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Imaging and Intervention in the Hepatic Veins

¹ All authors: Department of Radiology, Stanford University School of Medicine, Mail Code 5621, 300 Pasteur Dr., Stanford, CA 94305.

Received September 9, 2002; accepted after revision November 6, 2002.

 
Address correspondence to T. S. Desser.

Introduction

Top Introduction Normal Hepatic Veins Abnormal Flow Patterns Venous Obstruction Hepatic Venous Injuries Conclusion References

 
Compared with the portal veins, the hepatic veins have received less attention in the radiology literature. Therefore, radiologists may not be as familiar with hepatic vein abnormalities. As the population of patients who are imaged for liver disease in our institution continues to grow, we are encountering hepatic vein disorders more frequently in a variety of clinical settings. In this article, we review the cross-sectional imaging features of normal hepatic veins and describe a number of abnormal processes that may alter their appearance. Because sonography is widely used to screen for vascular abnormalities of the liver, we emphasize this technique for imaging of the hepatic veins. Interventional techniques that have proven useful in the treatment of hepatic vein disorders are also presented.

Normal Hepatic Veins

Top Introduction Normal Hepatic Veins Abnormal Flow Patterns Venous Obstruction Hepatic Venous Injuries Conclusion References

 
Anatomy
Although the liver has a dual blood supply, the hepatic veins provide the sole route of egress for blood exiting the liver. The segmental anatomy of the liver as defined by the French surgeon Claude Couinaud [1] divides the liver into eight segments, with portal vein branches at the center and hepatic veins at the periphery. The right, middle, and left hepatic veins enter the retrohepatic inferior vena cava just before it traverses the diaphragm, approximately 2 cm caudad to the right atrium and eustachian valve. The right hepatic vein enters the inferior vena cava separately, but the middle hepatic vein and the left hepatic vein may share a common trunk in 65–85% of patients [2]. Besides the three major hepatic veins, additional small accessory or short hepatic veins from the pericaval liver segments drain directly into the inferior vena cava caudad to its junction with the major veins [3]. These accessory veins are usually associated with the right lobe or caudate lobe and may occasionally be up to 1 cm in diameter (Fig. 1). Common anatomic variants include an accessory inferior right hepatic vein that drains Couinaud segment VI and a middle right hepatic vein that drains segment V. In one study, these variants were seen in 18% and 5.5% of patients, respectively [2]. The inferior right hepatic vein may be identified running parallel and deep to the posterior division of the right portal vein [4] (Fig. 2). Both the major and accessory hepatic veins exit the liver in its bare area, where the veins are surrounded by loose areolar tissue before joining the inferior vena cava.

View larger version (101K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 1. —Normal hepatic venous anatomy. Drawing shows major hepatic veins and short hepatic vein orifices.

View larger version (95K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2. —41-year-old healthy male volunteer. Transverse sonogram shows inferior right hepatic vein (arrow) joining inferior vena cava posterior to right portal vein.

Anatomic variations in venous drainage are particularly important in surgical planning of right lobe living donor transplantation, an increasingly common procedure in the treatment of end-stage liver disease [5]. If the main right hepatic vein is small, portions of the right lobe may be drained by the middle hepatic vein or an inferior right hepatic vein, and viability of the graft will depend on preservation of this venous drainage. Some centers therefore routinely use intraoperative Doppler sonography for assessing venous drainage of the split liver graft.

Unlike the portal veins, whose walls are echogenic over a wide range of insonation angles, the walls of the hepatic vein are echogenic only with perpendicular beam incidence. This is due to differences in the orientation of connective tissue fibers in the vessel walls, which are parallel and tightly packed in the hepatic veins but only loosely arrayed in a variety of directions along the portal veins [6].

