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Abdominal Compartment Syndrome

¹ All authors: Department of Radiology, Indiana University School of Medicine, 550 N University Blvd., Suite UH 0279, Indianapolis, IN 46202.

Received February 19, 2007; accepted after revision May 20, 2007.

 
Address correspondence to K. Sandrasegaran.

CME

This article is available for CME credit. See www.arrs.org for more information.

Abstract

Top Abstract Introduction Pathogenesis of Abdominal... Clinical Diagnosis Radiologic Findings Acute Compartment Syndrome in... Treatment of Abdominal... Conclusions References

 
OBJECTIVE. The purpose of this article is to discuss the pathogenesis, clinical features, radiologic findings, and treatment of abdominal compartment syndrome, which is defined as an acute elevation of the intraabdominal pressure with organ dysfunction.

CONCLUSION. Abdominal compartment syndrome is not well reported in the radiology literature. In this review, we discuss a range of CT signs such as elevated diaphragm, collapsed inferior vena cava, bowel wall thickening, bowel mucosal hyperenhancement, hemoperitoneum, and increasing abdominal girth, which, in combination, may allow the radiologist to raise the possibility of abdominal compartment syndrome.

Keywords: abdominal compartment syndrome • CT diagnosis • intraabdominal hypertension

Introduction

Top Abstract Introduction Pathogenesis of Abdominal... Clinical Diagnosis Radiologic Findings Acute Compartment Syndrome in... Treatment of Abdominal... Conclusions References

 
Compartment syndrome is well known in the extremities, where increased pressure within a closed fascial space depresses capillary perfusion pressure to a level that cannot maintain tissue viability. The effects of elevated intraabdominal pressure are less well recognized. Normally, the abdominal pressure is about 5 mm Hg. The intraabdominal pressure may increase with acute and substantial accumulation of fluid within the abdomen. "Abdominal compartment syndrome" is defined as intraabdominal pressure of at least 20 mm Hg with dysfunction of at least one thoracoabdominal organ [1–4]. In nearly all cases, there is some amelioration of organ function after decompressive laparotomy. Primary abdominal compartment syndrome results from injury or disease in the abdominopelvic region, such as after liver transplantation or pelvic fractures. Secondary abdominal compartment syndrome occurs from disease originating from outside the abdomen, such as from major burns or sepsis.

There are virtually no radiology reports of abdominal compartment syndrome. One reason for this may be that CT is not ordered for the diagnosis of abdominal compartment syndrome. The diagnosis is usually rapidly performed at the bedside with intravesical pressure measurements. However, radiologists should understand this entity because it is likely that many of these patients, especially those with trauma or pancreatitis, will undergo CT studies for determining the severity of the illness and for identifying potential complications. In this review, we discuss the pathogenesis, clinical features, radiologic findings, and treatment of abdominal compartment syndrome.

Pathogenesis of Abdominal Compartment Syndrome

Top Abstract Introduction Pathogenesis of Abdominal... Clinical Diagnosis Radiologic Findings Acute Compartment Syndrome in... Treatment of Abdominal... Conclusions References

 
As intraabdominal pressure rises, progressive organ failure occurs (Fig. 1). The kidneys and lungs are the most affected. With abdominal pressure of 15–20 mm Hg, the urinary output is reduced. When the pressure exceeds 30 mm Hg, anuria ensues [3, 5]. Renal failure is caused by external pressure on the renal vasculature and parenchyma [6]. Ureteric obstruction is not thought to be a cause [5].

View larger version (16K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 1 —Line diagram shows pathogenesis of abdominal compartment syndrome and sequence of events that lead to multiorgan failure. GFR = glomerular filtration rate, IVC = inferior vena cava.

In abdominal compartment syndrome, the diaphragm becomes elevated with reduced excursion. The thoracic volume and compliance are reduced. The ensuing compressive atelectasis and ventilatory perfusion mismatch lead to hypercarbia and respiratory acidosis [9, 10]. Oxygen delivery decreases with increasing abdominal pressure. Hypoxia is found in 20% of patients with abdominal pressure above 15 mm Hg and in all patients when the pressure exceeds 35 mm Hg [3]. Decompression usually results in prompt reversal of respiratory failure [2].

Increased abdominal pressure reduces venous return from the inferior vena cava and increases systolic arterial pressure in abdominal arteries [10]. Increased thoracic pressure reduces cardiac output. Elevated intracranial pressure may occur and has been shown to decline after decompression surgery for abdominal compartment syndrome [11].

