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AUTHOR AND EDITOR INFORMATION

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Author: Jackeline Gomez-Jorge, MD, Assistant Professor of Clinical Radiology, Department of Radiology, Vascular and Interventional Section, University of Miami/Jackson Memorial Medical Center

Jackeline Gomez-Jorge is a member of the following medical societies: Alpha Omega Alpha, American College of Radiology, American Heart Association, and American Medical Association

Editors: Glenn Krinsky, MD, Chief of Abdominal Imaging Section, Associate Professor, Department of Radiology, New York University School of Medicine; Bernard D Coombs, MB, ChB, PhD, Consulting Staff, Department of Specialist Rehabilitation Services, Hutt Valley District Health Board, New Zealand; John D Newell, Jr, MD, FACR, FCCP, FASER, Co-Director of Thoracic Imaging, UCDHSC; Director of Lung Imaging Center, Professor of Radiology and Professor of Medicine, Department of Radiology, University of Colorado Health Sciences Center, National Jewish Medical and Research Center; Univ. Colorado Hospital; Robert M Krasny, MD, Consulting Staff, Department of Radiology, The Angeles Clinic and Research Institute; Kyung J Cho, MD, FACR, William Martel Professor of Radiology, Interventional Radiology Fellowship Director, University of Michigan Health System

Author and Editor Disclosure

Synonyms and related keywords: aortic dissection, dissection of aorta, aortic intimal tear, pseudoaneurysm, aortic intramural hematoma, traumatic aortic dissection, AIH, aortic aneurysm

INTRODUCTION

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Background

Classic aortic dissection is a longitudinal split or partition in the media of the aorta. An intimal tear connects the media with the aortic lumen, and an exit tear creates a true and a false lumen. The smaller true lumen is lined by intima, and the false lumen is lined by media. Typically, flow in the false lumen is slower than in the true lumen, and the false lumen often becomes aneurysmal when subjected to systemic pressure. An acute aortic dissection is considered chronic at 2 weeks. The dissection usually stops at an aortic branch vessel or at the level of an atherosclerotic plaque.1, 2

Most classic aortic dissections begin at 3 distinct anatomic locations: the aortic root; 2 cm above the aortic root; and just distal to the left subclavian artery. Ascending aortic involvement may result in death from wall rupture, hemopericardium and tamponade, occlusion of the coronary ostia with myocardial infarction, or severe aortic insufficiency.

Aortic intramural hematoma (AIH) is a more recently described entity in which no intimal flap is present. It results in a spontaneous medial hematoma that may be secondary to an infarction of the vasa vasorum of the adventitia. Aortic intramural hematoma accounts for approximately 25% of aortic dissections. Involvement of the ascending aorta, especially if the overall aortic diameter is greater than 5 cm, should be treated surgically to prevent rupture or progression to a classic dissection with intimal tear. Conservative management is indicated for AIH of the descending aorta.3, 4, 5, 6, 7, 8

Related eMedicine topics:
Aortic Dissection (from Thoracic Surgery)
Aorta, Trauma
Thoracic Aortic Aneurysm
Abdominal Aortic Aneurysm

Related Medscape topics:
Specialty Site Radiology
Specialty Site Cardiology
Resource Center Atrial Fibrillation
Resource Center Vascular Surgery
CME/CE Cases from AHRQ WebM&M: The Wrongful Resuscitation
CME Highlights of the 14th Annual Symposium of the Preventive Cardiovascular Nurses Association

Pathophysiology

The pathogenesis of aortic dissection is not well understood, but the following are associated risk factors9, 10:

Mortality/Morbidity

The mortality rate increases when diagnosis is delayed; this is especially the case for ascending aortic dissections. The mortality rate is 1% per hour for the first 48 hours. However, patients who survive long enough to be hospitalized and who are without significant comorbidities usually survive. Occlusion of aortic branch vessels from aortic dissection may result in stroke, renal failure, mesenteric ischemia, lower-extremity ischemia, and paraplegia (caused by obstruction of the spinal artery). Interestingly, aortic intramural hematoma is rarely associated with significant narrowing of aortic branch vessels.

