Análisis numérico de una prótesis endobronquial utilizada para el tratamiento de cáncer pulmonar / Numerical analysis of intrabronchial prosthesis used for the treatment of lung cancer

En México, la mortalidad debido a enfermedades bronco-respiratorias se ubica en el sexto lugar según datos estadísticos dados por el Instituto Nacional de Enfermedades Respiratorias (INER). Esto genera la necesidad de incrementar la eficiencia en la aplicación de los tratamientos usados para este tipo de patología. Algunos de los métodos utilizados con mayor frecuencia para el tratamiento de estas dolencias hacen uso de micro dispositivos, también conocidos como válvulas endobronquiales. Este es un sistema alternativo que evita cirugías invasivas y logra prolongar e incrementar la calidad de vida de los pacientes. En este trabajo se presenta el análisis del desempeño de la válvula IBV®. Para el desarrollo del estudio numérico se determinaron las dimensiones y propiedades mecánicas del modelo a partir de catálogos del fabricante. Se desarrolló un modelo para el cual se consideraron las propiedades del Nitinol® y Silastic®. Asimismo, se propusieron dos condiciones de operación para la válvula, una anclada en el bronquio y la otra en la condición en la que se encuentra plegada dentro del broncoscopio. Se utilizó el Método del elemento finito (MEF) para simular las condiciones de trabajo de la válvula. Los resultados encontrados muestran el funcionamiento estructural y el nivel de los esfuerzos generados en el implante durante el ciclo de respiración forzada del individuo. Además, se proporcionan las bases para generar un nuevo dispositivo que pueda emular el funcionamiento de este tipo de implantes y aumente la eficiencia del tratamiento de dicha patología.

In Mexico, the mortality rate due to bronchial respiratory sickness is placed in the sixth position, according to statistics from the National Institute of Breathing Sickness (INER), so it is convenient to increment the efficiency of treatments for those pathologies. The intrabronchial valve is a recommended alternative method; being it main objective to avoid invasive surgery and increase the time and quality of patient´s life. Within this work a biomechanical analysis of an IBV® valve is carried out. Regarding the numerical analysis, the dimensions and mechanical properties of the valve were proposed based on catalogues published by the manufacturer as more reliable information was not available in the open literature. As a result, a new model was developed in which both materials Nitinol® and Silastic® are considered as the main valve materials. The proposed working conditions assume that the valve is implanted in folded form at the bronchus and then anchored when it is unfolded. Finite Element Method (FEM) was used to simulate the proposed working conditions. Results obtained show the structural performance and the level of stress generated in the implant during the breathing cycle. In addition, it provides the knowledge to generate a new device that could emulate the performance of these implants and develop a more efficient treatment this disease.

HLA expression in aortic and pulmonary homografts: effects of cryopreservation.

BACKGROUND: The present study was undertaken to find out the HLA allo-antigens on cardiac homografts. METHODS AND RESULTS: One pulmonary and eight aortic homografts were studied for the presence of major HLA class I and class II antigen expression. Cadaveric hearts were procured from the mortuary and kept in Hank's balanced salt solution with antibiotics at 4 degrees C. Bits were taken from the conduits and valves every 24 hours for 14 days during storage and snap-frozen using liquid nitrogen. A total of 1368 sections were made using a cryostat. These sections were stained using 4 monoclonal antibodies: BLA class I (MO736), class II HLA-DR (MO746), CD45 (MO701), and endothelial stain (MO616). All monoclonals were procured from DAKO. Class I antigen molecules could be demonstrated on the endothelial surface of the vessel wall from day 1 to day 4 to 5 of storage. They stained weaker and could not be demonstrated after day 10 of storage. Class I antigen molecules were positive in very fresh valves and by day 5-6 could not be seen on the valve surface. Class II (HLA-DR) antigen expression was present in the subendothelial layer from day 1 to day 12-14 of storage. They could also be demonstrated in valves and conduits released after cryopreservation. These class II staining cells were also stained by CD45 monoclonal antibody and hence could be macrophages, histiocytes or leucocytes. The endothelium was very well demonstrated in the vessel walls from day 1 to day 12-14 of storage; it could only be seen in very fresh valves. Storage in the liquid medium and sterilization procedures led to loss of endothelial lining of the valves. After cryopreservation and thawing, class I antigen molecules could not be demonstrated on the valves and conduits. Class II antigen molecules and CD45-stained cells continued to be demonstrated in the subendothelial layer and the valve matrix. The endothelium was intact in the vessel wall after cryopreservation and thawing, but could not be seen in the released valves. CONCLUSIONS: Allograft aortic and pulmonary conduits and valves are immunogenic, and HLA-ABC and HLA-DR antigen molecules can be demonstrated on different components of the vessel wall and valve leafets.