Evaluation of rat liver apoptotic and necrotic cell death after cold storage using UW,HTK, and Celsior

BACKGROUND: The benefit of Celsior in liver graft preservation is controversial. In the isolated perfused rat liver model, we compared the effects of Celsior, University of Wisconsin (UW), and histidine-tryptophan-ketoglutarate (HTK) preservation solutions on liver cell death. METHODS: Rat livers were stored at 4 degrees C for 0, 8, 16, or 24 hr in either Celsior, UW, or HTK and reperfused for 90 min (37 degrees C). Bile secretion and perfusate levels of liver enzymes and histone-associated DNA fragments were measured. Apoptosis and oncotic necrosis were analyzed in biopsies by DNA gel electrophoresis, hematoxylin and eosin histology, and enzyme histochemistry for lactate dehydrogenase (LDH) and 5'-nucleotidase (5'-NT). RESULTS: Perfusate flow rate through the liver during perfusion did not significantly differ among preservation solutions. Bile secretion was best preserved in UW livers after 16-hr (versus HTK livers) and 24-hr storage (versus HTK and Celsior livers). Enzyme leakage from UW livers was lower compared with HTK livers after 8-hr storage (serum glutamic oxaloacetic transaminase [SGOT], LDH) and with Celsior and HTK livers after 16-hr (SGOT, LDH) and 24-hr storage (SGOT, serum glutamic pyruvic transaminase, LDH, purine nucleoside phosphorylase). In situ LDH and 5'-NT activities were best preserved in UW livers (up to 24 hr), whereas enzyme activities declined remarkably in HTK livers (after 8 hr) and Celsior livers (after 16 hr of cold storage). Although perfusate DNA fragment levels were repeatedly lowest from Celsior livers, apoptotic DNA laddering and the number of fragmented nuclei in hematoxylin and eosin sections was not different among livers after 8, 16, or 24 hr of storage. CONCLUSIONS: Celsior and UW are equally effective in preventing rat liver cell death after 0-16 hr of cold preservation as compared with the less effective HTK solution. After 24-hr cold storage, rat livers were best preserved in UW. Furthermore, there was no significant difference in mode of cell death (apoptosis or oncotic necrosis) after storage in any of the three solutions.     

Curcumin has potent liver preservation properties in an isolated perfusion model

BACKGROUND: Curcumin has profound antioxidant and anti-inflammatory properties. This research assessed the effect of curcumin on liver preservation. METHODS: Sprague-Dawley rat livers were flushed with different preservation solutions [Euro-Collins solution (EC), phosphate buffer saline (PBS), University of Wisconsin solution (UW)] with or without curcumin (25-200 microM) and stored at 4 degrees C for 24-48 hours. Livers were then perfused for 120 minutes via the portal vein with oxygenated Krebs-Henseleit bicarbonate buffer solution at a pressure of 18 cm H2O in a perfusion apparatus. The livers in the normal (NL) group were flushed with EC, PBS, or UW, then immediately perfused (zero preservation time). RESULTS: We found that curcumin at 100 microM concentration had the optimal preservation characteristics. Portal flow rates and bile production were significantly higher and liver enzymes (alanine aminotransferase, aspartate aminotransferase, and lactate dehydrogenase) were significantly lower in the EC+C livers and PBS+C livers than in the EC or PBS with optimum concentration of 100 microM of curcumin. Comparing UW+C vs. UW livers, at 24 hours there was no difference in these parameters; however, at 36 hours and 48 hours, portal flow rates and bile production were significantly higher in UW+C livers. CONCLUSIONS: We found that curcumin has inherent organ preservation quality as it enhanced liver preservation in PBS. In addition, curcumin enhanced the preservation quality of EC and UW solutions, thereby extending the preservation time while maintaining the organ quality.     

