Abstract
Clinical manifestations of liver transplantation complications can be subtle and non-specific. Medical imaging, mainly Doppler ultrasound, plays an important role to detect and grade these. Colour Doppler ultrasound exams are routinely performed at 24–48 h, on the 7th day, the first and third month after transplantation. MDCT and MR images are acquired based on the Doppler ultrasound (DUS) findings, even in the absence of abnormal liver function. As vascular complications appear early after surgery, DUS should be performed by experience personnel. Diagnostic angiography is seldom performed. This pictorial review illustrates the key imaging findings of vascular complications in patients with liver transplantation: hepatic artery complications (such as thrombosis, stenosis of the anastomosis and pseudoaneurysms), portal vein abnormalities (such as occlusion and stenosis) and hepatic veins and/or inferior vena cava flow changes (Budd-Chiari syndrome).
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Highlight the importance of early detection of vascular complications after liver transplantation
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Describe key colour Doppler ultrasound findings as the initial imaging test.
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Review the CT and MR imaging findings of the arterial and venous complications.
Introduction
Currently, liver transplantation is the first-line treatment for patients with terminal liver disease, both acute and chronic.
In recent years, living donor liver transplant has been introduced, especially in children. It reduces the waiting period for a deceased donor transplant and also the ischemic period of the transplanted organ [1]. In this paper, we will focus on cadaveric liver transplantation.
Vascular complications after transplantation are infrequent. Their reported incidence is close to 7% for cadaveric donor liver transplantation and around 13% for living donor liver transplantation [2]. Unfortunately, vascular abnormalities may appear early after surgery, with an associated high incidence of graft loss and mortality [3]. As the clinical manifestations related to vascular injuries are non-specific, early radiological examination plays a major role to make an early diagnosis and establish the best treatment options. Early endovascular treatment is correlated with liver transplantation salvage [4], making early imaging studies especially important.
Colour Doppler ultrasound (CDUS) is the most appropriate imaging test, allowing the early evaluation of the patient, even within the recovery unit after surgery, and also precisely assessing the graft vessels patency [5]. When CDUS shows a vascular abnormality, the surgical anatomy is difficult to interpret or the patient’s clinical status is deteriorating, there is a need to complement the study with either contrast-enhanced CT or MR imaging [6, 7].
Traditionally, surgery has been the first-line treatment of complications, although, nowadays, endovascular treatments have been positioned as first options, limiting surgery to those cases where interventional radiology is limited or failed [8]. Abdominal radiologists should, therefore, foster interventional management when evaluating these patients.
Regarding vascular imaging evaluation, the following protocol is used in our institution, where more than 100 cadaveric liver transplants are performed every year:
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Postoperative CDUS at 24/48 h and day 7 after surgery (Fig. 1). These exams should always be performed [9]. Most patients also have a CDUS at the first and third months.
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Contrast-enhanced CT images are obtained when a vascular lesion is observed on CDUS images or when the liver function is impaired. Occasionally, MR is performed if contraindications to contrast-enhanced CT are present.
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T-tube cholangiography images with direct opacification are also performed on day 4 and the third month to assess the biliary tree.
In recent years, hepatic intra-operative ultrasonography has emerged as a new technique. It allows real-time evaluation of the anastomosis and so immediate treatment before abdominal closure [10].
Usual posttransplantation findings include right-sided pleural effusion, ascites, perihepatic hematoma and periportal oedema. All of them should resolve in the first weeks after surgery [11].
Vascular and biliary anastomoses should be assessed by CDUS. Radiologists should have a clear knowledge of the individual patient postoperative anatomy, since anastomoses are the locations where complications occur most frequently. Moreover, it is important to be aware of the anatomic variants, both in the donor and in the recipient [12].
Currently, the most common surgical technique is orthotopic liver transplantation, where the graft is placed in the right upper quadrant, at the anatomical liver location, after removal of the native liver [13]. Four anastomoses should be carefully assessed: portal vein, bile duct, anastomosis of the recipient inferior vena cava to the donor hepatic veins and anastomosis of the hepatic artery.
The most frequently affected anastomosis is at the hepatic artery [14]. This anastomosis can be made in different places, but the two most frequent are in the hairpin between the right and left hepatic arteries of the recipient or at the outlet of the gastroduodenal artery [15].
