PurposeResuscitative endovascular balloon occlusion of the aorta (REBOA) is a technique for temporary stabilization of patients with non-compressible torso hemorrhage. This technique has been increasingly used worldwide during the past decade. Despite the good outcomes of translational studies, clinical studies are divided. The aim of this multicenter-international study was to capture REBOA-specific data and outcomes.MethodsREBOA practicing centers were invited to join this online register, which was established in September 2014. REBOA cases were reported, both retrospective and prospective. Demographics, injury patterns, hemodynamic variables, REBOA-specific data, complications and 30-days mortality were reported.ResultsNinety-six cases from 6 different countries were reported between 2011 and 2016. Mean age was 52 ± 22 years and 88% of the cases were blunt trauma with a median injury severity score (ISS) of 41 (IQR 29–50). In the majority of the cases, Zone I REBOA was used. Median systolic blood pressure before balloon inflation was 60 mmHg (IQR 40–80), which increased to 100 mmHg (IQR 80–128) after inflation. Continuous occlusion was applied in 52% of the patients, and 48% received non-continuous occlusion. Occlusion time longer than 60 min was reported as 38 and 14% in the non-continuous and continuous groups, respectively. Complications, such as extremity compartment syndrome (n = 3), were only noted in the continuous occlusion group. The 30-day mortality for non-continuous REBOA was 48%, and 64% for continuous occlusion.ConclusionsThis observational multicenter study presents results regarding continuous and non-continuous REBOA with favorable outcomes. However, further prospective studies are needed to be able to draw conclusions on morbidity and mortality.
Background: Laparoscopic cholecystectomy is commonly performed, and several factors increase the
Readmissions and complications following cholecystectomy are common and associated with patient and disease characteristics.
IntroductionLiver surgery is widely used as a treatment modality for various liver pathologies. Despite significant improvement in clinical care, operative strategies and technology over the last few decades, liver surgery is still risky and optimal preoperative planning and anatomical assessment are necessary to minimize risks of serious complications. 3D printing technology is rapidly expanding and its applications in medicine are growing, but its applications in liver surgery are still limited. This article describes development of models of hepatic structures specific to a patient diagnosed with an operable hepatic malignancy. MethodsAnatomy data was segmented and extracted form CT and MRI liver of a single patient with a resectable liver tumour. The digital data of the extracted anatomical surfaces was then edited and smoothed resulting in a set of digital 3D models of the hepatic vein, portal vein with tumour, biliary tree with gallbladder and hepatic artery. These were then 3D printed. ResultsThe final models of the liver structures and tumour is provide good anatomical detail and representation of the spatial relationships between the liver tumour and adjacent hepatic structures. It can be easily manipulated and explored from different angles. ConclusionsA graspable, patient specific, 3D printed models of liver structures could provide an improved understanding of the complex liver anatomy, better navigation in difficult areas and allow surgeons to anticipate anatomical issues that might arrive during the operation. Further research into adequate imaging, liver specific volumetric software, and segmentation algorithms are worth considering to optimize this application. Methods Data Extraction and SegmentationRetrospectively collected radiology image data from a patient with an operable malignant hepatic tumour consisted of a standard CT angiogram of abdomen and pelvis and MRI of liver performed using a standard hepatic imaging protocol with gadolinium contrast. The CT slides were 3mm thick and MRI slides were 8.99 mm thick, both yielding anisotropic voxels when viewed as 3D. The data of both scans was stored in Digital Imaging and Communications in Medicine (DICOM) files. Amira 4.5.4. visualisation software (FEI, Hillsboro, USA) was used to view and segment the data. All scans were interrogated in three planes and pixels containing image data for hepatic and portal veins, hepatic artery, biliary structures and tumour were manually selected. (Figure 1). Due to varying image quality between the two radiology modalities used, MRI data was used to segment the biliary tree, portal vein, hepatic veins and tumour, whilst the CT was used to collect data for the hepatic artery. Segmentation was completed with a combination of manual, and "region growing"techniques, where the latter was used for large regions of similar density signal. Surgical InnovationMadurska, Poyade, Eason, Rea, Watson/ Development of patient specific 3D printed liver 5 model for preoperative planning Surface extraction and model pr...
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