Prolonged 24-hour subzero preservation of heterotopically transplanted rat hearts using antifreeze proteins derived from arctic fish

BACKGROUND: Arctic fish survive subzero temperatures by producing a family of antifreeze proteins (AFPs) that noncolligatively lower the freezing temperature of their body fluids. We report 24-hour storage of mammalian hearts for transplantation at subzero temperatures using AFPs derived from arctic fish. METHODS: Forty-two heterotopic transplantations were performed in isoimmune Sprague-Dawley rats. Harvested hearts were retrogradely infused with cold 4 degrees C University of Wisconsin (UW) solution and were preserved in a specialized cooling bath at two target temperatures, 4 degrees C and -1.3 degrees C for 12,18, and 24 hours (6 experiments/group). Preservation solutions were UW alone for the 4 degrees C group, and UW with 15 mg/mL AFP III for the -1.3 degrees C group. After hypothermic storage the hearts were heterotopically transplanted into isoimmune rats. Viability was assessed and graded on a scale of 0 to 6 (0 = no contractions to 6 = excellent contractions). Transplanted hearts were then fixed in vivo and were subject to electron microscopy and histopathologic examination. RESULTS: None of the hearts preserved at -1.3 degrees C in UW/AFP III solution froze. All control hearts preserved at -1.3 degrees C without AFP protection froze and died at reperfusion. Viability of hearts preserved at -1.3 degrees C in UW/AFP III solution was significantly better after 18 hours of preservation, 30 and 60 minutes after reperfusion (median, 5 versus 3 and 6 versus 3, respectively; p < 0.05) and after 24 hours of preservation 30 and 60 minutes after reperfusion (median, 4.5 versus 1.5 and 5 versus 2, respectively; p < 0.05). Histologic and electron microscopy studies demonstrated better myocyte structure and mitochondrial integrity preservation with UW/AFP III solution. CONCLUSIONS: Antifreeze proteins prevent freezing in subzero cryopreservation of mammalian hearts for transplantation. Subzero preservation prolongs ischemic times and improves posttransplant viability.     

Hypothermic machine perfusion of rat livers preserves endothelial cell function

This study was conducted to investigate the effect of starch in the preservation solution during hypothermic machine perfusion (HMP) on endothelial cell and hepatocyte functions in an isolated perfused rat liver model. Livers isolated from male Sprague-Dawley rats were perfused with the University of Wisconsin (UW) solution (HMP + starch group); modified UW solution (starch omitted) (HMP - starch group) at 0.4 mL/min per g liver; or simply stored in the UW solution (SCS group) at 4 degrees C for 24 hours. Following preservation, livers from HMP + starch, HMP - starch, SCS, and control group (without preservation) were perfused with Krebs-Henseleit Buffer solution at 37 degrees C for 30 minutes. Samples were taken every 10 minutes during 30-minute warm perfusion to assess hepatocyte and endothelial cell function and damage. After 24 hours of hypothermic preservation and 30 minutes rewarming, livers in the HMP + starch group displayed significantly lower lactate dehydrogenase levels and higher bile production. Endothelial cell function was also improved as indicated by hyaluronic acid uptake and shorter transient time for albumin observed in a multiple indicator dilution study. Liver wet and dry ratio and histological findings confirmed reduced edema formation in the tissue of the HMP + starch group livers compared with that of the HMP - starch and SCS group livers. These results suggest that HMP with the UW solution containing starch improve endothelial cell function and induce less hepatocellular damage following 24-hour preservation compared to SCS and HMP with the starch-free UW solution. These results also suggest that oncotic support may be an important component in preserving hepatic microcirculation in HMP.     

Euro-Collins solution versus UW-solution for long-term liver preservation in the isolated rat-liver perfusion model.

To compare UW-solution (UW) and Euro-Collins (EC) for long-term liver preservation we investigated the morphology and metabolic capacity of rat liver after 18 and 42-hours cold-storage in either UW or EC. After harvesting the rat liver was transferred to a perfusion chamber where it was perfused for 10 min with UW or EC at 4 degrees C. Thereafter livers were stored at 4 degrees C in UW or EC for 18 hours (both groups n = 6) or for 42 hours (both groups n = 8). After 18-hr or 42-hr cold-storage a 2-hr warm perfusion (37 degrees C) was started with Krebs-Ringer solution with carbogen to which 125Iodine-triiodothyronine (T3) was added. Control livers (n = 8) were immediately perfused with Krebs-Ringer without cold-storage. The following parameters were assessed: ASAT-levels in the perfusate, T3-metabolites in the bile and the perfusate, the perfusion pressure, the volume of bile secreted and light-microscopical morphology at the end of the warm perfusion period. After cold storage in UW-solution the ASAT-levels in the perfusate were lower than after storage in EC as well as the perfusion pressures. These livers demonstrated a better T3-metabolism and secreted more bile than EC-stored livers. Histological examination showed more tissue damage in the EC-stored livers than in the UW stored livers. We conclude that cold-storage of rat liver in UW-solution resulted in a better morphology and metabolic capacity as compared with EC-solution.     