The incidence is approximately 2000 cases per year, but lack of reporting and the small number of autopsies performed lead to gross underestimations of the true incidence. Ischemic heart disease is roughly 1000 times more common than aortic dissection in patients who present to the ED with chest pain. However, once the diagnosis is suspected, it must be confirmed or refuted with an imaging study.

Race

Aortic dissection is more common in African-Americans, followed by whites. Untreated hypertension may account for the greater prevalence in African-Americans. Aortic dissection is least common in Asians.

Sex

Aortic dissections are more common in men than in women (ratio, 3:1) and in patients aged 35-85 years; the peak incidence occurs in those aged 50-65 years.

Aortic intramural hematoma (AIH) usually occurs in slightly older patients.

Clinical Details

  • Ripping or tearing pain in the intrascapular area
  • Abrupt onset of pain
  • Acute, severe chest pain (Anterior chest pain may mimic acute myocardial infarction.)
  • Pain extending to the neck or jaw
  • Altered mental status
  • Symptoms of cerebrovascular accident
  • Syncope
  • Limb paresthesias
  • Horner syndrome
  • Dyspnea
  • Dysphagia
  • Flank pain if the renal arteries are involved
  • Hypertension
  • Hypotension if associated with cardiac tamponade, hypovolemia, excessive vagal tone

Dissections of the aorta can be classified into types (see Image 1).

  • DeBakey classification
    • Type I: The entire aorta is involved.
    • Type II: Only the ascending aorta is involved.
    • Type III: Only the descending aorta is involved. Type IIIA involves the descending aorta as far as the diaphragm. Type IIIB involves the descending aorta below the diaphragm.
  • Stanford classification
    • Type A: The ascending aorta is involved.
    • Type B: The descending aorta is involved.

It is noteworthy that isolated dissections that begin in the aortic arch but do not involve the ascending aorta do not fit neatly into these classifications.

AIH is classified in a similar fashion.

Preferred Examination

Preferred examinations for aortic dissection include contrast-enhanced spiral CT transesophageal echocardiography (TEE) in the emergency setting and MRI for hemodynamically stable patients. TEE has an advantage over CT and MRI in its ability to evaluate the status of the aortic valve and the ostia of the coronary arteries. CT and MR angiography have largely replaced conventional diagnostic angiography in the assessment of aortic dissection.11, 12, 13, 14

Several factors determine the best modality for the initial evaluation and postoperative follow-up. These factors include the following: stability of the patient's condition, the patient's renal function, suspected postoperative complication, and the availability of each imaging modality.

Maffei et al performed a randomized, controlled trial in which 44 patients (252 evaluations) were examined with TEE and CT.15 The authors concluded that both TEE and CT are atraumatic, safe, and accurate techniques for serial follow-up studies of patients treated for aortic dissection.

Limitations of Techniques

Three noninvasive studies are associated with high specificity and sensitivity for aortic dissection. CT and MRI are associated with a sensitivity and a specificity of 94-100% and 95-100%, respectively. Transesophageal echocardiography (TEE) is less sensitive and specific than spiral CT or MR, and TEE is operator-dependent. In addition, because of tracheal interposition, there is a 2 cm "blind spot" for TEE just proximal to the innominate arteries. Also, TEE is contraindicated in approximately 1% of patients (eg, TEE is contraindicated in patients with esophageal varices).


DIFFERENTIALS

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Aortic Regurgitation
Aortic Stenosis
Myocardial Infarct, Acute

Other Problems To Be Considered

Back pain, mechanical
Gastroenteritis
Hernias
Hypertensive emergencies
Myocarditis
Myopathies
Pancreatitis
Pericarditis and cardiac tamponade
Peripheral vascular injuries
Pleural effusion
Pulmonary embolism
Shock, hemorrhagic
Shock, hypovolemic
Thoracic outlet syndrome


RADIOGRAPH

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Findings

Findings of aortic dissection on plain film images include the following:

  • Mediastinal widening (this is the most common plain radiographic finding in aortic dissection; it is noted in 80% of patients) (see Image 2)
  • Double aortic knob sign (present in 40% of patients)
  • Diffuse enlargement of the aorta with poor definition or irregularity of the aortic contour
  • Inward displacement of aortic wall calcification by more than 10 mm
  • Tracheal displacement to the right
  • Pleural effusion (more common on the left side; suggests leakage)
  • Pericardial effusion
  • Cardiac enlargement
  • Displacement of a nasogastric tube
  • Left apical opacity

All findings on plain images are nonspecific but may help in determining the need for further workup.