Clinical Diagnosis

Top Abstract Introduction Pathogenesis of Abdominal... Clinical Diagnosis Radiologic Findings Acute Compartment Syndrome in... Treatment of Abdominal... Conclusions References

 
The rapid accumulation of abdominal fluid in some conditions (Table 1) may cause organ dysfunction. In contrast, a more gradual rise in abdominal pressure, such as in normal pregnancy or in ascitic accumulation in liver disease or ovarian cancer, does not normally result in abdominal compartment syndrome. Laparoscopy with pneumoperitoneum may cause elevated intraabdominal pressure, but the effect is transient and not to the degree required to cause abdominal compartment syndrome [12, 13].

Findings suggestive of abdominal compartment syndrome include a tensely distended abdomen; increased peak airway pressure; difficulty in maintaining ventilation, with hypoxia and hypercarbia; increasing creatinine; and oliguria. Increased gastric acidity is also a recognized finding of abdominal compartment syndrome [14]. However, most patients with abdominal compartment syndrome are in intensive care units, and clinical examination is usually not sensitive for diagnosing this entity.

Diagnosis of abdominal compartment syndrome is complicated by the fact that these patients have many other explanations for renal or pulmonary failure. Sepsis, acute respiratory distress syndrome, hypovolemic shock, and multiorgan failure syndrome are frequently seen in patients who are also at risk of abdominal compartment syndrome. In some patients, these diverse and potentially lethal conditions may coexist [15]. Unlike in pure hypovolemic shock, the mean arterial pressure is normal in abdominal compartment syndrome. Central venous and pulmonary wedge pressures are poor indicators of volume depletion in abdominal compartment syndrome because they are artificially elevated due to the increased thoracic pressure. In contrast to hypovolemic shock, it is unusual for renal failure to occur in patients with abdominal compartment syndrome without concomitant respiratory failure [16]. However, rapid IV resuscitation of a patient in hypovolemic shock may precipitate abdominal compartment syndrome [15].

In general, abdominal compartment syndrome should be suspected in any patient with the appropriate clinical antecedents whose organ dysfunction worsens or does not improve in the face of adequate supportive therapy. Measurement of intraabdominal pressure is required in such patients and is best assessed by a transurethral probe inserted in the urinary bladder [17, 18]. However, intravesical pressure measurements may not accurately reflect intraabdominal pressure if there is a neurogenic or contracted bladder, abdominal packing, or abdominal adhesions [12, 19].

Radiologic Findings

Top Abstract Introduction Pathogenesis of Abdominal... Clinical Diagnosis Radiologic Findings Acute Compartment Syndrome in... Treatment of Abdominal... Conclusions References

 
There is limited information, to our knowledge, regarding the radiologic findings in abdominal compartment syndrome. The CT findings in a total of eight adult and pediatric patients have been reported [20–22]. We reviewed the images obtained in 21 adult patients from our institution with clinically proven abdominal compartment syndrome on grounds of organ failure (usually lung or kidneys) and intravesical pressure measurement of at least 20 mm Hg. The mean of the maximum recorded intravesical pressure in our series of patients was 26.2 mm Hg (range, 20.4–34.5 mm Hg). CT was performed between 3 days before and 26 hours after the pressure measurements. When multiple CT scans were available, we reviewed the scans temporally closest to the maximum measured intravesical pressure. The causes of abdominal compartment syndrome were trauma (n =13), postoperative bleeding (n = 4), liver transplantation (n = 1), and severe pancreatitis (n =3).

We found several radiologic signs that may be associated with this condition (Table 2). Because we did not have a control group of patients with trauma or pancreatitis who did not have abdominal compartment syndrome, we cannot comment on how specific these findings are. An elevated diaphragm has been noted when the intraabdominal pressure rises above 15 mm Hg [23] (Fig. 2A, 2B, 2C, 2D, 2E, 2F). This was the single most common finding in our group. However, quantification of the diaphragm elevation is difficult even when comparison chest radiographs are available because CT scanograms are performed during quiet breathing in a supine position, whereas posteroanterior chest radiographs are not.

View larger version (181K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2A —57-year-old man with diabetes who had laparotomy for infective aortitis. Scout CT image obtained 1 day after surgery shows normal position of diaphragm. Reason for horizontal artifacts on this image is not clear.