Preservation of myocyte structure and mitochondrial integrity in subzero cryopreservation of mammalian hearts for transplantation using antifreeze proteins--an electron microscopy study.

OBJECTIVE: Freeze tolerant fish and insects in nature are able to survive subzero temperatures by noncolligatively lowering the freezing temperature of their body fluids using a family of thermal hysteresis proteins (antifreeze proteins, AFPs) specific for each species. Past efforts to cryopreserve mammalian hearts using these proteins were unsuccessful. We report the first successful subzero cryopreservation of rat hearts using fish derived antifreeze proteins with preservation of myocyte structure. METHODS: Heterotopic heart transplantations were performed in isoimmunic Sprague Dawley rats. Donors' hearts were arrested using University of Wisconsin (UW) solution and preserved in UW solution containing AFP I (six experiments) or AFP III (six experiments) at concentrations of 15-20 mg/cc for 2-6 h at subzero temperatures ranging from -1.1 to -1.3 degrees C. Four control experiments were performed by preserving harvested hearts in UW solution alone at -1.3 degrees C for 6 h. In all experiments ice was added in the solution for crystallization. Heterotopic transplantations were performed in the abdomen of the recipient rats. Viability was visually assessed and graded on a scale of 1 (poor contraction) to 6 (excellent contraction). The hearts were then fixed in vivo and processed for electron microscopy study. RESULTS: All hearts preserved at subzero temperatures using AFP I or AFP III survived displaying viability scores of 4-6 1 h after transplantation. Three of the four control hearts that were preserved at -1.3 degrees C without the protective effect of AFP froze and died upon reperfusion. Electron microscopy study of hearts preserved with AFP demonstrated preservation of myocyte structure and mitochondrial integrity.CONCLUSION: Subzero cryopreservation of mammalian hearts for transplantation using AFP I or AFP III is feasible with preservation of myocyte structure and mitochondrial integrity.     

Comparison of solutions for preservation of the rabbit liver as tested by isolated perfusion

The University of Wisconsin (UW) solution consists of a relatively complex mixture of agents. In this study we compared simpler preservation solutions, namely, histidine-tryptophan-ketoglutarate glutarate (HTK) and phosphatebuffered sucrose (PBS) with different compositions of UW solution in the isolated perfused rabbit liver model. Livers were stored cold for 24 and 48 h. After 24 h of preservation, the amount of bile produced in UW-preserved livers was significantly greater (P<0.05) than that in HTK-preserved livers. Also, there was less LDH released into the perfusate in UW-preserved livers. There was more edema and lower K+/Na+ rations in HTK-preserved livers than in UW-preserved livers (all data P<0.05). After 48 h of preservation, the differences between livers preserved in UW or HTK solution were less noticeable than at 24 h and bile production was similar. LDH and AST release were greater in HTK-preserved livers than in UW livers, but these differences were not statistically significant. Preservation in PBS for 48 h was worse than in either UW or HTK solution. Substitution of polyethylene glycol (PEG) for hydroxyethyl starch (HES) in 48-h UW-preserved livers was not effective. We conclude that solutions simpler in composition than UW solution may be effective in kidney transplantation but do not appear suitable for successuful liver preservation.     

Warm preflush with streptokinase improves microvascular procurement and tissue integrity in liver graft retrieval from non-heart-beating donors

