Interventional Radiology for Vascular and Solid Organ Trauma

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The first description of the use of transcatheter embolization of the internal iliac artery to control hemorrhage associated with pelvic fractures was published in 1972. Since that time, the role of interventional radiologists in trauma has evolved from that of making the initial diagnosis of vascular and solid organ injuries to temporizing or definitive treatment. ^{[1, 2, 3, 4, 5, 6, 7, 8, 9]}

Examples of vascular and solid organ trauma are displayed in the images below.

Many technical innovations in imaging and angiographic equipment, as well as new developments in transcatheter therapy, have paved the way for this trend in nonoperative management. These include the following:

State-of-the-art digital subtraction angiography

Helical CT

Microcatheters, steerable and hydrophilic guidewires, and coaxial guiding catheters and sheaths

Novel embolization materials and delivery systems

Stents and covered stents (stent-grafts)

CT usually is the imaging modality of choice; it is widely used in trauma cases, for the following reasons:

It may be used to grade solid organ injuries.

It can detect hemorrhage. On contrast-enhanced scans, extravasation (representing active bleeding) may be represented by a high attenuation focus caused by contrast media leak from a vessel. On non–contrast-enhanced scans, active or recent bleeding may be represented by high attenuation clot or blood (ie, the sentinel clot sign implies ongoing hemorrhage).

It may be used to detect vascular abnormalities, such as pseudoaneurysm, intimal dissection, arteriovenous fistula, and vascular occlusion.

It is useful in predicting which hemodynamically stable patients may benefit from nonoperative management.

In the selected trauma patient with suspected vascular injury or hemorrhage, diagnostic catheter angiography usually is performed. Catheter angiography may be performed as a screening procedure or to plan definitive transcatheter or surgical therapy. It is used as follows:

A large-field nonselective study, such as an abdominal aortogram, is obtained first.

Angiography may detect bleeding and may help in planning further selective studies.

Selective studies are performed to detect more subtle hemorrhage and vascular injuries and to direct further treatment, such as transcatheter embolization.

Angiography should be obtained early and quickly to diagnose hemorrhage immediately and to exploit an intact clotting cascade should transcatheter embolization be needed.

Indications for emergency catheter angiography in the trauma patient include clinical signs or symptoms of hemorrhage or CT evidence of ongoing hemorrhage or vascular injury.

In penetrating abdominal trauma, abdominal angiography rarely is indicated, because emergency laparotomy usually is indicated.

Transcatheter embolization (embolotherapy) is the intentional occlusion of a vessel by deposition of thrombogenic materials directly into the vessel via an angiographic catheter under remote control. Transcatheter embolization is the mainstay of modern interventional trauma radiology.

The arteries to be treated must be expendable or nonessential, or they must supply a relatively infarction-resistant vascular bed. Alternatively, they must be associated with distal collateral vessels, such as selective hepatic arteries; alternatively, if they are true end arteries, they must have adequate parenchymal reserve, as with selective renal artery embolization. Usually, these arteries can be ligated surgically.

Transcatheter embolization of active hemorrhage or vascular injury often is considered preferable to surgical treatment; this is the case in the following circumstances:

When rapid occlusion is desired

When surgical access is difficult

When the patient is a poor operative risk

When selective transcatheter embolization may limit the amount of normal tissue or parenchyma necrotized

In trauma, the 2 embolic agents of choice are metallic coils and gelatin sponge. Coils are made of various metals; they are usually fortified with soft fabric material to increase thrombogenicity.

Coils have are permanent occluding agents that remain at the site of deposition. They are best applied in single-vessel injuries; are placed quickly with a high degree of accuracy; and are available in a wide variety of sizes, diameters, lengths, and shapes. Detachable coils include mechanical and electrolytic mechanisms of detachment; they are ideal for occluding aneurysmal sac and may be retrieved if placement is suboptimal.

Gelatin sponges are a temporary occluding agent; the artery often recanalizes within weeks to months. They are best applied in cases involving single or multiple injuries of smaller arteries and are useful when more distal occlusion is necessary or when multiple collateral channels are present. They are administered as a slurry by mixing gelatin sponge powder with nonionic contrast material or as pledgets of various sizes.