False Positives/Negatives

Mediastinal fat commonly causes a widening of the mediastinum, which may lead to a false-positive diagnosis of aortic dissection.


CT SCAN

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Findings

Since its introduction in the 1970s, CT has become a widely used technology, particularly in the ED. With the advent of spiral CT, studies may be performed in less time than before, with less patient discomfort, greater accuracy, and lower iodine load. Spiral CT permits patient translation and data acquisition simultaneously. A major advantage of this technology is in the evaluation of thoracic trauma, which enables the rapid diagnosis of thoracic injury. Multislice or multidetector CT may be used for faster imaging or to acquire thinner slices that may be reconstructed in multiple planes.16, 17, 18, 19, 20

A typical helical scanning protocol for aortic dissection includes the following parameters: 5-mm collimation, 1.5 pitch, and 7.5-mm imaging spacing. Multidetector CT may be performed with 1-2.5 mm collimation. Initial nonenhanced CT is used for the diagnosis of acute hemorrhage and aortic rupture. This is followed by helical CT performed approximately 25-30 seconds after the injection of contrast material. Nonionic contrast material (120-135 mL) is power injected via a peripheral intravenous site at a rate of 3-4 mL/s. Because cardiac output is quite variable in these sick patients, a test injection of contrast should be used to determine circulation time; alternatively, an automated bolus detection scheme may be used. One advantage of the test injection method is that one may visually differentiate the true and false lumen on the basis of contrast arrival time.

Usually, scanning is performed from the thoracic inlet to the common femoral arteries. When a dissection is identified, repeat scanning may be performed to obtain delayed images of the false lumen and aortic branches. Multiplanar reformation images are obtained in sagittal, coronal, oblique sagittal, and curved projections generated with an independent workstation. The use of volume rendering may be helpful for planning surgery.

Typical CT findings in acute dissection or intramural hematoma include the following:

  • Aortic intramural hematoma: Crescentic high-attenuating clot within the media, with internally displaced calcification (see Image 3)
  • Intimal flap separating the two aortic channels (see Images 4-5)

Hemorrhagic pleural and pericardial effusions and mediastinal hemorrhage may be seen.

CT is helpful in postoperative follow-up. It may accurately depict associated complications, including the following:

  • Thrombosis
  • Hemorrhage
  • Infection
  • Pseudoaneurysms
  • Aortoenteric fistula
  • Ureteral obstruction

Degree of Confidence

The sensitivity of CT for aortic dissection is 87-94%, and the specificity is 92-100%.

False Positives/Negatives

Inadequate contrast opacification may lead to false-negative findings of aortic dissection. Aortic intramural hematoma may be misinterpreted as an aneurysm with thrombus or arteritis.

Spiral CT artifacts include perivenous streaks and motion artifacts. The perivenous streaks are caused by beam hardening and motion resulting from transmitted pulsation in a vein that carries undiluted contrast medium into the heart. Some authors recommend injecting the contrast agent at a rate of 2 mL/s via a peripheral intravenous site in the right arm. Aortic motion artifact is produced by the aortic wall motion from the end of diastole to the end of systole. Typically, this artifact is seen in the left anterior and right posterior margins of the aortic circumference.

In some patients, especially those with cystic medial necrosis, the intimal flap may be subtle.


MRI

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Findings

MRI is an accurate tool for use in diagnosis of aortic dissection, but it may not be readily available in the acute setting. In addition, unstable patients with Swan-Ganz catheters should not undergo MRI.21, 22, 23, 24, 25, 26, 14

MRI findings of aortic dissection include the following:

  • An intimal flap of medium signal intensity is surrounded by a signal void of fast-flowing blood on "black blood" echocardiogram (ECG)-gated spin-echo or double inversion recovery single-shot fast spin-echo MRI (see Image 6).
  • With cine gradient echo imaging, the intimal flap appears as a dark line against the high signal intensity of the flowing blood; it may change configuration during the cardiac cycle. It is important that a careful examination of the aortic flap be conducted during the cardiac cycle with cine MRI so as to detect the presence of "true lumen collapse," which may be associated with end-organ ischemia. In some cases, the intima is stripped 360° from the media and is essentially "free floating"; this may result in catastrophic intimo-intimo intussusception.

