ALTHOUGH SIMPLE IN STRUCTURE, THE thoracic aorta is a crucial component of the routine perioperative transesophageal echocardiography (TEE) examination. Pathologies such as atheroma, aneurysms, and dissections can be readily diagnosed and inspected in the operating room. Likewise, TEE can help guide the insertion of cannulas, stents, and intra-aortic balloon pumps (IABPs) during the actual surgical procedure. It is therefore imperative that the intraoperative echocardiographer have a firm grasp on both the anatomy and potential abnormalities of this vital blood vessel.
ANATOMY AND TEE IMAGING
The basic structure of the aorta is similar to that of an upside-down letter “J,” albeit with a slight twist (
Fig. 17.1). The aortic valve annulus, leaflets, and sinuses of Valsalva comprise the beginning of the thoracic aorta, collectively known as the aortic root. The ascending aorta, which is the start of the tubular portion, begins at the sinotubular junction (STJ), travels cephalad, and extends to the origin of the innominate (aka brachiocephalic) artery. The aortic arch begins at this point and travels horizontally to the origin of the left subclavian artery
(LSCA). The descending aorta begins just distal to the LSCA, at a region known as the aortic isthmus, and travels caudad going through the diaphragm.
It is important to keep this overall shape of the aorta in mind during its examination. The vertical nature of the descending portion explains why a short-axis view of this section is typically obtained at an omniplane angle of around 0°, while the short-axis view of the arch, which is horizontal in nature, is at 90°. The reverse is true of the long-axis views, with the descending and arch portions of the aorta obtained at 90° and 0°, respectively (
1). It is also important to keep in mind that the relationship between the esophagus and aorta changes as these structures travel from the abdomen into the thoracic cavity. At the level of the diaphragm, the aorta is posterior to the esophagus, while at the level of the arch, the aorta is anterior to it. Because of this changing orientation, the TEE probe is typically turned as it is withdrawn from the stomach to the upper esophagus in order to keep the aorta in the imaging field. Designating anterior/posterior and left/right while examining the descending aorta is also challenging.
For purposes of surgery and echocardiography, the thoracic aorta can be divided into six zones (see
Fig. 17.1) (
2). The first three zones are within the ascending aorta, with zone 1 closest to the aortic root, zone 2 the typical site for proximal anastomosis of coronary grafts, and zone 3 where aortic cross-clamping for cardiopulmonary bypass (CPB) occurs. The aortic arch is divided into two halves, creating zones 4 and 5. The descending aorta comprises zone 6. Because of the interposition of the trachea and left main stem bronchus, TEE cannot reliably image zones 3 and 4, which is the rationale for performing epiaortic scanning (see section below) (
3).
Because of the sheer length of the structure, the thoracic aorta can be viewed in many of the standard imaging planes. However, a systematic approach to its examination is recommended to ensure all possible sections are visualized. One common method is to begin its examination after obtaining the transgastric views of the left ventricle and turning the probe to the left until the descending aorta is seen in short axis at 0°. From here, the depth is typically set to 6 to 8 cm and the probe is withdrawn, following the aorta until the circular view of the descending in short axis becomes the tubular view of the arch in long axis
(Video 17.1). The omniplane angle can then be adjusted to about 90° to obtain the short axis of the arch and the probe advanced, following the descending aorta down to the diaphragm in long axis
(Video 17.2). The process can be repeated using color flow Doppler to help visualize dissections or coarctations of the descending aorta.
The ascending aorta can be visualized by first obtaining a mid-esophageal long axis of the aortic valve at a typical omniplane angle of 110 to 140°, and slowly withdrawing the probe to obtain imaging of the ascending aorta. By using the right pulmonary artery as an imaging window it is usually possible to see up to zone 2. The omniplane angle can then be decreased by 90° to obtain a short axis of the ascending aorta and the probe advanced to follow the aortic root down to the aortic valve in short axis
(Video 17.3). The views used to scan the thoracic aorta are provided in
Figure 17.1, and while their order of acquisition is not important, all are required for a complete examination.
ACUTE AORTIC SYNDROMES
Acute aortic syndromes are a collection of life-threatening conditions including aortic dissection, intramural hematoma (IMH), and penetrating aortic ulcers. Acute dissection of the ascending aorta, perhaps the best studied of these entities, has a widely quoted mortality rate of 1% to 2% per hour upon presentation (
4). Timely diagnosis is obviously critical so that appropriate surgical intervention can be instituted. Dissections that do not involve the ascending aorta are often managed medically unless there are signs of malperfusion.
Acute Aortic Dissection
An aortic dissection begins with a tear in the intimal layer of the aorta. The tear allows blood to enter and separate the intima from the media or adventitia, creating a “flap” of tissue separating the true aortic lumen from the false lumen. Thoracic aortic dissections are commonly classified by either the Stanford or DeBakey systems (
Fig. 17.2). While the DeBakey system is based upon the location and extent of the tear, the Stanford system is based upon whether the ascending aorta either is (type A) or is not (type B) involved. Aortography was historically considered the “gold standard” for diagnosis of aortic dissection, but it is very rarely used today due to its invasiveness and lower sensitivity than other modalities. Over the past 20 years, computerized tomography (CT) has become the primary imaging modality for diagnosis, being the first-line choice in over 70% of cases in the past 5 years (
5). Even if surgical intervention is initiated based upon CT findings, intraoperative TEE still plays an essential role in confirming the diagnosis and helping to guide surgical repair.