Other embolic agents that are used less often in the trauma setting include polyvinyl alcohol(PVA), microspheres, Onyx liquid embolic agent, and N-butyl cyanoacrylate (nBCA) or tissue glue.

PVA is a permanent occluding agent. It is available in small-size particles and is administered in a suspension with contrast material.

Microspheres are permanent embolic agents that are available in different particle sizes.

Onyx is a cohesive liquid agent, which is delivered with a special microcatheter. It causes a permanent occlusion.

Tissue glue is an injectable tissue adhesive. It polymerizes into a solid state when exposed to an ionized fluid, such as blood, and causes a permanent occlusion.

Stent-grafts or covered stents provide a means of salvaging injured or hemorrhaging arteries and increase the options for transcatheter treatment. Bare stents have been used successfully in the treatment of intimal dissection and pseudoaneurysm, as well as acute rupture. Stent grafts, either custom made or commercially available, are alternatives for treating arterial rupture or pseudoaneurysm in suitable vessels.

Stents are covered with vein or synthetic materials, such as polytetrafluoroethylene, polyethylene terephthalate (eg, Dacron), polycarbonate urethane compounds, or other proprietary materials. The stents may be expanded with balloons (iCAST, Atrium) or are self-expandable (Wallgraft, Boston Scientific; Viabahn, Gore; Fluency, BARD). Stents exclude and effectively repair the injured arterial segment.

Synonyms for acute thoracic aortic injury (ATAI) include aortic transection, aortic traumatic pseudoaneurysm, aortic rupture, aortic laceration, and aortic tear. ATAIs are responsible for 10-20% of high-speed traffic accident fatalities. More than 8000 cases per year have been documented in the United States. Most ATAIs represent full-thickness tears; in most cases, ATAIs are fatal, with death occurring at the scene of the accident.

Of patients with ATAI, 10-23% survive long enough to present to the hospital. Among cases of ATAI in patients who survive, approximately 30% are fatal within 6 hours, and 40% are fatal within 24 hours if undiagnosed and left untreated. Only 2-10% of untreated patients survive longer than 6 months.

ATAIs are caused by the rapid deceleration forces produced by high-speed motor vehicle accidents or falls from great heights. During acute deceleration, the thoracic aorta is relatively fixed in position at the aortic root, isthmus, and diaphragm. Movement of the aorta about these points of fixation causes stress and tethering, resulting in a tear at one or more of these locations.

Among patients who experience ATAI and who survive, the locations of the distribution of tears are as follows:

Aortic isthmus, 80-90%

Ascending aorta, 5-9%

Diaphragmatic aorta, 1-3%

Pathologically, a transverse tear of the aortic intima and media is found; in approximately 60% of patients, the adventitia is intact.

Of ATAI cases that are fatal at the scene, a higher percentage of lacerations involve the aortic root.

Multiple sites of ATAI occur in 6-20% of patients; aortic arch branch artery injuries occur in 4-10% of patients.

Imaging of ATAIs consists of plain radiography, CT, conventional thoracic aortography, transesophageal echocardiography, intravascular ultrasound, MRI, and magnetic resonance angiography. Of these, the 3 most commonly used modalities in the assessment of ATAI are plain radiography, CT, and conventional thoracic aortography. ^{[10, 11, 12, 13, 14, 15, 16, 17]}

Radiography

Plain chest radiography has a negative predictive value of 98% and is nonspecific. Findings include the following:

Widened mediastinum

Obscured aortic knob or aortopulmonary window

Deviation of nasogastric tube or trachea

Depressed left mainstem bronchus

Apical pleural cap

Left hemothorax

Abnormal aortic contour

Wide paraspinal stripe

First and second rib fractures

Thick paratracheal stripe

Computed tomography

Computed tomography for detection of mediastinal hematoma is superior to chest radiography; it has a lower rate of false-positive results. Isolated aortic injuries without a mediastinal hematoma are rare. Screening for mediastinal hematoma by CT may increase the rate of positive findings on conventional thoracic aortography. It demonstrates a sensitivity of 100% in aortic injury and has a negative predictive value of 100%.