Newer pulse sequences such as true fisp or Fiesta offer very fast cine imaging.

Basic MRI sequences for evaluating aortic dissection include spin-echo T1-weighted or breath-hold double inversion recovery sequences, cardiac-gated gradient-echo sequences, and three-dimensional (3D) thin-section MR angiography with a bolus injection of a single or double dose of gadolinium-based contrast agent

MRI findings of AIH include a crescent of blood surrounding but not compressing the aorta. The signal intensity of the crescent varies with age on T1-weighted imaging: it is isointense to muscle in the acute setting and is markedly hyperintense after 3-7 days.

MRI is helpful in postoperative follow-up. It may accurately depict associated complications, including the following:

  • Thrombosis
  • Hemorrhage
  • Infection
  • Pseudoaneurysms
  • Aortoenteric fistula
  • Ureteral obstruction

Degree of Confidence

The sensitivity and specificity of MRI for aortic dissection are both more than 90%.

False Positives/Negatives

Potential drawbacks of MRI include reported artifacts on cardiac-triggered thoracic spin-echo phase images. These may appear as an artifactual borderlike feature across the aorta (caused by helical flow in the aorta) that may be interpreted as a dissection. Other potential causes of misinterpretation include an atypical configuration of the intimal flap seen in short dissections and multiple false channels in cases in which the flaps are complex (see Images 7-8). Aortic anomalies also may cause confusion. False-positive findings seen in gadolinium-enhanced MRA include a central line or "maki" artifact. This occurs when the acquisition is performed too early as intra-aortic gadolinium concentration is rising. This artifact may be readily differentiated from an aortic dissection because it does not take a spiral course like a true intimal flap.

Gadolinium-based contrast agents (gadopentetate dimeglumine [Magnevist], gadobenate dimeglumine [MultiHance], gadodiamide [Omniscan], gadoversetamide [OptiMARK], gadoteridol [ProHance]) have been linked to the development of nephrogenic systemic fibrosis (NSF) or nephrogenic fibrosing dermopathy (NFD). For more information, see the eMedicine topic Nephrogenic Fibrosing Dermopathy. 

NSF/NFD disease has occurred in patients with moderate to end-stage renal disease after being given a gadolinium-based contrast agent to enhance MRI or MRA scans. NSF/NFD is a debilitating and sometimes fatal disease. Characteristics include red or dark patches on the skin; burning, itching, swelling, hardening, and tightening of the skin; yellow spots on the whites of the eyes; joint stiffness with trouble moving or straightening the arms, hands, legs, or feet; pain deep in the hip bones or ribs; and muscle weakness. For more information, see the FDA Public Health Advisory or Medscape.


ULTRASOUND

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Findings

ECG is helpful in the diagnosis of aortic dissections. It is particularly helpful in cases of ascending thoracic dissections, cardiac tamponade, and aortic regurgitation; transesophageal echocardiography (TEE) has a greater sensitivity and specificity than CT or MRI in detecting coronary arterial occlusion, aortic insufficiency, and cardiac tamponade. The sensitivity is 97-99%. The specificity is in the range of 97-100%.27, 28

According to a study by Mastrogiovanni, TEE was the favored study for the evaluation of aortic dissection.29  In their report of 54 patients, TEE findings confirmed the diagnostic dissection in all patients but one. TEE noted the site of the intimal tear; the extension of the dissection, pericardial effusion, aortic incompetence; and left ventricular function. Because of the high level of correspondence between the diagnosis made at TEE and the surgical anatomic findings, the authors favored the use of TEEfor many cases, as the sole diagnostic modality.

False Positives/Negatives

A tortuous aorta may result in a false-positive diagnosis of dissection. In cases involving a massive dilated ascending aorta (usually occurring as a result of cystic medial necrosis), it may be difficult to identify a small intimal flap.


NUCLEAR MEDICINE

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Findings

Nuclear medicine has no role in the diagnostic evaluation of acute aortic dissection. In a stable patient with chronic dissection and severe renal insufficiency, a renal scan may demonstrate the presence or absence of renal perfusion (usually of the left kidney).