Physiology
The hepatic veins are central veins whose flow pattern reflects the pressure variations within the right atrium during the cardiac cycle (Fig. 3). Normally, free communication exists between the hepatic veins and the right atrium, and hepatic venous flow is triphasic. There is a low-velocity phase of retrograde flow during right atrial contraction (the a wave). Two higher velocity phases of hepatofugal flow follow, the first during right ventricular systole after closure of the tricuspid valve, and the second during right ventricular diastole. These represent periods of declining right atrial pressure. Between these two phases of forward flow, preceding the opening of the tricuspid valve, the atrial pressure rises briefly (the v wave). This rise in atrial pressure interrupts the two periods of forward flow and may produce a short second period of hepatic venous flow reversal, even in healthy patients. V wave flow reversal is almost always smaller than the a wave flow reversal [7, 8, 9].

View larger version (18K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 3. —Schematic representation shows temporal events of cardiac cycle (EKG) and their relationship to central venous pressure (CVP) tracing and hepatic venous (HV) velocity waveform. Opening and closing of tricuspid valve are indicated.

Systolic forward flow velocities depend on atrial relaxation, motion of the tricuspid annulus toward the cardiac apex, and static right atrial pressure. High right atrial pressures reduce the gradient between this chamber and the hepatic veins and thereby decrease the velocity and quantity (estimated with flow-velocity integrals) of systolic forward flow. Hepatic venous velocity waveforms can thus be used to estimate right atrial pressure [9].

Spectral Doppler sonography readily shows the normal triphasic hepatic venous waveform (Fig. 4). To minimize the effect of the adjacent inferior vena cava, one should place the Doppler sonography sample volume 3–6 cm from the vessel outlet. We ask patients to suspend respiration but not to deeply inhale or exhale because these maneuvers alter venous pressures and consequently the hepatic venous waveform [10]. Likewise, the Valsalva maneuver raises intrathoracic pressure and alters the hepatic venous waveform, often rendering it monophasic [7]. Because hepatic blood flow increases in the postprandial state, patients should be examined when fasting.

View larger version (41K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 4. —Duplex Doppler sonogram of normal triphasic hepatic venous tracing of 43-year-old woman.

Hepatic venous pulsatility may disappear during pregnancy and may remain abnormal even beyond 8 weeks postpartum [11]. Hepatic venous waveforms in pregnant patients may be dampened or monophasic even before 20 weeks' gestation, and most patients (80%) have flat waveforms in the final 10 weeks of pregnancy [12]. The precise cause of these changes in pregnancy is unknown, although the altered cardiac output seen in pregnancy coupled with the pressure effects of the enlarged uterus may play a role [11]. Therefore, caution should be exercised when diagnosing suspected hepatic venous abnormalities in pregnant patients.

Abnormal Flow Patterns

Top Introduction Normal Hepatic Veins Abnormal Flow Patterns Venous Obstruction Hepatic Venous Injuries Conclusion References

 
A variety of abnormal processes both intrinsic and extrinsic to the liver may alter flow patterns in the hepatic veins. Abnormal flow may occur in the hepatic veins if there is abnormal communication between the hepatic veins and other hepatic vessels, right heart pressures are elevated, transmission of the right atrial pressure pattern is impeded because of venous outflow obstruction, or infiltration and altered compliance of the hepatic parenchyma result in dampening of hepatic venous flow patterns. Examples of each of these abnormal flow patterns are discussed in the following sections.

Intrahepatic Vascular Shunts and Vascular Malformations
Although they may mimic complex cysts or tortuous vessels on gray-scale sonography, vascular malformations are readily identified with color and power Doppler sonography.

Shunts between the hepatic arteries and the hepatic veins are rare but may occur in cavernous lymphangiomatosis or in Rendu-Osler-Weber syndrome [13]. More commonly, arteriosystemic shunts occur in the setting of hepatocellular carcinoma with hepatic venous invasion [14]. They may also develop after liver biopsy or with penetrating trauma.

Color Doppler sonography may reveal dilated and tortuous hepatic arteries and aliasing at the junction with the draining hepatic vein. The hepatic veins may show abnormal color-flow patterns, and spectral tracings typically show arterialization. Although arterioportal shunts are the most typical vascular communications associated with hepatocellular carcinoma, identification of hepatic artery-to-hepatic vein shunt should also prompt a search for an underlying neoplasm.

