Primary lower limb lymphoedema: classification with non-contrast MR lymphography.

PURPOSE: The purpose of the present study was to analyse the performance of non-contrast MR lymphography for the classification of primary lower limb lymphoedema in 121 consecutive patients with 187 primary lower limb lymphoedemas. MATERIALS AND METHODS: 121 consecutive patients with clinically diagnosed primary lower limb lymphoedema underwent non-contrast MR lymphography with a free-breathing 3D fast spin-echo sequence with a very long TR/TE (4000/884 ms). MR examinations were retrospectively reviewed for severity of lymphoedema (absent, mild, moderate, severe) and characteristics of inguinal lymph nodes and iliac and inguinal lymphatic trunks graded as aplasic (no lymph nodes or lymphatic trunks), hypoplasic (less lymph nodes or lymphatic trunks), normal and hyperplasic (more lymph nodes or more and/or dilated trunks). RESULTS: There was an excellent correlation between clinical stage and severity of lymphoedema (Cramer's V of 0,73 (p < 0.001)). Differentiation was feasible between inguinal lymphatic vessel aplasia (21%), hypoplasia (15%), normal pattern (53%) and hyperplasia (11%). Severe lymphoedema was observed in 46% of aplasic patterns and in 37% of hyperplasic patterns, but in only 15% of hypoplasic patterns and never observed in normal patterns (p < 0.001). CONCLUSION: Non-contrast MR lymphography is able to classify primary lower limb lymphoedemas into hyperplasic, aplasic, hypoplasic and normal patterns. KEY POINTS: • Non-contrast MR lymphography is able to classify primary lower limb lymphoedemas. • Lymphoedema can be classified in hyperplasic, aplasic, hypoplasic and normal patterns. • Non-contrast MR lymphography can optimize clinical management of primary lower limb lymphoedemas.

Preoperative portal vein embolization with a combination of trisacryl microspheres, gelfoam and coils.

PURPOSE: To evaluate the safety and efficiency of preoperative portal vein embolization (PVE) with a combination of trisacryl microspheres, gelfoam and coils for inducing lobar hypertrophy in hepatobiliary malignancy patients. MATERIALS AND METHODS: PVE was performed by a percutaneous left approach in 63 patients with hepatic malignancy (hepatocarcinoma=38, colorectal metastasis=14, cholangiocarcinoma=11). The indication of PVE and surgery was evaluated by hepatic tumor board take into consideration to the tumor extension and the hepatic volume on initial and post-embolization CT-scans. The total functional liver volume (TELV) and future liver remnant (FLR) volume were measured before and 24±5days after PVE to assess FLR, TELV and FLR/TELV ratios. Efficiency evaluation was based on FLR increase, the ability to perform the hepatectomy and the hepatic function after surgery. Safety evaluation was determined by clinical and biological follow-up after embolization and surgery. RESULTS: PVE was successful in all the patients. The mean FLR volume increases by 57±56% after embolization (449±180cm(3) to 663±254cm(3)) (P<0.0001). The FLR/TELV ratio increases by 11% after PVE (25±8% to 36±12%). Three minors' complications were registered without impact on surgery, and four patients developed portal hypertension. Forty-nine patients underwent hepatectomy; none of them developed liver failure. Surgery was not performed in 14 patients due to tumor progression (n=9), inadequate hypertrophy of FLR (n=1) and portal hypertension (n=4). CONCLUSION: Preoperative PVE with a combination of trisacryl microspheres, gelfoam and coils is a safe and effective method for inducing contralateral hypertrophy before right hepatectomy in patients with advanced hepatobiliary malignancy.

Hepatocellular carcinoma vascularization: from the most common to the lesser known arteries.

Hepatocellular carcinoma is the sixth most common cancer throughout the world. It is almost exclusively arterially vascularized, unlike the vascularization of the liver, which has a dual supply with a portal component of 75 to 80% and an arterial component of 20 to 25%. The reference treatment for intermediary stages of the Barcelona (B) classification is hepatic artery chemoembolization. The aim of chemoembolization is to inject the tumor chemotherapy into the artery and then to embolize the artery (or arteries), which supply the tumor. For this, knowledge of the anatomy of the hepatic artery is essential. Approximately 55% of the patients belong to the modal distribution, although numerous anatomical variants exist and must be recognized. In addition, primarily non-hepatic arteries may contribute to the vascularization of some hepatocellular carcinomas. Furthermore, new arterial supplies can be recruited by tumors after surgical or chemoembolization treatments. The aim of this article is to describe the different arteries, which may vascularize hepatocellular carcinomas. These arteries must be looked for, recognized, and reported by the radiologist on cross-section examinations in the pre-treatment assessment.