Hepatic artery complications
Related to their onset, hepatic artery complications can be defined as early (within the first month) or late (later than 1 month) complications. Early complications are the most important for patient prognosis because they are associated with graft loss and a high mortality rate.
Thrombosis (Figs. 2 and 3)
Artery thrombosis is the most serious complication of orthotopic liver transplantation, occurring approximately in 4 to 12% of cases [16]. Thrombosis represents more than 50% of all arterial complications, being the first cause of non-functional liver transplant. Usually, an early complication, it can occur even up to 4 months after transplantation.
Pulsed and power CDUS has a high sensitivity and specificity to detect the thrombus and grade the degree of stenosis and flow properties, not only at the hepatic artery but also at the intrahepatic branches. Parameters to be considered are hepatic artery diameter, hepatic artery peak systolic velocity and hepatic artery resistance index. Intraoperative ultrasound examination has high sensitivity and specificity for early detection of these findings [17]. Proper quantification of flow velocity within the stenosis by CDUS requires the use of a suitable angle. If the transducer is placed at a parallel or perpendicular angle to the artery whose speed is to be measured, quantified speeds would be lower than actual. Because of the impaired anatomy and generally poor sonographic window, it is usually difficult to find the correct angle. However, resistance index and spectral curve morphology are not affected by angle, being easier to study.
When the blood flow is not identified by CDUS, some different conditions should be considered such as slow flow secondary to vasospasm or low cardiac output. Also, many of these patients have a poor sonographic window due to the surgical dressing materials. Use of a contrast agent (contrast-enhanced US, CEUS) will improve the US diagnostic performance in these cases with a near perfect accuracy [18].
CT angiography is the best technique to further evaluate difficult cases due to its high accuracy, short examination time and facility to be performed with poor patient condition [19]. MRI has proven to have a diagnostic accuracy similar to ultrasound [20], while CT angiography is equivalent [21] or even better [6].
If thrombosis is suspected, a diagnostic arteriography will confirm the diagnosis and allow the best treatment decision. Some endovascular treatments are available to these patients, such as intraarterial thrombolysis (IAT), percutaneous transluminal angioplasty (PTA) and stent placement [8]. If treatment fails, retransplantation should be considered as soon as possible. Studies have shown retransplantation has a better survival rate than endovascular treatment [3]. Nevertheless, because of its less invasive nature, endovascular treatments should be performed as first-line treatment.
Stenosis (Figs. 4, 5, and 6)
The most frequently affected location is the anastomosis (2 to 13% of patients) [22]. Therefore, this region should me carefully evaluated.
Stenosis may progress to thrombosis. So, stenosis and thrombosis are two entities of the same spectrum of vascular complications of liver transplantation.
Stenosis can lead to splenic steal artery syndrome [23].
It usually occurs in the first 3 months (median time to diagnosis 90 to 120 days) [24] [25], but this time shows differences between patients, describing cases that happen even several years after surgery.
Doppler ultrasound is the most useful technique to show this complication, as explained for thrombosis.
It shows a characteristic pattern, depending on the segment studied and its relationship with stenosis. Power Doppler is also useful to quantify blood flow and study spectral curves [26].
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Prestenotic segment shows elevation of resistance index (more than 0.8) and low flow.
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Stenotic segment displays a very high flow rate and aliasing artefact, due to the turbulent flow. Blood systolic peak is more than 200 cm/s.
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Poststenotic segment presents a low resistance index (less than 0.5) and a parvus et tardus morphology of the spectral curves with long systolic acceleration time (more than 0.08 s). It has also a turbulent flow.
An important consideration
It is important to remember that, in the first 3 days after liver transplantation, an increased resistance index of the hepatic artery (greater than 0.8) is found in approximately 50% of the patients [27].
If found, it should be monitored until it has normalised, typically in the fourth day after the transplantation [28].
Although the severity of the described findings correlates with the degree of the stenosis, ultrasound does not allow proper quantification of this: the technique of choice is CT angiography [29]. In addition, CT allows proper evaluation of patients with a poor sonographic window. Multiplanar and three-dimensional curved reformatting are useful to measure the vessel lumen.