BACKGROUND: Apart from the warm ischemic insult, integrity of liver grafts from non-heart-beating donors (NHBD) is additionally affected by microvascular alterations including erythrocyte aggregation and thrombus formation, which might hamper appropriate equilibration of the preservation solution to the grafts' microvasculature precluding cold preservation. Thus, the objective of our study was to characterize microvascular perfusion quality of University of Wisconsin (UW) solution during initial flushout of livers from NHBD rats, and to analyze the effects of an additional warm preflush with Ringer's lactated solution (RL) and with RL containing streptokinase (SK). METHODS: Cardiocirculatory arrest was induced by phrenotomy. Subsequent to 30 min of warm ischemia, livers were perfused via an aortic catheter by gravity of 100 cm H2O either with 4 degrees C 100 ml UW solution (UW, n=7), or with 25 degrees C 30 ml RL preflush followed by 4 degrees C 100 ml UW solution (RL+UW, n=7), or with 25 degrees C 30 ml SK- (7500 IU) containing RL preflush and 4 degrees C 100 ml UW solution (SK/RL+UW, n=6). Liver microperfusion was quantified using in situ fluorescence epi-illumination microscopy. Liver microcirculation of sham-operated living animals (n=4) served as controls. Enzyme release after a 24-hr cold preservation period was used as an indicator of graft integrity. RESULTS: After 30 min of warm ischemia, microvascular perfusion of UW solution was found markedly altered when compared with that of sham-operated living controls, as indicated by a significant reduction (P<0.05) of acinar and sinusoidal perfusion. Preflush with RL (RL+UW) only slightly attenuated the acinar and sinusoidal perfusion deficits, whereas the addition of SK to RL (SK/RL+UW) resulted in a significant improvement of microvascular graft perfusion (P<0.05). Accordingly, the increased enzyme release observed in solely UW-flushed livers after 24 hr cold preseravtion was only slightly influenced by preflush with RL, but markedly attenuated (P<0.05) by pre-flush with RL containing SK. CONCLUSION: The additive fibrinolytic therapy using SK is effective to improve microvascular procurement of livers after warm ischemia and may thus represent a promising approach to attenuate parenchymal cell injury in liver graft retrieval from NHBD.     

Accumulation of Crystal Deposits in Abdominal Organs Following Perfusion with Defrosted University of Wisconsin Solutions

Previous studies reported on both visible and invisible particles in University of Wisconsin (UW) solutions. Those particles originated from components of the bags. In recent clinical observations we noticed macroscopically visible, indissoluble particles in UW bags reaching subzero temperatures during transportation of organs and preservation solutions. In an experimental model we examined whether those particles could be detected following perfusion of abdominal organs with established perfusion solutions. UW-, HTK- or physiological saline solutions reached -3 +/- 0.5 degrees C under conditions frequently applied during transportation. UW solutions demonstrated the accumulation of visible, indissoluble crystals and were subsequently used for the perfusion of abdominal organs in LEW rats. After perfusion with UW solutions stored at freezing temperatures, crystals were detected in all abdominal organs localized in and around vessels, bile ducts, glomeruli and in the interstitium of harvested livers, kidneys and pancreas. By spectroscopy, we were able to characterize crystals as adenosine. A 40-microm pore-size filter eliminated crystals from UW solutions. Crystals were absent in organs perfused with HTK- or saline solutions kept at subzero conditions. UW solutions can reach subzero temperatures under commonly used transportation conditions. Under these conditions, visible crystals accumulate and can be detected in abdominal organs of an experimental system.     

Improved rat liver preservation by hypothermic continuous machine perfusion using polysol, a new, enriched preservation solution.

For experimental machine perfusion (MP) of the liver, the modified University of Wisconsin solution (UW-G) is most often used. In our search for an enriched MP preservation solution, Polysol was developed. Polysol is enriched with various amino acids, vitamins, and other nutrients for the liver metabolism. The aim of this study was to compare Polysol with UW-G for MP preservation of the liver. Rat livers were preserved during 24 hours with hypothermic MP using UW-G (n = 5) or Polysol (n = 5). Hepatocellular damage (aspartate aminotransferase [AST], alanine aminotransferase [ALT], lactate dehydrogenase [LDH], alpha-glutathione-S-transferase [alpha-GST]) and bile production were measured during 60 minutes of reperfusion (37 degrees C) with Krebs-Henseleit buffer. Control livers were reperfused after 24 hours of cold storage in UW (n = 5). MP using UW-G or Polysol showed less liver damage when compared with controls. Livers machine perfused with Polysol showed less enzyme release when compared to UW-G. Bile production was higher after MP using either UW-G or Polysol compared with controls. In conclusion, machine perfusion using Polysol results in better quality liver preservation than cold storage with UW and machine perfusion using UW-G.     

