2018 Clinical Update in Liver Transplantation.

Liver transplantation (LT) continues to be the gold standard for treating end-stage liver disease, and challenges that are posed to the anesthesiologist during transplantation are well known. Successful liver transplantation requires knowledge, recognition, and treatment of hemodynamic and metabolic disturbances by the anesthesiologist. End-stage liver disease causes unique derangements to the clotting cascade, increasing risk both for hemorrhagic and thrombotic events. Cirrhotic cardiomyopathy may be masked for years because of low systemic vascular resistance in cirrhosis, and overt heart failure can be precipitated by LT. Surveys of high-volume transplant centers show an overall transesophageal echocardiography (TEE) use rate of 95%. Guidelines on the use of TEE in LT have mirrored safety findings in several studies and suggest TEE may be used for patients with esophageal varices if the benefit outweighs the risk. This review will cover organ system dysfunction in liver cirrhosis and the implications for liver cirrhosis patients and review recent advances in pathophysiology and treatments. In addition, the authors will highlight the concept of enhanced recovery after surgery and how it pertains to the LT patient population. Lastly, the authors review recent advances in organ preservation and optimization.

Feasibility of geometric-intensity-based semi-automated delineation of the tentorium cerebelli from MRI scans.

This paper describes a feasibility study of a method for delineating the tentorium cerebelli in magnetic resonance imaging (MRI) brain scans. The tentorium cerebelli is a thin sheet of dura matter covering the cerebellum and separating it from the posterior part of the temporal lobe and the occipital lobe of the cerebral hemispheres. Cortical structures such as the parahippocampal gyrus can be indistinguishable from tentorium in magnetized prepared rapid gradient echo and T1-weighted MRI scans. Similar intensities in these neighboring regions make it difficult to perform accurate cortical analysis in neuroimaging studies of schizophrenia and Alzheimer's disease. A semi-automated, geometric, intensity-based procedure for delineating the tentorium from a whole-brain scan is described. Initial and final curves are traced within the tentorium. A cost function, based on intensity and Euclidean distance, is computed between the two curves using the Fast Marching method. The initial curve is then evolved to the final curve based on the gradient of the computed costs, generating a series of intermediate curves. These curves are then used to generate a triangulated surface of the tentorium. For 3 scans, surfaces were found to be within 2 voxels from hand segmentations.