CT for detection of aortic injury (see the images below) has a sensitivity of 100% and specificity of 96% in aortic injury. The negative predictive value is 100%.

Findings on CT include the following:

Intraluminal low-attenuation focus

Contour abnormality

Pseudoaneurysm

Intramural hematoma

Localized dissection

Catheter aortography

Conventional catheter aortography (see the images below) is the standard of reference to which all other imaging modalities are compared, with a sensitivity of almost 100% and a specificity of 98%. Advantages include good evaluation of ascending thoracic aorta and brachiocephalic arteries. Catheter aortography may be used in conjunction with intravascular ultrasound, and it may be necessary for endovascular (stent-graft) treatment planning. However, to detect a subtle injury, 2 or more views are required.

Findings on catheter aortography include the following:

Intimal irregularity

Linear defect

Intimal flap

Contour abnormality

Pseudoaneurysm

Extravasation

Thickened wall

Pitfalls of catheter angiography include the following:

Anatomic variants

Atheromatous plaque

True aneurysm (ductus aneurysm)

Ductus diverticulum

Aortic spindle

Infundibulum of intercostal artery

Digital subtraction artifacts

Treatment of ATAI should follow the diagnosis promptly. Most patients require surgical repair of the thoracic aorta, usually with an interposition graft. Some patients are not good operative candidates because of concomitant injuries or comorbidities.

In the past, patients who were poor operative risks were treated with medical control of blood pressure and observation in some centers. Currently, selected patients are treated with endovascular aortic stent-grafts; with this approach, the risk associated with a thoracotomy may be avoided. ^{[18, 19, 20, 21, 22, 23, 24]}

The traditional treatment of blunt splenic trauma was surgical splenectomy; however, a trend of splenic salvage through nonoperative management of splenic injury has emerged as traumatologists have come to recognize the important role the spleen plays in preventing overwhelming sepsis by encapsulated organisms such as pneumococcus. ^{[25, 26, 27, 28, 29, 30]}

Nonoperative management should be considered for patients with splenic injury who are hemodynamically stable and who have no associated abdominal or CNS injuries that may preclude an accurate assessment of the abdomen by physical examination. CT is the imaging modality of choice to make the diagnosis of splenic injury, and it may help in grading the degree of injury. Grading scales have been developed to categorize the degree of injury and to assess the likelihood of splenic salvage, but such scales do not have predictive power on an individual basis. ^{[31, 32, 33]}

Some studies have shown that as many as 70% of patients with blunt splenic injuries may be treated nonoperatively, with success rates of 71-97%. Nonoperative management of splenic injuries is effective in more than 95% of children.

The American Association for the Surgery of Trauma has developed scales for classifying the severity of organ injury. The system for grading injury to the spleen is as follows:

Grade I — Small subcapsular hematoma (< 10% of surface area)

Grade II — Moderate subcapsular hematoma on 10-50% of surface area; intraparenchymal hematoma < 5 cm in diameter; capsular laceration < 1 cm deep

Grade III — Large or expanding subcapsular hematoma on more than 50% of surface area; intraparenchymal hematoma greater than 5 cm in diameter; capsular laceration 1-3 cm deep

Grade IV — Laceration more than 3 cm deep; laceration involving segmental or hilar vessels producing major devascularization (>25%)

Grade V — Shattered spleen; hilar injury that results in devascularization of the spleen

Helical CT may be useful in predicting which hemodynamically stable patients may fail nonoperative management if extravasation or posttraumatic splenic vascular injury within the spleen is demonstrated. These patients should be referred for transcatheter embolization of the spleen (see the images below).

The absence of extravasation on conventional angiography may be used to identify patients who may be managed successfully nonoperatively. Some investigators have recommended the liberal use of conventional angiography and transcatheter splenic artery embolization to increase the number of patients successfully managed nonoperatively.