MRI angiography is a limited technique because of a relatively high false-positive rate [20].
Hepatic artery stenosis requires early treatment. First, an angiography and an angioplasty should be made. If this procedure fails, surgery is required. Once again, retransplantation has a better outcome, but is preferred as a second-line treatment, to use when endovascular therapy does not work [3].
False aneurysm or pseudoaneurysm (Figs. 7 and 8)
Pseudoaneurysm of the hepatic artery and its branches presents the same features as in other parts of the body, differently to other vascular complications of liver transplantation. In this case, it can affect any of the branches, not only the site of the anastomosis.
It is a rare complication, with an incidence of 2.5% of the cases of liver transplantation, according to the retrospective study having the largest sample. It has no bias for any of the indications of liver transplantation [30].
In ultrasound, pseudoaneurysms present as a hypoechoic structure with turbulent blood flow within as observed by colour Doppler. Typically, due to swirl formed by the inlet and blood outlet, it is possible to observe the yin-yang sign [31].
If CT angiography is performed, it characteristically presents an arterial enhancement equal to the other arterial vessels, with an equal wash out in the later stages.
They are classified according to their location: extrahepatic and intrahepatic.
Extrahepatic pseudoaneurysms
The most common site is the arterial anastomosis. They can occur spontaneously or as a complication of treatment of a preexisting stenosis. Bacterial or fungal infection isolated from the peritoneal fluid or from the pseudoaneurysm wall can be present in up to 81% of cases, according to series [30].
Intrahepatic pseudoaneurysms
Characteristically, it is a complication of percutaneous liver biopsy, the usual cause, but also may be secondary to bile duct infections [5]. In case of rupture of such aneurysms, a portal or biliary fistula can appear. Pseudoaneurysms and fistulas secondary to percutaneous liver biopsies are much more frequent if the biopsy is done in the first days or weeks after transplantation. In fact, according to some reports, the risk of developing an arterioportal fistula is approximately 50% for biopsies performed in the first week, dropping to 10% if performed approximately 1 month after surgery [29].
In both cases, treatment consists of coil embolisation and stent placement to prevent inflow to the pseudoaneurysm. If the results of this treatment are not satisfactory, surgical resection can be performed [32].
Ischaemia/liver infarction
Hepatic infarction is very rare in normal patients, since the liver is a richly vascularised organ with blood from different circuits: the hepatic artery and the portal vein. Inside the liver, there are numerous anastomotic vessels and collateral branches.
However, in liver recipient patients, anastomoses are stopped, so hepatic infarction is much more common. It is usually associated with arterial occlusion (85% of cases), and, rarely with portal vein occlusion [29]. Bile ducts are especially sensitive to arterial blood flow impairment because they receive all their blood supply from the hepatic artery [33].
Ischaemia and liver infarction can be consequences of all three described alterations of the hepatic artery: thrombosis, stenosis and pseudoaneurysm.
Complications of the portal vein
Portal vein complications are infrequent. They affect less than 2% of liver transplantations [34].
The most common surgical technique is to directly anastomose the portal vein of the donor with that of the recipient.
However, sometimes this is not possible, because there is a portal thrombus which prevents direct anastomosis. In such cases, it is necessary to remove the segment occupied by the thrombus and perform a bypass. Typically, the donor iliac vein is used to make the bypass [35].
Complications of the portal vein usually affect the anastomosis, so it is important to know its location.
The most common complications of the portal vein will be explained.
Thrombosis (Fig. 9)
It is a rare complication. It occurs most often in the extrahepatic portal vein, at the site of the anastomosis. It can be proved by the absence of Doppler flow on ultrasound examination or a filling defect in the contrast-enhanced CT scan or MRI.
Some studies show that contrast-enhanced ultrasound is a promising technique being able to identify cases of thrombosis missed by other imaging techniques [36].
If thrombosis is seen in the first 72 h after surgery, surgical revision of the anastomosis should be made. Later, the treatment is done with percutaneous thrombolysis, angioplasty, stenting or, if unable to perform the treatment with these less invasive techniques, surgery.
