by Keyword: Vascular resistance
da Palma, R. K., Nonaka, P. N., Campillo, N., Uriarte, J. J., Urbano, J. J., Navajas, D., Farré, R., Oliveira, L. V. F., (2016). Behavior of vascular resistance undergoing various pressure insufflation and perfusion on decellularized lungs Journal of Biomechanics 49, (7), 1230-1232
Bioengineering of functional lung tissue by using whole lung scaffolds has been proposed as a potential alternative for patients awaiting lung transplant. Previous studies have demonstrated that vascular resistance (Rv) could be altered to optimize the process of obtaining suitable lung scaffolds. Therefore, this work was aimed at determining how lung inflation (tracheal pressure) and perfusion (pulmonary arterial pressure) affect vascular resistance. This study was carried out using the lungs excised from 5 healthy male Sprague-Dawley rats. The trachea was cannulated and connected to a continuous positive airway pressure (CPAP) device to provide a tracheal pressure ranging from 0 to 15cmH2O. The pulmonary artery was cannulated and connected to a controlled perfusion system with continuous pressure (gravimetric level) ranging from 5 to 30cmH2O. Effective Rv was calculated by ratio of pulmonary artery pressure (P PA) by pulmonary artery flow (V'PA). Rv in the decellularized lungs scaffolds decreased at increasing V' PA, stabilizing at a pulmonary arterial pressure greater than 20cmH2O. On the other hand, CPAP had no influence on vascular resistance in the lung scaffolds after being subjected to pulmonary artery pressure of 5cmH2O. In conclusion, compared to positive airway pressure, arterial lung pressure markedly influences the mechanics of vascular resistance in decellularized lungs.
JTD Keywords: Decellularized lung, Scaffolds, Vascular resistance
da Palma, R. K., Campillo, N., Uriarte, J. J., Oliveira, L. V. F., Navajas, D., Farré, R., (2015). Pressure- and flow-controlled media perfusion differently modify vascular mechanics in lung decellularization Journal of the Mechanical Behavior of Biomedical Materials , 49, 69-79
Organ biofabrication is a potential future alternative for obtaining viable organs for transplantation. Achieving intact scaffolds to be recellularized is a key step in lung bioengineering. Perfusion of decellularizing media through the pulmonary artery has shown to be effective. How vascular perfusion pressure and flow vary throughout lung decellularization, which is not well known, is important for optimizing the process (minimizing time) while ensuring scaffold integrity (no barotrauma). This work was aimed at characterizing the pressure/flow relationship at the pulmonary vasculature and at how effective vascular resistance depends on pressure- and flow-controlled variables when applying different methods of media perfusion for lung decellularization. Lungs from 43 healthy mice (C57BL/6; 7-8 weeks old) were investigated. After excision and tracheal cannulation, lungs were inflated at 10cmH
JTD Keywords: Acellular lung, Fluid mechanics, Lung bioengineering, Lung scaffold, Organ biofabrication, Tissue engineering, Vascular resistance