View larger version (93K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2B —57-year-old man with diabetes who had laparotomy for infective aortitis. Axial CT images from same series as A show ascites, normal position of diaphragm, and normal-sized inferior vena cava (IVC) (arrowhead, B). Also seen are hemoperitoneum (solid white arrow, C) and mucosal hyperenhancement of bowel (dashed arrows, C). Postoperative free peritoneal air is present. Black arrow in C indicates anteroposterior abdominal girth.

View larger version (90K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2C —57-year-old man with diabetes who had laparotomy for infective aortitis. Axial CT images from same series as A show ascites, normal position of diaphragm, and normal-sized inferior vena cava (IVC) (arrowhead, B). Also seen are hemoperitoneum (solid white arrow, C) and mucosal hyperenhancement of bowel (dashed arrows, C). Postoperative free peritoneal air is present. Black arrow in C indicates anteroposterior abdominal girth.

View larger version (175K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2D —57-year-old man with diabetes who had laparotomy for infective aortitis. Scout image from CT obtained 7 days later shows elevated right hemidiaphragm.

View larger version (97K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2E —57-year-old man with diabetes who had laparotomy for infective aortitis. Axial CT images from same study show as D show collapsed IVC (arrowheads) with greatly increased ascites and evidence of layered hemoperitoneum (white arrows, F). Anteroposterior abdominal girth (black double arrow, F) increased from C to F. Note jejunal feeding tube (black arrow, F) and heavily calcified iliac arteries (curved arrow, F). Patient had intraabdominal hypertension (intravesical pressure of 28 mm Hg). Emergency decompressive laparotomy was performed and patient survived.

View larger version (88K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2F —57-year-old man with diabetes who had laparotomy for infective aortitis. Axial CT images from same study show as D show collapsed IVC (arrowheads) with greatly increased ascites and evidence of layered hemoperitoneum (white arrows, F). Anteroposterior abdominal girth (black double arrow, F) increased from C to F. Note jejunal feeding tube (black arrow, F) and heavily calcified iliac arteries (curved arrow, F). Patient had intraabdominal hypertension (intravesical pressure of 28 mm Hg). Emergency decompressive laparotomy was performed and patient survived.

In our experience, abdominal measurements on a single CT scan are nonspecific, and an increased anteroposterior abdominal dimension may be seen with chronic ascites. Hemoperitoneum may be a more sensitive indicator for abdominal compartment syndrome than simple ascites (Figs. 3A, 3B, 3C, 4A, 4B, 4C, 5A, 5B, 6A, 6B, 6C, 6D). A previous case series of four patients suggested that when the ratio of the maximum anteroposterior abdominal girth to the lateral girth was higher than 0.8, abdominal compartment syndrome was likely [20]. In almost all of our patients with proven abdominal compartment syndrome (20 of 21), this ratio was lower than 0.7 (Fig. 6A, 6B, 6C, 6D). However, increasing girth seen on serial CT scans performed at short intervals is worrisome (Fig. 2A, 2B, 2C, 2D, 2E, 2F).

View larger version (124K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 3A —76-year-old woman after motor vehicle accident. Contrast-enhanced CT images show spleen is nonenhancing (white arrow, A), and grade 5 splenic injury was diagnosed. There is abdominal distention with large hematoma (solid black arrows, A and B), which displaces posteriorly and effaces stomach (containing nasogastric tube [arrowheads, A and B]). Bowel wall shows increased enhancement (arrowheads, C), and inferior vena cava (dashed arrows, A and B) and renal veins are flattened. These findings are also seen with severe hypotension (shock bowel), and imaging diagnosis of abdominal compartment syndrome cannot be made with certainty. However, at time of CT, patient was on inotropic agents and had normal renal function and blood pressure (hence decision to use IV contrast agent). In addition, intravesical pressure was 26 mm Hg, and patient underwent emergency laparotomy for splenectomy and evacuation of blood clot.