Stenosis (Figs. 10 and 11)
The site most frequently involved is the anastomosis. The characteristic findings in each imaging technique are as follows:
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Doppler ultrasound, there is typically an increase in portal blood flow velocity at the point of the anastomosis (greater than 125 cm/s) or three times higher at the site of the stenosis in comparison with the prestenotic segment [37]. As explained for arterial velocity, Doppler measurements require using a correct angle, which is not always possible to obtain because of patient conditions. Consequently, the stenotic/prestenotic ratio is a more accurate measurement.
An aliasing artefact can also appear in the stenotic segment because of turbulent flow. This can be also a normal finding in the early postoperative period. So, in the case of turbulent flow, anastomosis should be evaluated in future controls, for comparison [5].
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CT or MR angiography can observe and quantify the degree of stenosis.
Stenosis should be carefully differentiated from a physiological mild reduction in vessel calibre at the anastomotic site. This finding in more appreciable if there is a size discrepancy between the donor and recipient portal veins. In this case, the focal narrowing is a normal finding and it is not related to stenosis. Knowledge of preoperative anatomy and assessment of the graft will help to make the differential diagnosis. Nevertheless, this finding should be followed-up, because it predisposes to the development of a stenosis [35]. Treatments are angioplasty, stenting and, in case of failure of the prior techniques, surgical resection.
Ischaemia/liver infarction
Although much more common in the case of arterial complications, it may also occur as a result of stenosis or portal vein thrombosis.
Complications of the inferior vena cava
Inferior vena cava complications are in frequent. They affect less than 2% of liver transplantations [34]. Coronal reconstructions are especially useful in measuring the extension of the thrombus.
Thrombosis (Fig. 12)
Usually, they occur because of the surgical technique or a hypercoagulable state. Diagnosis and treatment are similar to that of portal vein thrombosis.
Stenosis (Fig. 13)
Just as in the other vessels, the most common site is the anastomosis. It is also possible that extrinsic compression stenosis occurs, secondary to oedema of the graft or fluid collections, hematomas or abscesses. The diagnostic and therapeutic techniques are similar to those described in the portal vein.
Complications of hepatic veins (Fig. 14)
These are rare complications. As in the rest of the vessels, characteristic complications are thrombosis (Budd-Chiari syndrome) and stenosis.
In the case of living donor transplantation, knowledge of the surgical anatomy is very important. Usually, the right hepatic vein is preserved in the right lobe of the graft, but the middle hepatic vein is usually left for the safety of the donor. Sometimes, the middle hepatic vein is also included in the graft, and therefore, it should be assessed in the postoperative control [38].
Conclusion
Early detection of vascular complications of liver transplantation is essential in establishing effective treatment: this determines the effectiveness of transplantation and patient mortality and morbidity.
Doppler ultrasound is the initial imaging test. If it does not allow definitive diagnosis, other techniques (contrast-enhanced ultrasound, CT, MRI) are indicated.
Availability of data and materials
Data sharing is not applicable to this article as no datasets were generated or analysed during the current study.
References
Monti L, Soglia G, Tomà P (2016) Imaging in pediatric liver transplantation. Radiol Med 121:378–390 https://doi.org/10.1007/s11547-016-0628-3
Khalaf H (2010) Vascular complications after deceased and living donor liver transplantation: a single-center experience. Transplant Proc 42:865–870. https://doi.org/10.1016/j.transproceed.2010.02.037
Duffy JP, Hong JC, Farmer DG, et al (2009) Vascular complications of orthotopic liver transplantation: experience in more than 4,200 patients. J Am Coll Surg 208:896–903; discussion 903-905. https://doi.org/10.1016/j.jamcollsurg.2008.12.032
