BACKGROUND/AIMS: Energy charge and capacity for adenosine triphosphate (ATP) synthesis have been demonstrated to play a major role in the maintenance of organ function after liver preservation for transplantation. The aim of this study was to evaluate whether a supply of liposomally-entrapped ATP during preservation could improve the energy state and metabolism of cold-stored rat liver. METHODS: In the first set of experiments, the uptake of ATP-containing liposomes and their effects on hepatic viability were determined in isolated perfused unstored rat liver. In the second set of experiments, rat livers were preserved for 18 h at 4 degrees C in UW solution in the presence of these liposomes, and effects on energy state, cell volume and metabolism were evaluated. In each part, data were compared with adequate control, unloaded liposome-treated, and free ATP-treated groups (n=6 in each group). RESULTS: In non-stored livers, ATP-containing liposomes were taken up by the liver; they did not alter hepatic viability and induced a decrease in energy substrate consumption (glucose and amino acids), and an improvement in intrahepatic ATP content (+23% vs. Control). Addition of liposomally-entrapped ATP during cold storage produced a significant attenuation of the decrease in hepatic ATP content (Lip ATP 2: 524+/-45 vs. Control 2: 364+/-106 nmol/g; p<0.05), and induced, during reperfusion, a decrease in proteolysis associated with an increase in cell volume compared with the other groups (Lip ATP 2: 633+/-63 vs. Control 2: 532+/-38, Unloaded Lip 2: 483+/-55 and Free ATP 2: 500+/-29 microl/g; p<0.01). CONCLUSIONS: These data indicate that liposomally-entrapped ATP represents an effective means to improve liver graft energy state and function. The decrease in protein degradation may be related to the modification of cell volume.
BACKGROUND/AIMS: Energy charge and capacity for adenosine triphosphate (ATP) synthesis have been demonstrated to play a major role in the maintenance of organ function after liver preservation for transplantation. The aim of this study was to evaluate whether a supply of liposomally-entrapped ATP during preservation could improve the energy state and metabolism of cold-stored rat liver. METHODS: In the first set of experiments, the uptake of ATP-containing liposomes and their effects on hepatic viability were determined in isolated perfused unstored rat liver. In the second set of experiments, rat livers were preserved for 18 h at 4 degrees C in UW solution in the presence of these liposomes, and effects on energy state, cell volume and metabolism were evaluated. In each part, data were compared with adequate control, unloaded liposome-treated, and free ATP-treated groups (n=6 in each group). RESULTS: In non-stored livers, ATP-containing liposomes were taken up by the liver; they did not alter hepatic viability and induced a decrease in energy substrate consumption (glucose and amino acids), and an improvement in intrahepatic ATP content (+23% vs. Control). Addition of liposomally-entrapped ATP during cold storage produced a significant attenuation of the decrease in hepatic ATP content (Lip ATP 2: 524+/-45 vs. Control 2: 364+/-106 nmol/g; p<0.05), and induced, during reperfusion, a decrease in proteolysis associated with an increase in cell volume compared with the other groups (Lip ATP 2: 633+/-63 vs. Control 2: 532+/-38, Unloaded Lip 2: 483+/-55 and Free ATP 2: 500+/-29 microl/g; p<0.01). CONCLUSIONS: These data indicate that liposomally-entrapped ATP represents an effective means to improve liver graft energy state and function. The decrease in protein degradation may be related to the modification of cell volume.
Authors: Claudio Maldonado; Sathnur B Pushpakumar; Gustavo Perez-Abadia; Sengodagounder Arumugam; Andrew N Lane Journal: J Surg Res Date: 2012-07-06 Impact factor: 2.192