Estudo prospectivo e randomizado da revascularização do miocárdio minimamente invasiva com dissecção da artéria torácica interna esquerda por videotoracoscopia robótica / Robotic left internal mammary artery harvesting for single vessel minimally invasive coronary bypass: a randomized controlled trial

Adriano Márcio de Melo Milanez

14 October 2011

Objetivos: O objetivo desse estudo foi comparar a perviedade da artéria torácica interna esquerda (ATIE) dissecada por videotoracoscopia robótica para revascularização minimamente invasiva do ramo interventricular anterior (RIA) com a revascularização do miocárdio convencional. Métodos: De 2007 a 2010, 36 pacientes foram randomizados para revascularização do miocárdio minimamente invasiva (RMMI) ou revascularização do miocárdio convencional (RMC). Pacientes randomizados para o grupo RMMI foram submetidos à dissecção da ATIE por videotoracoscopia auxiliada pelo braço robótico AESOP seguida de uma minitoracotomia anterior esquerda no 4º espaço intercostal para anastomose com o RIA. Pacientes randomizados para o grupo RMC foram submetidos a revascularização do miocárdio convencional com esternotomia mediana completa, dissecção aberta da ATIE e anastomose ao RIA. Fluxometria por tempo de trânsito (FTT) foi utilizada para avaliação da perviedade da ATIE imediata. Após 24 meses uma tomografia multislice foi utilizada para avaliar a perviedade a médio prazo da ATIE. Resultados: O tempo médio de dissecção da ATIE no grupo RMMI foi de 50,1 ± 11,2 vs. 22,7 ± 3,3 min no grupo RMC. Não houve diferença significativa no fluxo médio da ATIE para o RIA entre os grupos estudados (46,17 ± 20,11 vs. 48,61 ± 23,42 mL/min, p=0,86) respectivamente. Não houve diferença significante na incidência de infecção de ferida profunda (0 vs. 2, p=0,48) e necessidade de reoperação por sangramento (0 vs. 1, p=1,00) nos grupos RMMI e RMC respectivamente. A angiotomografia mostrou perviedade da ATIE em 100% dos pacientes do grupo RMMI vs. 94,1% no grupo RMC (p=1,00). Não houve mortalidade nos grupos estudados. Conclusão: A revascularização do miocárdio minimamente invasiva do ramo interventricular anterior com dissecção da artéria torácica interna esquerda por videotoracoscopia robótica foi segura e factível. A perviedade da artéria torácica interna esquerda imediata e a médio prazo foi similar entre ambas as técnicas / Objective: The aim of this study was to compare the patency of left internal mammary artery (LIMA) robotically harvested for left anterior descendent (LAD) artery minimally invasive bypass with conventional LIMA to LAD off-pump bypass. Method: From 2007 to 2010, 36 patients were randomized to either LIMA robotically harvested to LAD artery minimally invasive bypass or standard LIMA to LAD off-pump bypass. Patients assigned to robotic group underwent robotic endoscopic harvesting of LIMA with the AESOP system followed by a small left thoracotomy in the 4th intercostal space for off-pump LAD bypass. Patients assigned to standard group underwent full median sternotomy, open LIMA harvesting followed by off-pump LAD bypass. Transit time flow measurement was used for intraoperative evaluation of LIMA to LAD patency. After a mean 24-month follow-up, Multislice Computed Tomography was used to evaluate LIMA to LAD midterm patency. Results: The mean LIMA harvesting time in robotic group was 50.1 ± 11.2 min vs. 22.7 ± 3.3 min in conventional group. There was no significant difference in intraoperative LIMA to LAD flow between robotic and conventional groups (46.17 ± 20.11 mL/min vs. 48.61 ± 23.42 mL/min, p=0.86). There were no significant differences in incidence of wound infection (0 vs. 2, p=0,48) and reoperation for bleeding (0 vs. 1, p=1.00) between robotic and conventional groups respectively. In robotic group, Multislice CT revealed patent LIMA graft in 100% patients vs. 94.1% patients in conventional group (p=1.00). There was no mortality in the study group. Conclusions: Minimally invasive LAD bypass using LIMA graft robotically harvested was safe and feasible. Early and mid-term LIMA patency was similar between both techniques

Angiografia coronária/métodos

Artéria torácica interna

Doença das coronárias/cirurgia

Ensaio clínico controlado aleatório

Fluxômetros

Patência vascular

Robótica

Tomografia computadorizada espiral

Coronary angiography/methods

Coronary artery bypass off-pump

Coronary disease/surgery

Flowmeters

Mammary arteries

Randomized controlled trial

Robotics

Spiral computed

Surgical procedures minimally invasive

Tomography

Vascular patency

"Contribuição da ressonância magnética na avaliação de doadores do lobo direito ao transplante hepático intervivos" / Contribuition of magnetic resonance in the evaluation of donors for right lobe living liver transplantation