If CT evidence of splenic injury is seen in a hemodynamically stable patient, celiac and splenic angiography is employed. If intrasplenic extravasation is documented, the splenic artery is embolized to occlusion using coils just distal to the dorsal pancreatic artery. If extrasplenic extravasation is documented, a more distal embolization of the splenic artery branches is performed with gelatin sponge pledgets until extravasation resolves; this is followed by coil embolization of the main splenic artery. This may result in a large percentage of patients being treated nonoperatively with a high success rate.

Transcatheter embolization is used for blunt splenic trauma. The indication is extravasation or vascular injury. Techniques include the following:

Proximal coil embolization just distal to the dorsal pancreatic artery and proximal to the pancreatic magna artery to decrease the head of pressure and to preserve distal collateral flow

Nonselective distal embolization using smaller particles such as Gelfoam pledgets

Superselective distal embolization using a microcatheter and microcoils, polyvinyl alcohol particles, or microspheres at the bleeding site

Combination of proximal and distal embolization

For grade IV splenic injuries, Sclafani et al reported an 84% salvage rate, ^[34] and Shanmuganathan et al reported a 94% salvage rate when using splenic embolization. ^[35] In comparison, Brasel et al reported only a 4% salvage rate using only nonoperative treatment. ^[36]

Complications of splenic embolization include inadvertent embolization, splenic infarction and/or abscess, and splenic artery dissection.

Analogous to splenic injury, the trend in blunt hepatic trauma is nonoperative management of the hemodynamically stable patient. The traditional treatment of liver trauma was exploration and surgical packing, but the nontherapeutic laparotomy rate was as high as 67%, largely because in most cases of liver injury, hemorrhage resolves spontaneously before laparotomy can be performed (see the images below). ^{[37, 38, 39, 40, 41, 42, 43]}

The grade of hepatic injury does not necessarily correlate with the rate of success of nonoperative treatment. In grade III and IV liver injuries, reported success rates for nonoperative management range widely. Overall, the nonoperative success rate in patients with liver trauma has been reported to be as high as 89-98%. Patients who are hemodynamically stable but show ongoing signs of hemorrhage (which occurs in 3% of patients) or who have documented extravasation on CT of the liver should undergo conventional angiography of the liver. If these patients have angiographic extravasation, pseudoaneurysm, arteriovenous fistula, or arteriobiliary fistula, transcatheter embolization of the abnormal site should be performed. ^[44]

The American Association for the Surgery of Trauma’s scale for grading the severity of injury to the liver is as follows:

Grade I — Capsular avulsion; periportal blood tracking; superficial laceration less than 1 cm deep; subcapsular hematoma less than 1 cm thick

Grade II — Laceration 1-3 cm deep; subcapsular/central hematoma 1-3 cm in diameter

Grade III — Laceration greater than 3 cm deep; subcapsular/central hematoma greater than 3 cm in diameter

Grade IV — Massive central or subcapsular hematoma greater than 10 cm; lobar tissue maceration or devascularization

Grade V — Bilobar tissue maceration or devascularization

Features of transcatheter embolization of the liver are as follows:

The dual blood supply of the liver makes postembolization infarction less likely

An occluded portal vein is a relative contraindication

Superselective embolization with Gelfoam pledgets or coils/microcoils is desirable

PVA and tissue glue have been used successfully as embolic agents in the hepatic arteries

Hagiwara et al and Ciraulo et al have reported high technical and clinical success rates with embolization in hepatic trauma ^{[45, 46]}

The complication rate is low

Penetrating injuries of the liver from stab and gunshot wounds have been managed successfully with transcatheter embolization using criteria similar to those used in cases of blunt hepatic injury.