Portosystemic venovenous shunts are more common and may also be congenital or acquired. Congenital shunts are rare (Fig. 5). They are thought to occur either by persistence of connections among tributaries of the vitelline vein (the precursor of the portal and hepatic veins and portions of the inferior vena cava [13]) or by rupture of a portal vein aneurysm into the hepatic vein [14]. By contrast, acquired shunts are common because they occur as sequelae of cirrhosis. These shunts provide collateral pathways for venous drainage of the liver in the setting of portal hypertension. Although the most commonly identified portosystemic shunts are extrahepatic, large intrahepatic portosystemic collaterals may be identified in the subcapsular area of the liver or may drain directly into the inferior vena cava [14]. Spectral tracings typically show turbulent waveforms with large shunts or high-velocity flow in smaller shunts.

View larger version (130K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 5. —84-year-old woman referred for evaluation of lower extremity edema. Contrast-enhanced portal venous phase CT scan shows portal vein–hepatic vein shunt. Hepatic vein tributary (white arrow) connects to left portal vein (arrowhead) via small vascular malformation (black arrow).

Hepatic venovenous shunts are most commonly identified in the setting of venous outflow obstruction and are discussed in the next section.

Right Heart Failure
When the volume of venous blood return exceeds the capacity of the right heart, central venous pressure rises, and the inferior vena cava and hepatic veins dilate [15]. Gray-scale sonography shows marked increase in the diameter of the inferior vena cava and the hepatic veins. Congestion in the hepatic sinusoids leads to compression, atrophy, and necrosis of centrilobular hepatocytes, first producing fatty infiltration and, when chronic, fibrosis (i.e., cirrhosis). The perisinusoidal fibrosis seen in cardiac cirrhosis results in decreased hepatic compliance, and hepatic venous waveforms may change from triphasic to monophasic. Forward flow velocities in the hepatic veins are typically slowed because of a lowered pressure gradient with the right atrium. Alternatively, if tricuspid regurgitation is present, hepatic venous pulsatility may increase, and hepatic venous flow during right ventricular systole may decrease or even reverse [15]. Hepatic venous flow patterns may also be abnormal in constrictive pericarditis [16]. Portal venous waveforms may be abnormal as well, changing from monophasic to pulsatile flow.

CT scans in patients with passive congestion may show reticulated or mottled enhancement of the hepatic parenchyma, the pattern typical of venous outflow obstruction described at greater length in the next section [15] (Fig. 6). The hepatic veins and the inferior vena cava may be distended, and there may be reflux of contrast material into the hepatic veins if tricuspid regurgitation is present.

View larger version (146K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 6. —42-year-old woman with suspected intraabdominal abscess. Contrast-enhanced portal venous phase CT scan shows reticular or mosaic perfusion of liver similar to pattern in Budd-Chiari syndrome. At autopsy, patient had severe ischemic cardiomyopathy and hepatic congestion.

Venous Obstruction

Top Introduction Normal Hepatic Veins Abnormal Flow Patterns Venous Obstruction Hepatic Venous Injuries Conclusion References

 
Obstruction of hepatic venous outflow results in the clinical phenomenon known as Budd-Chiari syndrome, consisting of congestive hepatomegaly, abdominal pain (from hepatic capsular distention), and ascites. Budd-Chiari syndrome is also a rare but important cause of portal hypertension. The original reports by Budd and Chiari described thrombosis of the major hepatic veins, in some cases also of the suprahepatic inferior vena cava [17]. Later reviews of patients with impairment of hepatic venous outflow included cases of both suprahepatic inferior vena cava obstruction and hepatic vein thrombosis, and the term Budd-Chiari syndrome came to be applied to both entities. Recently, however, one authority suggested that obstructions of both the inferior vena cava and the hepatic vein should be considered as separate entities [17]. Nevertheless, hepatic venous obstruction and congestion can be a reversible cause of inferior vena cava obstruction.

