constellation of findings, often called the blue toe syndrome, is highly suggestive of a proximal source of emboli. When an AAA is the source, the aneurysm is often too small to palpate and only recognized with radiologic investigation.
In rare instances, an intact AAA can cause symptoms by compressing adjacent structures, with symptoms arising from those structures involved. Large, long-standing aneurysms can cause vertebral body erosion and severe back pain. Compression of the duodenum between the superior mesenteric artery and an AAA can cause duodenal obstruction, vomiting, and weight loss. Obstruction of the ureters in the patient with an inflammatory aneurysm can cause symptoms suggestive of ureteral colic.
Although the classic description of a ruptured AAA is the triad of pain, hypotension, and a pulsatile abdominal mass, many patients have only one or two components of this triad, and occasionally none of these classic features.
Acute rupture is often the first presentation of an AAA. Not infrequently, however, patients may have a previously diagnosed AAA that has not been repaired because the aneurysm was small or the patient was considered too high risk. Any new or acute symptoms in these patients should be considered acute aneurysmal rupture.
Most patients with a ruptured AAA experience pain in the abdomen, back, or flank. The pain is classically acute, severe, and constant. Although it may be difficult to localize, the pain can radiate to the chest, thigh, inguinal area, or scrotum. A history of pain may be more difficult to elicit if the patient’s mental status is compromised by severe hypotension.
The source of the pain associated with aneurysm rupture is not clearly understood. It may be caused by the expansion of the aortic wall or by stimulation of visceral sensory nerves in the retroperitoneum. Identical pain can occur with intact but acutely expanding aneurysms, which may be impossible to differentiate clinically from ruptured aneurysms.
In patients with a ruptured aneurysm, the duration of symptoms before presentation can vary dramatically. Some patients present immediately after rupture because the pain is severe, sudden in onset, and may be accompanied by hypotension. In others, the rupture is initially contained in the retroperitoneum and blood loss is minimal. In these cases, the pain may be minor, waxing and waning, and the presentation delayed. Rare patients with a ruptured AAA may have symptoms for several days or even weeks before seeking medical attention; therefore, a long duration of symptoms does not exclude the diagnosis of ruptured AAA.
Rupture of an AAA may be accompanied by nausea and vomiting in addition to pain or, rarely, absent significant pain. Sudden hemorrhage may present as syncope or near-syncope. Compensatory hemodynamic mechanisms may restore blood pressure and cerebral perfusion to normal. Transient improvement in symptoms is common but will be followed by hemodynamic deterioration if the diagnosis and treatment are delayed. Ruptured AAAs are often large, and non-obese patients will have a palpable abdominal mass. The examination may be difficult if abdominal guarding is present or if an ileus causes significant distention. Aortic pulsations may not be prominent if the blood pressure is low.
Hypotension is the least consistent part of the triad, occurring in approximately half of patients, and is often a late finding. When the initial blood loss is minimal, vital signs may be normal. Patients with initially normal vital signs are more likely to be misdiagnosed and may quickly and unpredictably deteriorate and become hypotensive.
Occasionally, rupture into the retroperitoneum is contained for many weeks or months. When this occurs, patients develop abdominal or back pain, presumably at the time of aneurysm leakage, which subsequently diminishes or resolves completely. If the diagnosis is made, chronic rupture (organized hematoma) is found at surgery. These patients can have chronic pain and may progress to free rupture and massive hemorrhage at any time.
A primary aortoenteric fistula (AEF) is formed when an unrepaired AAA erodes into the gastrointestinal tract, most commonly in the third or fourth portion of the duodenum. A secondary AEF, a communication between the site of previous aortic surgery and the gastrointestinal tract, can occur as a late complication of AAA repair and should be considered in any patient with a severe gastrointestinal bleed and a history of aortic graft placement. An AAA can rupture into the gastrointestinal tract (AEF) or inferior vena cava (aortocaval fistula).
Early in the formation of a primary AEF, the adjacent AAA erodes through the bowel wall from the outside. This can lead to the leakage of intestinal contents, with local infection and abscess formation. Eventually, breakdown of the aortic wall leads to an AEF and may lead to gastrointestinal bleeding. A patient with an AEF may have abdominal or back pain, fever and other signs of intra-abdominal infection, or gastrointestinal bleeding. Because most of these fistulae are into the duodenum, hemorrhage usually manifests as hematemesis or melena. The initial bleeding results from erosion of vessels in the bowel wall and is often occult or minor. Massive bleeding from rupture into the intestinal lumen can occur days or even weeks after the initial bleeding. Primary AEF, although rare, should be considered in any patient older than 50 years with unexplained severe gastrointestinal bleeding. A patient with an AAA diagnosed by history, physical examination, or other modality, presenting with gastrointestinal bleeding should raise the concern for AEF.
An arteriovenous (usually aortocaval) fistula arises when periaortic inflammation causes adherence of the aorta to an adjacent vein, with pressure on the vessel walls causing the development of an arteriovenous communication. If concomitant extravasation of blood into the retroperitoneum occurs, the clinical presentation is similar to that of other patients with ruptured AAAs. More commonly, however, the aneurysm ruptures into the vena cava without leaking externally, and the signs and symptoms of a large arteriovenous fistula dominate the clinical picture.
As in other patients with AAAs, a patient with an arteriovenous fistula may have abdominal or back pain. An aneurysm that becomes fistulous with the vena cava is usually large, and 80% to 90% are palpable. A continuous abdominal bruit can be auscultated in approximately 75% of patients with arteriovenous fistulae, and 25% of patients have a palpable abdominal thrill.
Shunting of blood from the arterial to the venous system increases venous pressure, venous volume, and venous return to the heart. Signs and symptoms of high-output congestive heart failure (dyspnea, jugular venous distention, pulmonary edema) are often present. The increased venous volume and pressure can cause lower extremity edema or cyanosis, and dilated superficial veins can be seen on the legs or abdominal wall. Distention and rupture of veins in the bladder mucosa can cause gross or microscopic hematuria, and rectal bleeding can occur for similar reasons. Because of shunting of arterial blood into the venous system, the lower extremities may be cool with diminished pulses.
The patient with an arteriovenous fistula often has renal insufficiency caused by a decrease in renal perfusion as a result of high-output congestive heart failure and increased renal venous pressure. Such patients may exhibit hematuria, which is common when an arteriovenous fistula is present but not in other patients with AAAs. Computed tomography (CT), and preferably computed tomographic angiography (CTA), is essential for diagnosing or ruling out arteriovenous fistula formation.
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