Approximately 85-90% of kidney injuries are attributed to blunt renal trauma; penetrating injuries are responsible for 10-15%. The management of blunt trauma of the kidneys has become increasingly conservative over the past 10 years; currently, most grade I and grade II injuries are treated nonoperatively with observation. As with splenic and hepatic injuries, transcatheter embolization may be used to treat hemodynamically stable patients in the following settings: there is evidence of ongoing hemorrhage; there is CT evidence of extravasation or vascular injury; there is persistent or recurrent hematuria; or large retroperitoneal hematomas are present (see the images below). ^{[47, 48, 49, 50, 51, 52, 53, 54]}

Although the treatment of more severe grade III renal injuries is more controversial, there is a trend to treat these injuries nonoperatively as well. In more severe kidney injuries, surgery results in nephrectomy in as many as one third of patients. A perinephric hematoma usually is contained partly by the Gerota fascia. When this is opened with surgery, significant blood loss may occur if vascular control is not obtained promptly. Thus, the physician may elect to perform a trial of transcatheter embolization of the bleeding sites or vascular abnormalities.

Grade IV or V blunt renal injuries usually require surgery for definitive treatment, which also may result in nephrectomy; however, some of these injuries may be managed nonoperatively.

In cases of penetrating renal trauma, surgical exploration is commonly employed, particularly if the peritoneum has been transgressed. Conventional angiography may delineate precisely the status of the renal vasculature preoperatively; it may be a prelude to transcatheter embolization in a limited number of cases (see the images below).

Nonvascular percutaneous intervention may be applied to urinoma, urine leak, ureteral laceration, and transection injuries. These interventions include percutaneous nephrostomy for urine diversion, ureteral stent placement for ureteral injuries, and drainage tube placement for urinoma formation. ^{[55, 56, 57, 58, 59, 60]}

The American Association for the Surgery of Trauma’s system for grading injury to the kidney is as follows:

Grade I — Contusion or contained and nonexpanding subcapsular hematoma, without parenchymal laceration; hematuria

Grade II — Nonexpanding, confined, perirenal hematoma or cortical laceration less than 1 cm deep; no urinary extravasation

Grade III — Parenchymal laceration extending more than 1 cm into cortex; no collecting system rupture or urinary extravasation

Grade IV — Parenchymal laceration extending through the renal cortex, medulla, and collecting system

Grade V — Pedicle injury or avulsion of renal hilum that devascularizes the kidney; completely shattered kidney; thrombosis of the main renal artery

Transcatheter embolization of renal injuries

The kidney is an end-artery organ with minor transcapsular and intrarenal collaterals.

Superselective distal embolization with Gelfoam pledgets or microcoils is desirable.

Transcatheter embolization of injuries to the branch arteries is successful in 84-100% of patients.

Hemorrhage associated with pelvic trauma, with or without pelvic fracture, is common and may arise from venous, osseous, or arterial sources or any combination of the above. Typically, pelvic hemorrhage is treated first with the use of external fixation; external fixation is usually successful in treating venous and osseous bleeding, through a tamponade effect. External fixation may reduce a fracture and/or dislocation, thus decreasing the pelvic space and increasing the tamponade effect. ^{[61, 62, 63]}

Continued bleeding may indicate an arterial source; such bleeding is associated with high morbidity and mortality rates. Intractable hemorrhage associated with pelvic fracture is a large contributor to the overall mortality rate of approximately 10%. Surgical exploration and intervention of a pelvic hematoma often is complex, owing to the difficulties in visualizing the hemorrhaging artery or arteries within the extraperitoneal hematoma and in gaining arterial control. In addition, an operation exposes the patient to the added risk of increased blood loss through surgical disruption of the pelvic fascia; this may be important in the tamponade of the hematoma.

In many trauma centers, conventional angiography and, potentially, transcatheter embolization are employed for patients with pelvic trauma who have already undergone abdominal exploration and are known to have an associated solid organ injury and who continue to hemorrhage despite external fixation. ^{[64, 65]} In other trauma centers, angiography may be obtained before external fixation or surgical abdominal exploration if significant hemorrhage is present, even in unstable patients. ^[66]

Transcatheter embolization of pelvic trauma that is performed early, within 3 hours of presentation, has been shown to lower the mortality rate. Overall, angiography is required in fewer than 10% of patients with pelvic trauma. When angiography is performed, extravasation is documented in approximately one half of patients; in such cases, transcatheter embolization is warranted.