Singhal A, Stokes K, Sebastian A, Wright HI, Kohli V (2010) Endovascular treatment of hepatic artery thrombosis following liver transplantation. Transpl Int 23:245–256 https://doi.org/10.1111/j.1432-2277.2009.01037.x
Crossin JD, Muradali D, Wilson SR (2003) US of liver transplants: normal and abnormal. Radiographics 23:1093–1114. https://doi.org/10.1148/rg.235035031
Katyal S, Oliver JH 3rd, Buck DG, Federle MP (2000) Detection of vascular complications after liver transplantation. Am J Roentgenol 175:1735–1739. https://doi.org/10.2214/ajr.175.6.1751735
Boraschi P, Della Pina MC, Donati F (2016) Graft complications following orthotopic liver transplantation: role of non-invasive cross-sectional imaging techniques. Eur J Radiol 85:1271–1283. https://doi.org/10.1016/j.ejrad.2016.04.008
Chen J, Weinstein J, Black S, Spain J, Brady PS, Dowell JD (2014) Surgical and endovascular treatment of hepatic arterial complications following liver transplant. Clin Transplant 28:1305–1312. https://doi.org/10.1111/ctr.12431
Pareja E, Cortes M, Navarro R, Sanjuan F, López R, Mir J (2010) Vascular complications after orthotopic liver transplantation: hepatic artery thrombosis. Transplant Proc 42:2970–2972. https://doi.org/10.1016/j.transproceed.2010.07.063
Stanescu AL, Kamps SE, Dick AAS, Parisi MT, Phillips GS (2018) Intraoperative Doppler sonogram in pediatric liver transplants: a pictorial review of intraoperative and early postoperative complications. Pediatr Radiol 48:401–410. https://doi.org/10.1007/s00247-017-4053-0
Ito K, Siegelman ES, Stolpen AH, Mitchell DG (2000) MR imaging of complications after liver transplantation. Am J Roentgenol 175:1145–1149. https://doi.org/10.2214/ajr.175.4.1751145
Girometti R, Pancot M, Como G, Zuiani C (2017) Imaging of liver transplantation. Eur J Radiol 93:295–307. https://doi.org/10.1016/j.ejrad.2017.05.014
Lladó L, Figueras J (2004) Techniques of orthotopic liver transplantation. HPB (Oxford) 6:69–75. https://doi.org/10.1080/13651820310020756
Girometti R, Como G, Bazzocchi M, Zuiani C (2014) Post-operative imaging in liver transplantation: state-of-the-art and future perspectives. World J Gastroenterol 20:6180–6200. https://doi.org/10.3748/wjg.v20.i20.6180
Itri JN, Heller MT, Tublin ME (2013) Hepatic transplantation: postoperative complications. Abdom Imaging 38:1300–1333. https://doi.org/10.1007/s00261-013-0002-z
Wozney P, Zajko A, Bron K, Point S, Starzl T (1986) Vascular complications after liver transplantation: a 5-year experience. Am J Roentgenol 147:657–663. https://doi.org/10.2214/ajr.147.4.657
Gu LH, Fang H, Li FH et al (2012) Prediction of early hepatic artery thrombosis by intraoperative color Doppler ultrasound in pediatric segmental liver transplantation. Clin Transplant 26:571–576. https://doi.org/10.1111/j.1399-0012.2011.01580.x
Hom BK, Shrestha R, Palmer SL et al (2006) Prospective evaluation of vascular complications after liver transplantation: comparison of conventional and microbubble contrast-enhanced US. Radiology 241:267–274. https://doi.org/10.1148/radiol.2411050597
Kim SY, Kim KW, Kim MJ, Shin YM, Lee MG, Lee SG (2007) Multidetector row CT of various hepatic artery complications after living donor liver transplantation. Abdom Imaging 32:635–643. https://doi.org/10.1007/s00261-006-9145-5
Glockner JF, Forauer AR, Solomon H, Varma CR, Perman WH (2000) Three-dimensional gadolinium-enhanced MR angiography of vascular complications after liver transplantation. AJR Am J Roentgenol 174:1447–1453. https://doi.org/10.2214/ajr.174.5.1741447
Legmann P, Costes V, Tudoret L et al (1995) Hepatic artery thrombosis after liver transplantation: diagnosis with spiral CT. Am J Roentgenol 164:97–101. https://doi.org/10.2214/ajr.164.1.7998578
Piardi T, Lhuaire M, Bruno O et al (2016) Vascular complications following liver transplantation: a literature review of advances in 2015. World J Hepatol 8:36–57. https://doi.org/10.4254/wjh.v8.i1.36
Sanyal R, Shah SN (2009) Role of imaging in the management of splenic artery steal syndrome. J Ultrasound Med 28:471–477
