Your search keyword '"Gellman, Barry"' showing total 2 results

1. Computational Design and In Vitro Characterization of an Integrated Maglev Pump-Oxygenator.

Author

Zhang, Juntao, Taskin, M. Ertan, Koert, Andrew, Zhang, Tao, Gellman, Barry, Dasse, Kurt A., Gilbert, Richard J., Griffith, Bartley P., and Wu, Zhongjun J.

Subjects

LUNG diseases, MEMBRANE oxygenators, COMPUTATIONAL fluid dynamics, COMPUTER-aided design, COMPUTATIONAL complexity, HEMODYNAMICS

Abstract

For the need for respiratory support for patients with acute or chronic lung diseases to be addressed, a novel integrated maglev pump-oxygenator (IMPO) is being developed as a respiratory assist device. IMPO was conceptualized to combine a magnetically levitated pump/rotor with uniquely configured hollow fiber membranes to create an assembly-free, ultracompact system. IMPO is a self-contained blood pump and oxygenator assembly to enable rapid deployment for patients requiring respiratory support or circulatory support. In this study, computational fluid dynamics (CFD) and computer-aided design were conducted to design and optimize the hemodynamics, gas transfer, and hemocompatibility performances of this novel device. In parallel, in vitro experiments including hydrodynamic, gas transfer, and hemolysis measurements were conducted to evaluate the performance of IMPO. Computational results from CFD analysis were compared with experimental data collected from in vitro evaluation of the IMPO. The CFD simulation demonstrated a well-behaved and streamlined flow field in the main components of this device. The results of hydrodynamic performance, oxygen transfer, and hemolysis predicted by computational simulation, along with the in vitro experimental data, indicate that this pump-lung device can provide the total respiratory need of an adult with lung failure, with a low hemolysis rate at the targeted operating condition. These detailed CFD designs and analyses can provide valuable guidance for further optimization of this IMPO for long-term use. [ABSTRACT FROM AUTHOR]

Published

2009

2. Functional and Biocompatibility Performances of an Integrated Maglev Pump-Oxygenator.

Author

Zhang, Tao, Cheng, Guangming, Koert, Andrew, Zhang, Juntao, Gellman, Barry, Yankey, G. Kwame, Satpute, Aditee, Dasse, Kurt A., Gilbert, Richard J., Griffith, Bartley P., and Wu, Zhongjun J.

Subjects

OXYGENATORS, LUNG disease diagnosis, RESPIRATORY insufficiency treatment, BIOCOMPATIBILITY, HEMODYNAMICS, ANIMAL models in research, EQUIPMENT & supplies

Abstract

To provide respiratory support for patients with lung failure, a novel compact integrated pump-oxygenator is being developed. The functional and biocompatibility performances of this device are presented. The pump-oxygenator is designed by combining a magnetically levitated pump/rotor with a uniquely configured hollow fiber membrane bundle to create an assembly free, ultracompact, all-in-one system. The hemodynamics, gas transfer and biocompatibility performances of this novel device were investigated both in vitro in a circulatory flow loop and in vivo in an ovine animal model. The in vitro results showed that the device was able to pump blood flow from 2 to 8 L/min against a wide range of pressures and to deliver an oxygen transfer rate more than 300 mL/min at a blood flow of 6 L/min. Blood damage tests demonstrated low hemolysis (normalized index of hemolysis [NIH]∼0.04) at a flow rate of 5 L/min against a 100-mm Hg afterload. The data from five animal experiments (4 h to 7 days) demonstrated that the device could bring the venous blood to near fully oxygen-saturated condition (98.6% ± 1.3%). The highest oxygen transfer rate reached 386 mL/min. The gas transfer performance was stable over the study duration for three 7-day animals. There was no indication of blood damage. The plasma free hemoglobin and platelet count were within the normal ranges. No gross thrombus is found on the explanted pump components and fiber surfaces. Both in vitro and in vivo results demonstrated that the newly developed pump-oxygenator can achieve sufficient blood flow and oxygen transfer with excellent biocompatibility. [ABSTRACT FROM AUTHOR]

Published

2009