As with other injuries, Cerva et al and Stephen et al have shown that CT is indispensable in diagnosing and monitoring pelvic hemorrhage. ^{[67, 68]} CT also is necessary in making the diagnosis of and classifying pelvic fractures and/or dislocations. The sensitivity and specificity of CT for active extravasation in cases of pelvic trauma is 80-84% and 85-98%, respectively. CT evidence of extravasation in the pelvis is an indication for transcatheter embolization.

In pelvic trauma, arterial bleeding most frequently occurs from superior gluteal and internal pudendal arteries. The fascia of the piriformis muscle may lacerate the superior gluteal artery, even in the absence of fracture. All branches of the hypogastric artery are at risk for bleeding.

Knowledge of the relationship of branch arteries of the hypogastric artery to the surrounding and adjacent musculotendinous and ligamentous structures is helpful in predicting arterial injuries and in directing selective catheterization for angiography. Pelvic and retroperitoneal hemorrhage also may arise from the lumbar, inferior epigastric, deep circumflex iliac, and middle sacral arteries.

For pelvic angiography, access from the common femoral artery contralateral to the pelvic hematoma, fracture, or extravasation is demonstrated on CT (see the images below).

The procedure is as follows:

Initially, nonselective pelvic angiography is performed from a catheter in the lower abdominal aorta.

Next, the hypogastric artery of interest is selected, and selective hypogastric angiography is performed.

Microcatheters are needed for superselective angiography and embolization.

Brisk hemorrhage may be evident on nonselective pelvic angiogram, but subtle extravasation may require selective or subselective angiography for detection.

Pelvic transcatheter embolization technique is as follows:

If possible, and when the source of extravasation is defined, superselective embolization with gelatin sponge pledgets of 1-2 mm in diameter or slurry is optimal.

Proximal coil embolization is less attractive for distal extravasation because it makes future access difficult (should it be needed) and because the exuberant distal collateralization of the pelvic vasculature renders this technique ineffective.

Proximal coil embolization for proximal hypogastric artery injury should be performed; it may be performed after embolization with distal gelatin sponge pledgets.

In patients with massive hemorrhage, nonselective embolization using gelatin sponge pledgets from the hypogastric artery position is acceptable; with this approach, bleeding may be quickly arrested.

Empirical embolization of both hypogastric arteries may be performed if no bleeding site is identified on angiography but there is clinical or CT evidence of hemorrhage.

A postembolization nonselective angiogram should be performed to exclude additional extravasation sites and to ensure that collateral vessels are not causing retrograde (backfill) hemorrhage; in such cases, further embolization is required.

For pelvic transcatheter embolization, the success rate of stopping hemorrhage is 85-100%. Despite high technical success rates, the mortality rate is approximately 50% because of concomitant injuries.

Pelvic transcatheter embolization complications include the following:

Inadvertent embolization — Occurs only rarely, provided catheter position is satisfactory and the embolization procedure is terminated once occlusion is established.

Ischemic tissue necrosis or infarction — Occurs only rarely, provided particle sizes remain larger than 500 microns, in cases involving extensive distal collateralization of the pelvic vasculature

Impotence in men — Difficult to differentiate from impotence of neurogenic etiology related to injuries to the lumbosacral plexus

Peripheral vascular trauma is relatively common in urban settings where penetrating injuries often occur. In nonurban settings, nonpenetrating peripheral vascular injuries, such as occur with blunt trauma, crush injuries, injuries associated with displaced skeletal fractures and joint dislocations, and degloving injuries, are seen more often (see the images below). ^{[69, 70, 71, 72, 73]}

Catheter angiography is indicated in cases of known or suspected peripheral vascular injury when the location of the injury is not certain, when multiple injury sites may be present, when the diagnosis requires confirmation, or when transcatheter treatment may be the therapy of choice.

The mechanisms of injury differ for penetrating trauma and blunt trauma. In penetrating trauma, the vascular injury may be produced by the direct penetration of the object through the vessel, with resulting disruption, or by dissipation of kinetic energy within the tissues adjacent to the vessel. In the case of low-velocity objects such as knives, the object must traverse the vessel, and the object must penetrate it to cause injury.