Important aspects for the intraoperative echocardiographer to address during the examination are summarized in
Table 17.1 (
6).
The hallmark finding of an acute aortic dissection on TEE is the visualization of the intimal flap. It is usually very irregularly shaped and highly mobile (Video 17.4). Visualizing the flap in two separate imaging planes (
Fig. 17.3) is important in order to distinguish artifacts from true dissection flaps. One such confounder is the presence of a pulmonary artery catheter, which can create reverberation artifacts mimicking a flap (
Fig. 17.4). When in doubt, this can be remedied by pulling the catheter back and seeing if the “flap” remains. Other sources of linear artifacts include calcifications on the aortic valve or root, and
atherosclerosis of the ascending aorta (
7). They can typically be distinguished from a true dissection by their lack of rapid, oscillatory movement, their tendency to cross known anatomic boundaries, and their indistinct structural borders.
Once the dissection flap is visualized, it is useful to determine where the break in the intima (aka the “tear” or “entry point”) has occurred, since one of the primary aims of surgical treatment is to excise this region.
Color flow Doppler is often used to visualize a turbulent jet flowing from the true lumen into the false lumen (
Fig. 17.5). This separation, or “margination,” of flow can also be helpful in distinguishing a true dissection from an artifact which has no margination of color flow Doppler. The true lumen can usually be differentiated from the false lumen due to its expansion during systole
(Video 17.5). Additionally, the false lumen is often larger, and frequently has spontaneous echo contrast or thrombus within it, particularly in the descending aorta (
8).
Intramural Hematoma
While the initiating event for the classical aortic dissection is a break in the intimal layer, the underlying cause of an IMH is thought to be a rupture of vasa vasorum in the medial layer (
9). This blood accumulation causes a thickening of the medial layer which may progress to intimal fracture, and subsequent flap formation like a classic aortic dissection, or frank aortic rupture. The mortality from IMH is dependent on the location (i.e., ascending or descending aorta) and is similar to that of classic aortic dissection (
10). As such, the Stanford classification system is applied, with type A considered a surgical emergency.
Unlike the classic aortic dissection, there is no intimal flap. On TEE imaging, IMH appears as a thickening of the medial layer of the aorta (
Fig. 17.6 and
Video 17.6). This typically measures 7 ± 2 mm in type A cases, and 15 ± 6 mm in type B (
11). Other features may include echolucency within the medial layer, and medial displacement of calcium in the intimal layer. It is important to note that atherosclerotic plaques appear above the intimal layer, while IMHs occur below the intimal layer.
Penetrating Atherosclerotic Ulcer
Of the acute aortic syndromes, penetrating atherosclerotic ulcer (PAU) is the least common, accounting for somewhere between 2% and 7% of cases (
12). While most atherosclerotic disease protrudes above the intimal layer into the vessel lumen, PAU consists of plaque that has eroded through the internal elastic lamina into the aortic media. No dissection flap is created, but the localized erosion of the medial wall can lead to aneurysm formation or even aortic rupture. Like IMHs, PAUs of the ascending aorta are often considered for emergent surgical intervention due to the risk of rupture (
13). However, most PAUs occur in the descending aorta, where there is controversy among advocates of stent placement, frequent monitoring, or open repair (
14,
15).
No dissection flap or false lumen is visualized on TEE in cases of PAU. Instead, there is a crater-like ulcer with jagged edges and possible echolucent areas within the plaque (
Fig. 17.7). The erosion into the medial layer can make it difficult to clearly see the exact borders of the aortic lumen. There are typically extensive surrounding areas of atherosclerotic disease, and adjacent effusions or fluid collections are common.
Following Repair
Following repair of an ascending aortic dissection, efforts should be made to identify both the proximal and distal ends of the graft. Most synthetic grafts are made from either a polyester fiber (e.g., Dacron) or polytetrafluoroethylene (PTFE) (
16). On TEE, these materials can usually be distinguished from native tissue by their striated appearance (
Fig. 17.8). Interrogation of the aortic valve should be performed as per usual practice following any valvular intervention. It should be noted, however, that prosthetic valves or resuspended native valves are typically sewn within the aortic graft.
Thoracic Aortic Aneurysms
Dilatation of the thoracic aorta can occur due to a variety of clinical conditions including altered flow dynamics, underlying connective tissue disorders, and atherosclerosis. It is therefore useful to provide certain measurements of the aortic root and ascending aorta as part of a complete examination, which are illustrated in
Figure 17.9. Typical values for these measurements are provided in
Table 17.2 (
17,
18,
19), although the size of a “normal” aorta will depend upon age, sex, and overall body surface area (
20). Aortic measurements exceeding the values in
Table 17.2 by more than 50% are considered aneurysmal. Aneurysms can be broadly divided into either
saccular, meaning a focal outpouching, or
fusiform, meaning cylindrical and affecting the entire circumference of the aorta.
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