View larger version (137K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 3B —76-year-old woman after motor vehicle accident. Contrast-enhanced CT images show spleen is nonenhancing (white arrow, A), and grade 5 splenic injury was diagnosed. There is abdominal distention with large hematoma (solid black arrows, A and B), which displaces posteriorly and effaces stomach (containing nasogastric tube [arrowheads, A and B]). Bowel wall shows increased enhancement (arrowheads, C), and inferior vena cava (dashed arrows, A and B) and renal veins are flattened. These findings are also seen with severe hypotension (shock bowel), and imaging diagnosis of abdominal compartment syndrome cannot be made with certainty. However, at time of CT, patient was on inotropic agents and had normal renal function and blood pressure (hence decision to use IV contrast agent). In addition, intravesical pressure was 26 mm Hg, and patient underwent emergency laparotomy for splenectomy and evacuation of blood clot.

View larger version (142K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 3C —76-year-old woman after motor vehicle accident. Contrast-enhanced CT images show spleen is nonenhancing (white arrow, A), and grade 5 splenic injury was diagnosed. There is abdominal distention with large hematoma (solid black arrows, A and B), which displaces posteriorly and effaces stomach (containing nasogastric tube [arrowheads, A and B]). Bowel wall shows increased enhancement (arrowheads, C), and inferior vena cava (dashed arrows, A and B) and renal veins are flattened. These findings are also seen with severe hypotension (shock bowel), and imaging diagnosis of abdominal compartment syndrome cannot be made with certainty. However, at time of CT, patient was on inotropic agents and had normal renal function and blood pressure (hence decision to use IV contrast agent). In addition, intravesical pressure was 26 mm Hg, and patient underwent emergency laparotomy for splenectomy and evacuation of blood clot.

View larger version (153K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 4A —20-year-old woman who presented with traumatic placental abruption at 26 weeks' gestation. CT was performed to exclude trauma to abdominal organs. Contrast-enhanced CT images show high-density peritoneal fluid (white arrows, A and B) indicating hemoperitoneum. Bowel walls are thickened and show increased enhancement (black arrows, A and B). Inferior vena cava is collapsed (black arrowheads, A and B). Extravasation of IV contrast material is seen in placenta (white arrowheads, C). Intravesical pressure was 29 mm Hg. Patient was moribund and underwent emergency cesarean section. She died 2 days later of multiorgan failure.

View larger version (154K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 4B —20-year-old woman who presented with traumatic placental abruption at 26 weeks' gestation. CT was performed to exclude trauma to abdominal organs. Contrast-enhanced CT images show high-density peritoneal fluid (white arrows, A and B) indicating hemoperitoneum. Bowel walls are thickened and show increased enhancement (black arrows, A and B). Inferior vena cava is collapsed (black arrowheads, A and B). Extravasation of IV contrast material is seen in placenta (white arrowheads, C). Intravesical pressure was 29 mm Hg. Patient was moribund and underwent emergency cesarean section. She died 2 days later of multiorgan failure.

View larger version (150K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 4C —20-year-old woman who presented with traumatic placental abruption at 26 weeks' gestation. CT was performed to exclude trauma to abdominal organs. Contrast-enhanced CT images show high-density peritoneal fluid (white arrows, A and B) indicating hemoperitoneum. Bowel walls are thickened and show increased enhancement (black arrows, A and B). Inferior vena cava is collapsed (black arrowheads, A and B). Extravasation of IV contrast material is seen in placenta (white arrowheads, C). Intravesical pressure was 29 mm Hg. Patient was moribund and underwent emergency cesarean section. She died 2 days later of multiorgan failure.

View larger version (111K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 5A —50-year-old man after motor vehicle accident. Contrast-enhanced CT images show extensive hemoperitoneum in right upper quadrant (white arrowheads). Note right rib fracture on A. Liver dome is superiorly positioned in relation to heart in A, indicating right hemidiaphragmatic elevation. There is inhomogeneous and patchy hepatic enhancement. Inferior vena cava is collapsed (black arrowhead, B). Grade 5 liver trauma was diagnosed. Intravesical pressure was 32 mm Hg. Patient underwent emergency laparotomy but died soon afterward.

View larger version (116K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 5B —50-year-old man after motor vehicle accident. Contrast-enhanced CT images show extensive hemoperitoneum in right upper quadrant (white arrowheads). Note right rib fracture on A. Liver dome is superiorly positioned in relation to heart in A, indicating right hemidiaphragmatic elevation. There is inhomogeneous and patchy hepatic enhancement. Inferior vena cava is collapsed (black arrowhead, B). Grade 5 liver trauma was diagnosed. Intravesical pressure was 32 mm Hg. Patient underwent emergency laparotomy but died soon afterward.