In injuries caused by high-velocity weapons such as hunting rifles and assault weapons, the object does not need to penetrate the vessel to cause damage. With high-velocity objects, kinetic energy is expelled and dissipated within the surrounding tissues as the object decelerates. This causes shock waves and cavitation, which produce injury within the local soft tissues. High-power penetrating objects may produce injury to vessels within a 10 cm radius of the trajectory. These are termed proximity injuries. Any of these mechanisms may cause laceration, pseudoaneurysm formation, transection, arteriovenous fistula, or thrombosis of the vessel. ^[74]

In blunt trauma, shearing and direct compression forces are involved. A direct compression or crushing force may produce an injury such as a mural contusion. The shearing mechanism, which occurs with stretching or traction forces, produces complete transection or intimal or medial dissection, which may result in the formation of a pseudoaneurysm. In addition, severe extrinsic compression from such entities as an adjacent hematoma, a fracture fragment, a dislocation, or edema, may cause severe narrowing of the vessel, which in turn may result in thrombosis. Vasospasm may occur as an isolated injury or in association with the above-mentioned vascular insults.

Many peripheral vascular injuries may be treated by transcatheter embolization or with the placement of a stent or a stent-graft placement. ^{[75, 76]}

Major indications for catheter angiography include the following:

Active arterial bleeding or expanding hematoma

Peripheral pulse deficit

Bruit over the site of injury

Isolated neurologic deficit

Hypotension or other sign of ongoing hemorrhage

Minor indications for catheter angiography include the following:

Proximity of a wound or trajectory to a major blood vessel

Nonexpanding hematoma

Posterior dislocation of the knee joint and anterior dislocation of the elbow joint

Catheter angiography technique is as follows:

As in the evaluation of atherosclerotic disease, the principles of interrogation of inflow and outflow should be followed

A minimum of 2 angiographic views centered on the region of injury usually is required

Outflow should be examined to exclude a distal embolization from a proximal injury site

In gunshot injuries, angiography or fluoroscopy of the entire extremity should be undertaken to exclude embolization of metallic gunshot, shrapnel, or fragments

For transcatheter embolization, the artery to be embolized must be nonessential or expendable. This is an alternative to surgical ligation. It provides optimal treatment when surgical access is limited or difficult and requires ligation of additional collateral arteries.

Embolization may be performed for pseudoaneurysm and arteriovenous fistula. Embolization should be performed proximally and distally to the lesion to prevent backfilling through collateral vessels. Consideration should be given to embolizing the neck of a pseudoaneurysm or arteriovenous fistula to preserve the parent vessel. A success rate of 85-100% is reported.

For stents and stent-grafts, experience with stents in cases of trauma is limited. Stents have the potential to preserve injured arteries.

Most vascular injuries of the head and neck arise from penetrating trauma. Significant penetrating injuries usually require surgical exploration; however, patients with less accessible zone 1 and zone 3 penetrating neck injuries may benefit from angiographic screening and possible treatment, such as transcatheter embolization if the injury involves a branch of the external carotid artery (see the images below). ^{[77, 78, 79, 80, 81, 82]}

Blunt injuries of the carotid and vertebral arteries appear to be more common than previously suggested. Early diagnosis and treatment of these injuries improves neurologic outcome. Aggressive screening protocols may increase the diagnosis of these injuries; the failure to diagnose and treat these lesions may result in a devastating and permanent neurologic injury. The pathophysiology of blunt carotid and cervical injuries usually is dissection, which may result in a stenosis, pseudoaneurysm formation, or both. Extracranial internal carotid injuries are much more common than intracranial internal carotid injuries; they usually originate at the C2-C3 vertebral level and terminate at the base of the carotid canal.

Historically, treatment of blunt injuries of the carotid and vertebral arteries included anticoagulation and antiplatelet therapy, although some patients required surgical repair. More recently, reports and series documenting the successful management and definitive treatment of blunt internal carotid artery injuries with endovascular stents have been published. ^{[83, 84]} Unilateral injuries of the vertebral artery often are treated with transcatheter embolization; such treatment requires that the contralateral vertebral artery be patent and of normal appearance.