Thrombosis is by far the leading cause of obstruction of the major hepatic veins. In the intrahepatic inferior vena cava, obstruction may also be caused by a membrane or web. These webs were originally thought to be congenital in origin, but evidence now suggests that they are actually sequelae of thrombosis [17]. One authority now prefers the term "obliterative hepatocavopathy" rather than "membranous obstruction of the inferior vena cava." Symptomatic hepatic vein thrombosis is almost always due to an underlying myelopro-liferative disorder, hypercoagulable state, or other predisposing factors such as the use of oral contraceptives [18]. Hepatic vein thrombosis may also be due to infection, tumor invasion, or sequelae of trauma (Figs. 7 and 8). In contrast, obliterative hepatocavopathy is most often idiopathic but may be associated with increased risk of hepatocellular carcinoma.

View larger version (128K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 7. —74-year-old woman with liver abscess (not shown). CT scan shows thrombus (arrow) in right hepatic vein.

View larger version (124K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 8. —88-year-old man with hepatocellular carcinoma. CT scan shows tumor thrombus invading and expanding right hepatic vein (white arrow) and inferior vena cava (black arrow).

An increasingly important cause of hepatic venous outflow obstruction is venous anastomotic stricture in patients who have undergone liver transplantation. Newer liver transplantation techniques such as living related donor liver transplantation (split liver transplantation) and orthotopic liver transplantation with piggyback anastomosis may increase the risk of hepatic venous anastomotic stricture [19, 20]. Torsion of the right liver graft and hypertrophy of the graft with compression of the inferior vena cava are other reported causes of venous outflow obstruction in this patient population [21, 22].

Budd-Chiari syndrome can be diagnosed on color Doppler sonography when color flow is absent in the main hepatic veins [23, 24]. Duplex Doppler sonography can be used to confirm absence of flow when findings on color Doppler sonography are suggestive of venous occlusion. Color-flow Doppler sonography may also reveal intrahepatic venovenous collaterals that provide alternative pathways for venous return to the right heart when the inferior vena cava or the hepatic veins are obstructed [25, 26] (Figs. 9A, 9B). One common collateral pathway connects intrahepatic venous collaterals to systemic venous pathways via subcapsular veins and may be identified on the surface of the liver [25]. Alternatively, blood may be shunted away from an obstructed hepatic vein and toward a patent one, producing a pattern of bicolored hepatic veins (two adjoining hepatic veins with flow in opposite directions on color Doppler sonography). Venous obstruction elevates sinusoidal pressure, causing portal hypertension and conversion of the portal vein to an outflow tract.

View larger version (163K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 9A. —40-year-old woman with Budd-Chiari syndrome. Transverse color Doppler sonogram obtained at level of caudate lobe shows numerous intrahepatic collateral vessels (arrows).

View larger version (124K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 9B. —40-year-old woman with Budd-Chiari syndrome. CT scan obtained at same level as A shows characteristic appearance of Budd-Chiari syndrome, with increased central hepatic enhancement and decreased enhancement of liver periphery.

Gray-scale sonography in Budd-Chiari syndrome may show low-level echogenic material within the normally sonolucent lumen of the hepatic vein. However, even if the hepatic veins appear patent on gray-scale and color Doppler sonography, spectral tracings should be obtained. Absence of phasicity (monophasic flow) in the hepatic venous waveform may indicate the presence of a hepatic venous anastomotic stricture and a hemodynamically significant obstruction of venous outflow [19, 20]. Decrease in hepatic venous peak velocity to less than 10 cm/sec may also occur [20] (Figs. 10A,10B,10C,10D).

View larger version (58K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 10A. —60-year-old man with liver dysfunction after orthotopic liver transplantation 2 years earlier. Duplex sonogram of right hepatic vein shows low-velocity undulating monophasic waveform suggestive of venous outflow obstruction.