MRI of cholangitis: traps and tips.

There are many limitations to the examination of the bile ducts by magnetic resonance imaging, which may be four orders: (1) technical, requiring analysis of Maximum Intensity Projection (MIP) three-dimensional (3D) volume reconstructions as well as native images, the use of T1-weighted sequences obtained in 3D to avoid entry slice phenomena, and knowledge of the inherent limits of the method, the spatial resolution of which is still less than optimal; (2) anatomical: you need to know the appearance of flow artefacts within the bile ducts and the traps that the presence of air or bleeding into the bile ducts can create; you also need to know the characteristic appearance of the indentation caused by the hepatic artery on the bile ducts and the variants and modifications seen in cases of portal biliopathy; (3) semiological: the terms used to describe bile duct abnormalities seen in MRI are often derived from imprecise descriptions used in retrograde cholangiography: irregularities of the bile ducts, a beaded 'string of pearls' appearance, a 'dead tree' appearance; (4) related to a complex disease, cholangitis which is a complex pathological condition, with possible overlaps between different conditions, such as primary sclerosing cholangitis (PSC), secondary sclerosing cholangitis, autoimmune cholangitis. In any case, the diagnosis of cholangiocarcinoma associated with PSC is always difficult. These limitations can be circumvented by using a precise exploration technique comprised of 3D magnetic resonance cholangiography sequences, which allow volume analysis, examination of native slices and of thick or thin MIP reconstructions, and heavily T2-weighted and T1-weighted 3D sequences with and without gadolinium injection, which is not always essential. The examination must be interpreted according to a stereotyped plan that includes (1) examination of the bile ducts, searching for and describing any stenosis, the presence or absence of dilatation, (2) a systematic search for any intrahepatic calculus, (3) examination of the heterogeneity of the liver parenchyma, investigation to find any liver dysmorphia and signs of portal hypertension, (4) analysis of the enhancement of the liver parenchyma and any enhancement of the wall of the bile ducts.

[Chest magnetic resonance lymphography]. / Lymphographie par résonance magnétique thoracique.

Lymphangio-MRI is a non-invasive technique that allows the precise imaging of thoracic lymphatic vessels without contrast-enhancing agents. This technique is still in progress, and will benefit from better knowledge of thoracic lymphatic diseases and further improvement of MRI spatial resolution.

[Imaging in oncology: terms and definitions]. / Onkologische Bildgebung: Begriffe und Definitionen.

Oncologic imaging includes the morphological description of the primary tumor region for an accurate classification of the tumor and lymph node stage and whether distant metastases have occurred according to the TNM staging system. Knowing the stage of the disease helps to plan the treatment and to estimate the prognosis. In clinical routine this is accomplished by conventional imaging techniques, such as ultrasound (US), computed tomography (CT) and magnetic resonance imaging (MRI). Additionally, oncologic imaging is essential in treatment monitoring to visualize and quantify the effect of cancer therapy according to response evaluation criteria in solid tumors (RECIST) and World Health Organization (WHO) criteria. The tremendous development in oncology and technical innovations in imaging represent a particular challenge for radiology.

Diagnosis and radiological treatment of digestive haemorrhage following supramesocolic surgery.

Digestive haemorrhage following supramesocolic abdominal surgery (cephalic duodenopancreatectomy, cholecystectomy, total oesogastrectomy) is a rare but serious complication, which can be life-threatening. Improvement in scanning techniques has made it possible to modify the diagnostic strategy and improve the therapeutic management of the patients. The aim of this iconographic review is to recall the causes of digestive haemorrhage following supramesocolic surgery and to illustrate the dominant role of tomodensitometry in diagnosing it and in planning and controlling the efficacy of endovascular treatment.

MR Imaging of sclerosing cholangitis.

MRCP is a non-invasive cholangiographic technique used in detection and characterization of bile ducts abnormalities. MRCP features of primary sclerosing cholangitis are randomly distributed annular strictures alternating with slightly dilated bile ducts. Secondary sclerosing processes including ascending, ischemic, caustic, AIDS-related, eosinophilic and autoimmune cholangitis can mimic PSC at MRCP.