The grading scale for blunt carotid arterial injury is as follows:

Grade I — Luminal irregularity or dissection with less than 25% luminal narrowing

Grade II — Dissection or intramural hematoma with luminal narrowing of 25% or more; intramural thrombus; or raised intimal flap

Grade III — Pseudoaneurysm

Grade IV — Occlusion

Grade V — Transection with free extravasation

The findings associated with blunt carotid or vertebral injury are as follows:

Expanding cervical hematoma

Hemorrhage from mouth, nose, ears, or wounds

Massive facial fractures

Cervical bruit in patients younger than 50 years

Evidence of stroke on CT

Unexplained or incongruous central or lateralizing neurologic deficit, anisocoria, Horner syndrome, transient ischemic attack, or amaurosis fugax

Basilar skull fracture through or near the carotid canal

Fracture through the foramen transversarium

Severe flexion or extension fracture or subluxation of the cervical spine

Conventional catheter angiography remains the standard of reference to which all other imaging modalities are compared. Advantages include accuracy and facilitation of treatment through transcatheter embolization or endovascular stent or stent-graft placement. Disadvantages include the fact that it is not universally available in a timely fashion; it is invasive, with a small risk of catheter-induced stroke; and it is expensive.

Ultrasonography requires less experience in the trauma setting; it can be quickly performed and is inexpensive; and it is portable and therefore can be used at the bedside. However, it is operator dependent and is less effective in zone-1 and zone-3 injuries and injuries of the vertebral artery.

Magnetic resonance angiography requires little experience in the acute trauma setting. It may be used in conjunction with imaging of the CNS and does not require administration of iodinated contrast material. However, it is susceptible to motion artifact; it requires MRI-compatible life-support devices; it is not universally available; and its efficacy is not yet proven.

CT angiography evaluation often is obtained in stable trauma patients. It provides fast imaging from aortic arch to intracerebral vasculature and may be used in conjunction with imaging of the CNS and spine. It does, however, require iodinated contrast material; it is not universally available; and its efficacy has not been proven.

With regard to endovascular management, multiple small series and case reports with follow-up periods of up to 2.5 years suggest that the use of metallic stent placement is effective in treating traumatic pseudoaneurysm of the internal carotid artery.

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Christopher S Morris, MD Associate Professor of Radiology, Program Director, Department of Vascular and Interventional Radiology, University of Vermont College of Medicine

Christopher S Morris, MD is a member of the following medical societies: American College of Radiology

Disclosure: Nothing to disclose.

Douglas M Coldwell, MD, PhD Professor of Radiology, Director, Division of Vascular and Interventional Radiology, University of Louisville School of Medicine

Douglas M Coldwell, MD, PhD is a member of the following medical societies: American Association for Cancer Research, American Heart Association, SWOG, Special Operations Medical Association, Society of Interventional Radiology, American Physical Society, American College of Radiology, American Roentgen Ray Society

Disclosure: Received consulting fee from Sirtex, Inc. for speaking and teaching; Received honoraria from DFINE, Inc. for consulting.

Kyung J Cho, MD, FACR, FSIR William Martel Emeritus Professor of Radiology (Interventional Radiology), Frankel Cardiovascular Center, University of Michigan Health System

Kyung J Cho, MD, FACR, FSIR is a member of the following medical societies: American College of Radiology, American Heart Association, American Medical Association, American Roentgen Ray Society, Association of University Radiologists, Radiological Society of North America

Disclosure: Nothing to disclose.

Anthony Watkinson, MD Professor of Interventional Radiology, The Peninsula Medical School; Consultant and Senior Lecturer, Department of Radiology, The Royal Devon and Exeter Hospital, UK

Anthony Watkinson, MD is a member of the following medical societies: Radiological Society of North America, Royal College of Radiologists, Royal College of Surgeons of England

Disclosure: Nothing to disclose.

Interventional Radiology for Vascular and Solid Organ Trauma

Research & References of Interventional Radiology for Vascular and Solid Organ Trauma|A&C Accounting And Tax Services
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