Abbasoglu O, Levy MF, Vodapally MS et al (1997) Hepatic artery stenosis after liver transplantation--incidence, presentation, treatment, and long term outcome. Transplantation 63:250–255
Denys AL, Qanadli SD, Durand F et al (2002) Feasibility and effectiveness of using coronary stents in the treatment of hepatic artery stenoses after orthotopic liver transplantation: preliminary report. AJR Am J Roentgenol 178:1175–1179. https://doi.org/10.2214/ajr.178.5.1781175
Uzochukwu LN, Bluth EI, Smetherman DH et al (2005) Early postoperative hepatic sonography as a predictor of vascular and biliary complications in adult orthotopic liver transplant patients. AJR Am J Roentgenol 185:1558–1570. https://doi.org/10.2214/AJR.04.1258
García-Criado A, Gilabert R, Salmerón JM et al (2003) Significance of and contributing factors for a high resistive index on Doppler sonography of the hepatic artery immediately after surgery: prognostic implications for liver transplant recipients. AJR Am J Roentgenol 181:831–838. https://doi.org/10.2214/ajr.181.3.1810831
Caiado AH, Blasbalg R, Marcelino AS et al (2007) Complications of liver transplantation: multimodality imaging approach. Radiographics 27:1401–1417. https://doi.org/10.1148/rg.275065129
Quiroga S, Sebastià MC, Margarit C, Castells L, Boyé R, Alvarez-Castells A (2001) Complications of orthotopic liver transplantation: spectrum of findings with helical CT. Radiographics 21:1085–1102. https://doi.org/10.1148/radiographics.21.5.g01se061085
Volpin E, Pessaux P, Sauvanet A et al (2014) Preservation of the arterial vascularisation after hepatic artery pseudoaneurysm following orthotopic liver transplantation: long-term results. Ann Transplant 19:346–352. https://doi.org/10.12659/AOT.890473
Lupattelli T (2006) The yin-yang sign. Radiology 238:1070–1071. https://doi.org/10.1148/radiol.2383031884
Nagaraja R, Govindasamy M, Varma V et al (2013) Hepatic artery pseudoaneurysms: a single-center experience. Ann Vasc Surg 27:743–749. https://doi.org/10.1016/j.avsg.2012.08.018
Orons PD, Sheng R, Zajko AB (1995) Hepatic artery stenosis in liver transplant recipients: prevalence and cholangiographic appearance of associated biliary complications. AJR Am J Roentgenol 165:1145–1149. https://doi.org/10.2214/ajr.165.5.7572493
Pérez-Saborido B, Pacheco-Sánchez D, Barrera-Rebollo A et al (2011) Incidence, management, and results of vascular complications after liver transplantation. Transplant Proc 43:749–750. https://doi.org/10.1016/j.transproceed.2011.01.104
Singh AK, Nachiappan AC, Verma HA et al (2010) Postoperative imaging in liver transplantation: what radiologists should know. Radiographics 30:339–351. https://doi.org/10.1148/rg.302095124
Rennert J, Dornia C, Georgieva M et al (2012) Identification of early complications following liver transplantation using contrast enhanced ultrasound (CEUS). First results. J Gastrointestin Liver Dis 21:407–412
Chong WK, Beland JC, Weeks SM (2007) Sonographic evaluation of venous obstruction in liver transplants. AJR Am J Roentgenol 188:W515–W521. https://doi.org/10.2214/AJR.06.1262
Yu PF, Wu J, Zheng SS (2007) Management of the middle hepatic vein and its tributaries in right lobe living donor liver transplantation. Hepatobiliary Pancreat Dis Int 6:358–363
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Acknowledgements to the Abdominal Imaging Section of Hospital La Fe and to the Hepatobiliary Multidisciplinary Group.
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JJDM and CBV collected the cases, revised the clinical histories and selected the images. JJDM wrote the paper. CBV and LMB revised the paper and the images. All authors read and approved the final manuscript.
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Luis Marti-Bonmati is the Editor-in-Chief of Insights into Imaging. All the other authors declare that they have no competing interests.
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Delgado-Moraleda, JJ., Ballester-Vallés, C. & Marti-Bonmati, L. Role of imaging in the evaluation of vascular complications after liver transplantation. Insights Imaging 10, 78 (2019). https://doi.org/10.1186/s13244-019-0759-x
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DOI: https://doi.org/10.1186/s13244-019-0759-x