Gisele Warmbrand

14 December 2004

Este estudo teve, por finalidade, estabelecer o valor da ressonância magnética em 30 doadores potenciais do lobo direito do fígado, na determinação dos seguintes fatores: esteatose hepática; anatomia biliar; anatomias arterial hepática, venosas portal e hepática, e volume hepático lobar, comparando-os, respectivamente, com os achados anatomopatológicos da biópsia hepática, da colangiografia intraoperatória, da angiografia digital e/ou com os achados cirúrgicos, e com o peso real do enxerto. A RM subestimou a infiltração gordurosa hepática; permitiu identificar a anatomia biliar, com concordância em 83% dos casos; apresentou 100% de concordância na avaliação das anatomias arterial e venosas portal e hepática, e superestimou, em pequeno grau, o volume hepático lobar / The purpose of this study was to establish the value of the magnetic resonance in 30 potential donors for right lobe living liver transplantation. The main goal was to determine the following factors: steatosis; biliar anatomy; hepatic arterial anatomy; portal and hepatic venous anatomy, and lobar liver volume, comparing them to liver biopsy results, to intraoperative colangiography, to digital angiography and/or surgical findings, and to the real graft weight, respectively. The MR has underestimated liver steatosis; it has identified biliar anatomy with 83% of agreement; it has had 100% of agreement in the evaluation of arterial and portal and hepatic venous anatomy, and it has overestimated with small degree the lobar liver volume

COLANGIOGRAFIA/métodos

DOADORES VIVOS

FÍGADO GORDUROSO

FÍGADO/anatomia & histologia

TRANSPLANTE DE FÍGADO

CHOLANGIOGRAPHY/methods

FATTY LIVER

LIVER TRANSPLANTATION

LIVER/anatomy & histology

LIVING DONORS

MAGNETIC RESONANCE ANGIOGRAPHY/methods

MAGNÉTIC RESONANCE IMAGING/methods

A study of blood flow in normal and dilated aorta

Deep, Debanjan

12 1900

Indiana University-Purdue University Indianapolis (IUPUI) / Atherosclerotic lesions of human beings are common diagnosed in regions of arte- rial branching and curvature. The prevalence of atherosclerosis is usually associated with hardening and ballooning of aortic wall surfaces because of narrowing of flow path by the deposition of fatty materials, platelets and influx of plasma through in- timal wall of Aorta. High Wall Shear Stress (WSS) is proved to be the main cause behind all these aortic diseases by physicians and researchers. Due to the fact that the atherosclerotic regions are associated with complex blood flow patterns, it has believed that hemodynamics and fluid-structure interaction play important roles in regulating atherogenesis. As one of the most complex flow situations found in cardio- vascular system due to the strong curvature effects, irregular geometry, tapering and branching, and twisting, theoretical prediction and in vivo quantitative experimental data regarding to the complex blood flow dynamics are substantial paucity. In recent years, computational fluid dynamics (CFD) has emerged as a popular research tool to study the characteristics of aortic flow and aim to enhance the understanding of the underlying physics behind arteriosclerosis. In this research, we study the hemo- dynamics and flow-vessel interaction in patient specific normal (healthy) and dilated (diseased) aortas using Ansys-Fluent and Ansys-Workbench. The computation con- sists of three parts: segmentation of arterial geometry for the CFD simulation from computed tomography (CT) scanning data using MIMICS; finite volume simulation of hemodynamics of steady and pulsatile flow using Ansys-Fluent; an attempt to perform the Fluid Structure Simulation of the normal aorta using Ansys-Workbench. Instead of neglecting the branching or smoothing out the wall for simplification as a lot of similar computation in literature, we use the exact aortic geometry. Segmen- tation from real time CT images from two patients, one young and another old to represent healthy and diseased aorta respectively, is on MIMICS. The MIMICS seg- mentation operation includes: first cropping the required part of aorta from CT dicom data of the whole chest, masking of the aorta from coronal, axial and saggital views of the same to extract the exact 3D geometry of the aorta. Next step was to perform surface improvement using MIMICS 3-matic module to repair for holes, noise shells and overlapping triangles to create a good quality surface of the geometry. A hexahe- dral volume mesh was created in T-Grid. Since T-grid cannot recognize the geometry format created by MIMICS 3-matic; the required step geometry file was created in Pro-Engineer. After the meshing operation is performed, the mesh is exported to Ansys Fluent to perform the required fluid simulation imposing adequate boundary conditions accordingly. Two types of study are performed for hemodynamics. First is a steady flow driven by specified parabolic velocity at inlet. We captured the flow feature such as skewness of velocity around the aortic arch regions and vortices pairs, which are in good agreement with open data in literature. Second is a pulsatile flow. Two pulsatile velocity profiles are imposed at the inlet of healthy and diseased aorta respectively. The pulsatile analysis was accomplished for peak systolic, mid systolic and diastolic phase of the entire cardiac cycle. During peak systole and mid-systole, high WSS was found at the aortic branch roots and arch regions and diastole resulted in flow reversals and low WSS values due to small aortic inflow. In brief, areas of sudden geometry change, i.e. the branch roots and irregular surfaces of the geom- etry experience more WSS. Also it was found that dilated aorta has more sporadic nature of WSS in different regions than normal aorta which displays a more uniform WSS distribution all over the aorta surface. Fluid-Structure Interaction simulation is performed on Ansys-WorkBench through the coupling of fluid dynamics and solid mechanics. Focus is on the maximum displacement and equivalent stress to find out the future failure regions for the peak velocity of the cardiac cycle.

Arteries -- Research

Arteriosclerosis

Computational fluid dynamics -- Research

Blood-vessels -- Physiology

Aortic valve -- Stenosis

Blood flow -- Measurement

Blood flow -- Diseases

Human physiology -- Mathematical models

Coronary arteries -- Tomography

Heart -- Diseases -- Computer simulation

Biomedical engineering -- Research