View larger version (169K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 6A —54-year-old man who underwent orthotopic liver transplantation. Scout radiograph (A) and axial CT scan (B) performed 3 days after liver transplantation show elevated left hemidiaphragm (arrow, A) and collapsed inferior vena cava (arrowhead, B). Note severe ascites in B. Intravesical pressure was elevated (21 mm Hg).

View larger version (112K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 6B —54-year-old man who underwent orthotopic liver transplantation. Scout radiograph (A) and axial CT scan (B) performed 3 days after liver transplantation show elevated left hemidiaphragm (arrow, A) and collapsed inferior vena cava (arrowhead, B). Note severe ascites in B. Intravesical pressure was elevated (21 mm Hg).

View larger version (78K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 6C —54-year-old man who underwent orthotopic liver transplantation. Color Doppler sonogram shows virtually no diastolic flow in main hepatic artery. In fact, initial reversal of diastolic flow (arrows) is seen.

View larger version (158K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 6D —54-year-old man who underwent orthotopic liver transplantation. Patient underwent therapeutic paracentesis with drainage of 10.5 L of serous fluid. Postdrainage scout radiograph (same magnification as scout image A) shows return of diaphragm to normal position and reduced distention. Skin folds (arrowheads) were seen after acute abdominal decompression. Decompressive surgery was not required. Abdominal compartment syndrome is rare in patients undergoing liver transplantation at our institution, possibly because fascia is routinely left open, and skin is sutured. After satisfactory postoperative recovery, fascia and skin are closed a few days later.

Flattened inferior vena cava and increased bowel enhancement (shock bowel) may be seen in hypovolemic shock and are not specific to abdominal compartment syndrome (Fig. 3A, 3B, 3C). However, these findings were seen in our patients who were not hypotensive. Therefore, we believe that these findings can also be seen in abdominal compartment syndrome in the absence of hypotension. In another study, two of four patients with abdominal compartment syndrome had increased bowel enhancement and renal compression. Flattened renal veins was a common finding on CT in our patients (n = 14). Mosaic liver perfusion was seen in some patients with trauma to the liver (Fig. 5A, 5B).

Small-bowel dilatation was seen in only two patients. In addition, three patients had gastric distention. The reason for gastric distention is not clear. In the three patients with clinical suspicion of abdominal compartment syndrome after liver transplantation, the resistive indexes of the hepatic arteries were elevated, with virtually no diastolic flow or even reversed flow (Fig. 7A, 7B, 7C).

View larger version (166K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 7A —67-year-old man who presented with severe acute pancreatitis. Scout image shows elevated diaphragm (arrow) and abdominal distention.

View larger version (130K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 7B —67-year-old man who presented with severe acute pancreatitis. CT image shows inferior vena cava (arrowhead) is collapsed. IV contrast material was not given due to renal dysfunction.

View larger version (148K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 7C —67-year-old man who presented with severe acute pancreatitis. CT image shows severe pancreatic ascites. Ratio of maximum anteroposterior girth to lateral abdominal girth is 0.65 (double-headed arrows).

Acute Compartment Syndrome in Specific Situations

Top Abstract Introduction Pathogenesis of Abdominal... Clinical Diagnosis Radiologic Findings Acute Compartment Syndrome in... Treatment of Abdominal... Conclusions References

 
Trauma
Of patients with severe blunt abdominal trauma, 5–20% develop abdominal compartment syndrome [3, 24]. This risk is higher in patients with grade 5 liver trauma or combined abdominopelvic injury and in those who have undergone abdominal packing for bleeding or primary fascial closure after laparotomy. In a series of 311 patients with abdominopelvic trauma who subsequently developed abdominal compartment syndrome [24], the liver was the most frequent site of injury (Fig. 5A, 5B). Injuries to the spleen, pancreas, and bowel have also been associated with predisposition to abdominal compartment syndrome.

Another study of 70 patients who developed abdominal compartment syndrome after a penetrating abdominal trauma [14] found gastrointestinal and vascular (arterial or venous) injury in 70% and 35% of patients, respectively. Rarely, abdominal compartment syndrome may develop in patients without visible organ injury [24]. Trauma patients with abdominal compartment syndrome show a reduction in intraabdominal pressure and improvements in hemodynamic status and renal and pulmonary function after decompressive laparotomy.