View larger version (114K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 10B. —60-year-old man with liver dysfunction after orthotopic liver transplantation 2 years earlier. Percutaneous transhepatic venogram shows near occlusion at anastomosis, with stasis of flow. Pressure gradient was 14 mm Hg.

View larger version (109K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 10C. —60-year-old man with liver dysfunction after orthotopic liver transplantation 2 years earlier. Venogram obtained from above piggyback anastomosis shows tapered occlusion.

View larger version (129K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 10D. —60-year-old man with liver dysfunction after orthotopic liver transplantation 2 years earlier. Final venogram obtained after stent placement shows rapid passage of contrast material from hepatic vein into inferior vena cava and right atrium.

Contrast-enhanced CT and MR imaging in Budd-Chiari syndrome may show non-visualization of the major hepatic veins and a mosaic heterogenous perfusion pattern diffusely involving the liver [27] (Fig. 11). Although the classic finding is preserved enhancement in the central pericaval portion of the liver because of preservation of venous drainage of the caudate lobe, in practice, enhancement patterns will depend on the relative degree of obstruction of the various draining veins [28]. When Budd-Chiari syndrome is caused by thrombosis of the major hepatic veins, compensatory hypertrophy of the caudate lobe will usually occur as a result of venous drainage directly into the inferior vena cava. The enlarged caudate lobe may cause compression of the inferior vena cava. Prominent collaterals, typically the ascending lumbar, azygos, and hemiazygos veins, may be seen in patients with Budd-Chiari syndrome because of obstruction of the intrahepatic inferior vena cava. Intrahepatic collaterals may also be identified (Figs. 12A, 12B). Enlargement of the normally small accessory hepatic veins may also occur.

View larger version (99K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 11. —45-year-old woman with ulcerative proctitis and Budd-Chiari syndrome. Contrast-enhanced CT scan shows heterogeneous hepatic enhancement, with relatively increased enhancement in pericaval region. Transjugular intrahepatic portosystemic shunt (arrow) was placed from stump of right hepatic vein to right portal vein for treatment of portal hypertension.

View larger version (106K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 12A. —20-year-old man with Budd-Chiari syndrome with portosystemic collaterals. Contrast-enhanced portal venous phase CT scan obtained at dome of liver shows thrombosed hepatic veins (arrows). Esophageal varices (arrowhead) are present.

View larger version (167K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 12B. —20-year-old man with Budd-Chiari syndrome with portosystemic collaterals. Portal venous phase CT scan obtained inferior to A shows pericaval intrahepatic collaterals (white arrow) and dilated paraumbilical vein (black arrow).

Regardless of the cause, prolonged obstruction of venous outflow leads to hepatic congestion with ensuing loss of hepatocytes. If elevated pressure continues, fibrosis will occur, with development of cirrhosis and hyperplastic nodules. Large hyperplastic nodules may be seen in patients with Budd-Chiari syndrome and should not be mistaken for hepatocellular carcinoma [29].

Budd-Chiari syndrome may be fulminant with rapidly progressive liver failure (uncommon) or acute or subacute, with abdominal pain, ascites, hepatomegaly, and renal failure developing over a week or two. Most common is the chronic form of Budd-Chiari syndrome, with ascites developing over 2 months or more. In subacute and chronic Budd-Chiari syndrome, complications of portal hypertension determine prognosis and are fatal in more than 50% of patients within 2 years [30]. Although Budd-Chiari syndrome leads to portal hypertension, it is the culprit in only a small minority of portal hypertension cases, approximately 2% in some recent series [30, 31].

Interventional radiologic techniques such as placement of transjugular intrahepatic portosystemic shunts have produced good outcomes in patients with Budd-Chiari syndrome complicated by portal hypertension [30]. If feasible, angioplasty and stenting of hepatic venous obstruction [32] or of segmental stenosis of the inferior vena cava [33] have proven useful, whereas thrombolysis has proven effective in treatment of acute thrombosis [31, 34]. Frequently, resolution of hepatic venous outflow obstruction allows spontaneous restoration of inferior vena cava flow and luminal diameter.

