Liver-assist device with a microfluidics-based vascular bed in an animal model
Journal
Annals of Surgery
Journal Volume
252
Journal Issue
2
Pages
351-357
Date Issued
2010
Author(s)
Carraro A.
Kulig K.M.
Miller M.L.
Kaazempur-Mofrad M.
Weinberg E.
Entabi F.
Albadawi H.
Watkins M.T.
Borenstein J.T.
Vacanti J.P.
Neville C.
Abstract
Objective: This study evaluates a novel liver-assist device platform with a microfluidics-modeled vascular network in a femoral arteriovenous shunt in rats. Summary of background data: Liver-assist devices in clinical trials that use pumps to force separated plasma through packed beds of parenchymal cells exhibited significant necrosis with a negative impact on function. Methods: Microelectromechanical systems technology was used to design and fabricate a liver-assist device with a vascular network that supports a hepatic parenchymal compartment through a nanoporous membrane. Sixteen devices with rat primary hepatocytes and 12 with human HepG2/C3A cells were tested in athymic rats in a femoral arteriovenous shunt model. Several parenchymal tube configurations were evaluated for pressure profile and cell survival. The blood flow pattern and perfusion status of the devices was examined by laser Doppler scanning. Cell viability and serum protein secretion functions were assessed. Results: Femoral arteriovenous shunt was successfully established in all animals. Blood flow was homogeneous through the vascular bed and replicated native flow patterns. Survival of seeded liver cells was highly dependent on parenchymal chamber pressures. The tube configuration that generated the lowest pressure supported excellent cell survival and function. Conclusions: This device is the first to incorporate a microfluidics network in the systemic circulatory system. The microvascular network supported viability and function of liver cells in a short-term ex vivo model. Parenchymal chamber pressure generated in an arteriovenous shunt model is a critical parameter that affects viability and must be considered in future designs. The microfluidics-based vascular network is a promising platform for generating a large-scale medical device capable of augmenting liver function in a clinical setting. Copyright ? 2010 by Lippincott Williams & Wilkins.
SDGs
Other Subjects
albumin; dimeticone; polyethersulfone; silastic; animal cell; animal experiment; animal model; arteriovenous shunt; article; cell viability; controlled study; device; femoral artery; femoral vein; fluorescence microscopy; human; human cell; laser Doppler flowmetry; liver; liver assist device; liver cell; liver function; medical instrumentation; microelectromechanical system; microfluidics; nonhuman; nude rat; priority journal; protein secretion; rat; treatment outcome; Animals; Arteriovenous Shunt, Surgical; Bioreactors; Cell Culture Techniques; Cell Survival; Cells, Cultured; Disease Models, Animal; Femur; Hepatocytes; Laser-Doppler Flowmetry; Liver, Artificial; Male; Microcirculation; Microfluidics; Proteins; Rats; Rats, Inbred Lew
Type
journal article