In our series of patients with abdominal compartment syndrome after trauma (n = 13), the organs injured were liver (n =6), spleen (n = 4), mesentery or small bowel (n =3), kidneys (n = 3), pancreas (n = 2), and uterus (n = 1). Some patients had multiple organ injuries. In all cases, the organ injury was moderate to severe (grades 3–5), with hemoperitoneum seen on CT in 11 cases (Figs. 3A, 3B, 3C, 4A, 4B, 4C, 5A, 5B).

Liver Transplantation
Several factors associated with liver transplantation lead to elevated intraabdominal pressure. These include bowel edema from portal vein clamping, hepatic reperfusion edema, and donor–recipient graft-size mismatch match [25]. The occurrence of abdominal compartment syndrome with intraabdominal pressure of more than 25 mm Hg after liver transplantation is thought to be 30% [26]. After liver transplantation, there is an increased incidence of portal vein and hepatic artery thrombosis in patients with acute compartment syndrome compared with those without acute compartment syndrome [27]. In our experience, peripheral infarction of the liver, lack of diastolic flow in the hepatic artery branches (Fig. 6A, 6B, 6C, 6D), and to-and-fro flow in the portal vein may be sonographic markers of rising intraabdominal pressure.

Pancreatitis
The prevalence of intraabdominal hypertension in patients with severe acute pancreatitis is about 40–50% [28], and the frequency of abdominal compartment syndrome requiring surgical decompression is about 10% [29]. Early and aggressive fluid resuscitation in patients with severe acute pancreatitis is likely to result in an increased incidence of abdominal compartment syndrome. Abdominal compartment syndrome may be confused with other metabolic syndromes that are found in severe acute pancreatitis, including systemic inflammatory response syndrome and multiple organ dysfunction syndrome [30]. CT findings of increasing peritoneal or retroperitoneal fluid collections (Fig. 7A, 7B, 7C) and bowel wall enhancement should raise concern for abdominal compartment syndrome.

Treatment of Abdominal Compartment Syndrome

Top Abstract Introduction Pathogenesis of Abdominal... Clinical Diagnosis Radiologic Findings Acute Compartment Syndrome in... Treatment of Abdominal... Conclusions References

 
The mortality rate associated with abdominal compartment syndrome is significant, ranging between 60% and 70% [3, 4, 16]. The poor outcome relates not only to abdominal compartment syndrome itself but also to concomitant injury and hemorrhagic shock. Treatment of the shock with large-volume resuscitation may worsen abdominal compartment syndrome by causing reperfusion bowel edema [3].

The currently accepted treatment for abdominal compartment syndrome is decompressive laparotomy. However, decompressive laparotomy does not prevent death in abdominal compartment syndrome. A metaanalysis of 250 patients who had decompressive laparotomy for abdominal compartment syndrome found a mortality rate of 49% [31]. Other methods of reducing intraabdominal pressure include drainage of fluid collections and muscle relaxation [32].

Many techniques have been described for temporarily covering the abdomen after decompression laparotomy using mesh, opened sterile saline bags, plastic, or silicone. Others have used skin clips to achieve skin closure while leaving the muscle and fascial layer open [4]. The complications of leaving the abdomen open include delayed bowel fistula and ventral hernia, which occur in up to two thirds of patients treated with an open abdomen. A less common but more serious complication is a potentially lethal reperfusion syndrome with persistent hemorrhage [33]. Nevertheless, most surgeons would prefer to leave the abdomen open in those who are at high risk of abdominal compartment syndrome.

Conclusions

Top Abstract Introduction Pathogenesis of Abdominal... Clinical Diagnosis Radiologic Findings Acute Compartment Syndrome in... Treatment of Abdominal... Conclusions References

 
General and trauma surgeons and intensivists are aware of abdominal compartment syndrome and observe for clinical signs of this condition. Radiologic input into the diagnosis of this entity has been minimal in the past. Individual CT signs such as elevated hemidiaphragm, flattened inferior vena cava and renal veins, and increased bowel wall enhancement are neither sensitive nor likely specific for abdominal compartment syndrome. However, when a combination of these findings is present in the appropriate clinical setting or if the signs are seen to worsen on sequential imaging studies, the radiologist should raise the possibility of abdominal compartment syndrome.

References

Top Abstract Introduction Pathogenesis of Abdominal... Clinical Diagnosis Radiologic Findings Acute Compartment Syndrome in... Treatment of Abdominal... Conclusions References

 

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