ANGIOGRAPHY

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Findings

Aortography was the reference standard for the preoperative evaluation and diagnosis of aortic dissection. With the advent of transesophageal echocardiography (TEE), CT, and MRI, its role has become important only if nonsurgical interventional procedures are indicated. It is quite controversial whether coronary angiography should be performed before sternotomy in a stable patient with aortic dissection, inasmuch as concomitant coronary bypass grafting may be performed if diseased vessels are present.

Diagnostic criteria include visualization of a lucent flap and delayed filling and washout of the false lumen. The expanding false lumen may compress the true lumen and cause it to become narrowed. A dual lumen aorta is noted when both the true and false lumens are opacified (see Image 9). Aortic intramural hematoma (AIH) is almost impossible to diagnose with aortography because no compression of the lumen exists.

During aortography, overinjection of the false lumen should be avoided if it is entered during the procedure. The operator should be suspicious if he or she has difficulty advancing the guidewire into the aortic valve. Abdominal and pelvic aortography should be included in the diagnostic study to assess the level of the reentry site. Obstruction of the aortic branches may be noted (most commonly in the left renal artery, which is the site in approximately 25-30% of patients). Visceral and extremity ischemia may occur when the superior or inferior mesenteric arteries and the iliac arteries are compromised.

Degree of Confidence

Aortographic findings are less sensitive than those of newer noninvasive techniques, especially for aortic intramural hematoma.

False Positives/Negatives

Pitfalls of angiography include a lack of visualization of the false lumen because of thrombosis or inadequate opacification with contrast material. Streak artifacts secondary to aortic or cardiac motion or opacification of the sinus of Valsalva may be confused with thrombus. Pitfalls also include missing the diagnosis of an intramural hematoma (frequently associated with progression to frank dissection) and misdiagnosis when the false lumen is thrombosed.


INTERVENTION

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Aortic fenestration is an alternative in treating the complications of aortic dissection, including renal and/or mesenteric ischemia in type B dissections. Surgical repair of type A or B dissection usually redirects blood to the true lumen and cures branch vessel compromise. However, because operative mortality is 35% in acute type B dissection, interventional techniques are a viable option. The mortality rate of patients with aortic dissection and renal or mesenteric ischemia is extremely high: 50-70% for patients with renal ischemia and up to 87% for patients with mesenteric ischemia. Aortic fenestration, with or without stenting of an underperfused vessel, appears to have a role in the treatment of static or dynamic obstruction of aortic branches.30, 31, 32, 33, 34, 35, 36

The goal of treatment is to create a tear in the dissection flap that separates the true and the false lumens. This procedure allows local blood flow across the flap and reperfuses the organs supplied by the true lumen or those that are underperfused. The following steps are required:

  • If CT or MRI is available, digital subtraction angiography with a power injection into the true lumen suffices in the assessment of the orientation of the true and false lumens. Intravascular or transesophageal ultrasound (TEUS) may be performed to help localize the needle and differentiate the true from false lumen as well.
  • The actual fenestration is performed by advancing a Rosch-Uchida needle or any equivalent device from the true lumen (usually the smaller one) to the false lumen (usually the larger one).
  • The needle is rotated to a position perpendicular to the dissection flap and is advanced to make the puncture. The needle causes the wall to become tented during this step. The fenestration site is chosen as close as possible to the arteries that are compromised.
  • Using a sheath to measure pressures on both sides (ie, in the true and false lumens) is convenient.
  • Once the needle is advanced into the false lumen, a working wire may be advanced into the false lumen. A 12- to 15-mm balloon is inflated across the flap to create a transverse tear. The flap is frequently soft, and a waist in the balloon may not be seen. The IVUS device may be used to assess correct placement of the balloon.
  • Successful puncturing of the flap may be confirmed by injecting saline into the fenestration catheter. Microbubbles in the false lumen confirm successful flap puncture. The IVUS device may be swept up and down the aorta. If fenestration is successful, the IVUS device switches from one lumen to the other at the site of the fenestration.
  • Aortic stents are used to buttress open the true lumen. The stents are deployed between the fenestration and the compromised artery but not across the fenestration. When the dissection propagates into a branch artery, it may be treated with stent placement after the gradient is measured across the branch vessel.8