Venoocclusive Disease and Sinusoidal Obstruction Syndrome
Vascular obstruction may also occur in the liver at the microscopic level. Commonly termed "venoocclusive disease," microscopic obstruction is due to marked fibrosis in hepatic sinusoids produced by a toxic insult to endothelial cells and may not necessarily involve the hepatic venules [35]. Damaged endothelial cells swell, slough, and embolize distally, causing microvascular obstruction. Consequently, the term "sinusoidal obstruction syndrome" is now preferred by several authors [35]. Although the clinical picture of sinusoidal obstruction syndrome—hepatomegaly, ascites, and jaundice—may be indistinguishable from Budd-Chiari syndrome and macroscopic vascular obstruction, the cause of sinusoidal obstruction syndrome and its patient populations are different. First described in South African patients who had ingested herbal teas or foods containing pyrrolizidine alkaloids, sinusoidal obstruction syndrome in Western countries is almost always seen in association with chemotherapy conditioning regimens for bone marrow transplantation, particularly those containing cyclophosphamide or busulfan.

Sonographic and CT findings in sinusoidal obstruction syndrome may be similar to those of Budd-Chiari syndrome, with hepatomegaly and ascites. In sinusoidal obstruction syndrome, the venous flow may appear attenuated (Figs. 13A, 13B), but unlike Budd-Chiari syndrome, the major hepatic veins may appear patent. Sinusoidal fibrosis may lead to portal vein thrombosis or portal flow reversal evident on color Doppler sonography. Acutely, reversal of portal venous flow may represent the only pathway of venous drainage in these patients. Sonography is also useful to exclude other potential causes of hepatomegaly and jaundice in this patient population, such as biliary tract disease or infiltrative tumor.

View larger version (49K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 13A. —23-year-old woman with acute myelogenous leukemia and sinusoidal obstruction syndrome (hepatic venoocclusive disease) after bone marrow transplantation. Duplex Doppler sonogram shows low-velocity monophasic flow in middle hepatic vein.

View larger version (119K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 13B. —23-year-old woman with acute myelogenous leukemia and sinusoidal obstruction syndrome (hepatic venoocclusive disease) after bone marrow transplantation. Contrast-enhanced CT scan shows heterogeneous hepatic enhancement and low attenuation adjacent to patent right hepatic vein and inferior vena cava, presumably representing lymphedema.

Most patients with sinusoidal obstruction syndrome recover spontaneously with supportive treatment of fluid and respiratory status, but severe cases are commonly fatal. Interventional radiologists may be called on to perform wedged hepatic pressures or transvenous liver biopsy for diagnosis of this entity because this technique is safer than percutaneous biopsy in patients with thrombocytopenia. Tissue plasminogen activator and anticoagulation have been investigated but proved effective in less than one third of patients with sinusoidal obstruction syndrome and not useful at all in patients with associated renal or pulmonary failure. Placement of a transjugular intrahepatic portosystemic shunt may be useful for reduction of portal venous pressure and for reduction of ascites, but some authors suggest that these shunts have no effect on outcome in this entity [35].

Parenchymal Diseases
Dampening of the normal triphasic waveform may occur when diffuse liver disease alters the elasticity and vascular resistance of the liver. Cirrhosis may produce a pattern of pseudoportal flow—that is, monophasic turbulent flat flow in the hepatic veins [36, 37, 38, 39, 40].

In studies of patients with chronic hepatitis, abnormal hepatic venous waveforms were shown to correlate histologically with cirrhosis, fibrosis, and steatosis, although not with periportal inflammation or necrosis [38]. Alterations of hepatic venous flow in this population included loss of the brief period of flow reversal leading to a biphasic waveform or a completely flat (monophasic) waveform. Monophasic hepatic venous flow has never been seen in healthy control subjects [36, 37]. Abnormal hepatic venous waveforms correlate with the severity of cirrhosis, as measured by the Child-Pugh score [36, 37, 41].