Some centers have begun treating patients who have type B dissections by placing a covered stent-graft across the entry tear. This approach yields the same physiologic results as surgical repair (ie, it redirects blood flow to the true lumen). However, the long-term results of this technique are not known. Often, multiple reentry tears are present; these may keep the false lumen patent and result in aneurysmal dilatation.8

Medical/Legal Pitfalls

  • Failure to identify the imaging features of a dissection
  • Delay of treatment as a result of performing unnecessary imaging studies
  • Death during an aortic fenestration performed without appropriate informed consent


FURTHER READING

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Aortic aneurysm and dissection.
Finnish Medical Society Duodecim.  2004 Feb 26.  Various pagings.  [NGC Update Pending] NGC:004359
 
Acute chest pain - suspected aortic dissection.
American College of Radiology.  1995 (revised 2005).  5 pages.  NGC:004621
 
Screening for abdominal aortic aneurysms: recommendation statement.
United States Preventive Services Task Force.  1996 (revised 2005).  16 pages.  NGC:003960

The Society of Thoracic Surgeons practice guideline series: transmyocardial laser revascularization. Society of Thoracic Surgeons.  2003.  16 pages.  NGC:004052

Guidelines on the management of valvular heart disease.
European Society of Cardiology.  2007 Jan.  39 pages.  NGC:005534


MULTIMEDIA

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Media file 1:  Image A represents a Stanford A or a DeBakey type 1 dissection. Image B represents a stanford A or DeBakey type II dissection. Image C represents a Stanford type B or a DeBakey type III dissection. Image D is classified in a manner similar to A but contains an additional entry tear in the descending thoracic aorta. Note that a primary arch dissection does not fit neatly into either classification.
Click to see larger pictureClick to see detailView Full Size Image
Media type:  Image

Media file 2:  Plain anteroposterior view of the chest demonstrates a wide mediastinum. Courtesy of Jorge J. Guerra, Jr, MD.
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Media type:  X-RAY

Media file 3:  Nonenhanced CT scan of the chest demonstrates a type B acute aortic intramural hematoma with displacement of intimal calcification and a crescentic high-attenuating clot without mass effect on the aortic lumen. Courtesy of Joel L. Fishman, MD.
Click to see larger pictureClick to see detailView Full Size Image
Media type:  CT

Media file 4:  Contrast-enhanced axial CT image demonstrates an intimal flap that separates the two channels in the ascending and descending aorta diagnostic of a Stanford type A dissection. Courtesy of Joel L. Fishman, MD.
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Media type:  CT

Media file 5:  Contrast-enhanced axial CT image demonstrates an intimal flap that separates the two channels in the ascending aorta and descending aorta and begins at the level of the aortic root. Courtesy of Joel L. Fishman, MD.
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Media type:  CT

Media file 6:  Sagittal gradient-echo MRI image obtained in early systole shows a jet of blood flowing through the intimal tear from the smaller anterior true lumen into the larger posterior false lumen. The intimal flap is recognized as the medium signal intensity linear structure that divides the true and false lumens. An aortic stent-graft could be placed across the intimal/entry tear in the descending thoracic aorta to redirect blood into the anterior true lumen. Courtesy of Joel L. Fishman, MD.
Click to see larger pictureClick to see detailView Full Size Image
Media type:  MRI

Media file 7:  Unenhanced CT scan of the chest depicts a complex dissection with multiple false channels in an aneurysmal descending aorta. Aortic rupture could not be excluded as there is a large aorta with hyperintense areas of fresh hematoma and a pleural effusion. Left lower lobe lung disease is present. Courtesy of Joel L. Fishman, MD.
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Media type:  CT

Media file 8:  Contrast-enhanced CT scan obtained at the level of the aortic arch demonstrates an aortic dissection with almost complete separation of the aortic intima. The slight prolapse may be the beginning of a configuration at risk for intimo-intimo intussusception, a potentially fatal event. Courtesy of Joel L. Fishman, MD.
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Media type:  CT

Media file 9:  Oblique arteriogram of the thoracic aorta demonstrates the double-barrel aorta sign of aortic dissection. Both the true and false lumina are opacified. Courtesy of Joel L. Fishman, MD.
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Media type:  Image


REFERENCES

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Aorta, Dissection excerpt

Article Last Updated: Sep 5, 2008