Focal hepatic masses that compress adjacent hepatic veins may also cause flattening of the hepatic venous waveform. Even benign masses such as focal nodular hyperplasia may produce sufficient local mass effect to dampen the hepatic venous waveforms (Figs. 14A, 14B).

View larger version (103K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 14A. —34-year-old woman with focal nodular hyperplasia. Transverse sonogram shows isoechoic mass near confluence of right hepatic vein and inferior vena cava.

View larger version (65K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 14B. —34-year-old woman with focal nodular hyperplasia. Duplex Doppler sonogram shows low-velocity monophasic right hepatic venous waveform.

Hepatic Venous Injuries

Top Introduction Normal Hepatic Veins Abnormal Flow Patterns Venous Obstruction Hepatic Venous Injuries Conclusion References

 
Injuries of the retrohepatic inferior vena cava and the major hepatic veins after blunt trauma are associated with high mortality rates, ranging from 50% to 80% in some series. Death usually results from exsanguination during surgical attempts at control, exposure, and repair of hemorrhage from these largely inaccessible structures located within the bare area of the liver. In potentially lethal injuries—that is, those associated with free bleeding—there is disruption of surrounding tissues capable of tamponading the hemorrhage. Such surrounding structures include the liver parenchyma (for intrahepatic venous lacerations) and the retrohepatic areolar tissue, suspensory ligaments, and diaphragm (for extrahepatic venous injuries) [42].

High-grade liver lacerations may damage the major hepatic veins in the parenchyma or may avulse them at their extrahepatic portions. The most common major hepatic venous injuries involve the intraparenchymal segments and are produced by damage to the central posterior portion of the liver—the liver dome. Massive hemorrhage can occur when the surrounding containing structures—liver parenchyma and capsule, ligaments, and diaphragm—have been disrupted. Although these injuries can extend centrally to involve portal vein or hepatic artery branches, it is thought that hepatic veins are more prone to injury because they are less well supported by connective tissue. On CT and sonography, injury of the hepatic veins or the retrohepatic inferior vena cava should be suspected when a deep laceration involves the dome of the liver and blood is present in the bare area of the liver.

Treatment of major hepatic venous injuries has evolved from a strategy of attempted direct surgical repair to one of tamponading with packing, either with gauze or omentum [42]. Tamponading and containment strategies have reduced mortality substantially compared with surgical repair. Recently, however, interventional radiologic techniques have proven useful in cases of packing failures. Transvenous stenting of a retrohepatic inferior vena cava tear at its junction with the right hepatic vein in a patient with repeated intraoperative packing failures has been reported in the literature [43]. This technique may prove increasingly important in the years to come.

Conclusion

Top Introduction Normal Hepatic Veins Abnormal Flow Patterns Venous Obstruction Hepatic Venous Injuries Conclusion References

 
Obstruction of the hepatic veins may produce profound liver dysfunction. Alternatively, sonographic abnormalities of the hepatic veins may reflect underlying focal or diffuse hepatic disease. In patients who are not pregnant, loss of the normal triphasic waveform in the hepatic veins indicates an abnormality either in venous outflow or in hepatic compliance. Attention to the Doppler sonographic signature of the hepatic veins may provide critical evidence of underlying abnormality in the liver. Color Doppler sonography may reveal vascular occlusions or altered venous pathways that may be invisible on gray-scale sonography alone. Findings on CT may suggest the diagnosis of hepatic venous outflow obstruction if the hepatic veins are not visualized or perfusion is heterogeneous, and CT may show complications such as large hyperplastic nodules and collateral venous pathways. Interventional radiologic techniques, particularly the placement of hepatic venous or inferior vena cava stents or transjugular intrahepatic portosystemic shunts, may reduce morbidity in patients with venous outflow disorders stemming from hepatic congestion and ensuing portal hypertension.

References

Top Introduction Normal Hepatic Veins Abnormal Flow Patterns Venous Obstruction Hepatic Venous Injuries Conclusion References

 

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