Hepatic energy metabolism during hypothermic storage and reperfusion using different protecting solutions.

Effects of 5 cold storage solution on hepatic high energy phosphate metabolism and metabolic function were examined using the isolated perfused rat liver. University of Wisconsin (UW), Euro-Collins (EC), and 2 cardioplegic solutions, Bretschneider's HTK and St. Thomas Hospital solution, were studied for their protective capacity. Krebs-Henseleit bicarbonate buffer (KHB) was used to point out the effect of simple hypothermia. Liver ATP, total adenine nucleotides and energy charge losses were significantly lower during 21 h of storage in UW-preserved livers. Also, only UW-protected livers were able to complete regeneration of ATP and total adenine nucleotides after 1 h of reperfusion, whereas EC, HTK, St. Thomas and KHB stored livers only showed minimal regeneration. Concerning metabolic function, UW protected livers liberated significantly less LDH and sGOT as well in the 21-hour storage solution as into the perfusate under reperfusion conditions. This study demonstrates the capability of UW solution in liver preservation by its ability to maintain and restore high energy phosphates.     

Hemodynamic and biochemical changes during normothermic and hypothermic sanguinous perfusion of the porcine hepatic graft

Using an ex vivo liver sanguinous perfusion system, hemodynamic and biochemical changes of the porcine livers were studied, which were preserved cold (4 degrees C) for 24 hr in University of Wisconsin solution and reperfused with normothermic (37 degrees C) (n = 8) or hypothermic (32 degrees C) (n = 8) blood for 3 hr. Six more livers were reperfused with normothermic blood (37 degrees C) immediately after procurement as controls. The total hepatic blood flow was adjusted to 1 ml/min/g liver weight, in which hepatic artery and portal vein flows were administered at a 1:2 ratio. In livers stored cold for 24 hr in UW solution and perfused normothermically, a statistically higher hepatic artery resistance was exhibited at 30 and 60 min after reperfusion (P less than 0.05), and there was lower bile output (P less than 0.05) at 90 and 120 min as compared to the controls. In livers stored cold for 24 hr in UW solution and perfused hypothermically, as compared to ones perfused normothermically, statistically higher hepatic-artery and portal-vein resistances (P less than 0.05) were observed throughout the perfusion period and 60 min after reperfusion, respectively. In addition, bile output and oxygen consumption of these livers were statistically lower than those of ones perfused normothermically (P less than 0.05). In contrast, chemistries of the perfusate of livers perfused hypothermically were comparable to ones perfused normothermically. Histologic examination of the liver perfused hypothermically demonstrated hepatic arterial and/or portal venous congestion and mild-to-moderate hemorrhage in the portal triads. This study suggests that livers preserved for a prolonged period of time demonstrate a high hepatic arterial resistance shortly after revascularization, and that recipient hypothermia after revascularization may be a risk factor for the development of hepatic arterial thrombosis following liver transplantation.     

High-Na + low-K + UW cold storage solution reduces reperfusion injuries of the rat liver graft

The isolated perfused rat liver model was used to assess graft viability after 24 h of cold preservation. Two solutions were compared for liver preservation: Belzer's original UW solution (high-K ⁺ UW) and a solution containing the same components but with inverted concentrations of sodium and potassium (high-Na ⁺ UW). During the 120 min of normothermic reperfusion, livers preserved in the high-Na ⁺ UW solution released lower levels of creatine kinase-BB isoenzyme, transaminases (ALT and AST), and potassium than those preserved in the high-K ⁺ UW solution. Bile flow and biliary excretion of indocyanine green increased when livers were preserved in the high-Na ⁺ UW solution. We found no statistical differences for oxygen consumption and tissue ATP concentration. The results of this study support the concept that a high-Na ⁺ UW solution is a more effective means of preserving rat livers, at least after 24 h of cold-storage and 120 min of reperfusion in the isolated perfused model, than the original high-K ⁺ UW solution. Liver preservation in the high-Na ⁺ UW solution reduces damage to sinusoidal endothelial and hepatocellular cells. The use of an extracellular-like Belzer cold storage solution eliminates potassium-related problems in cold preservation and subsequent normothermic reperfusion while keeping all the qualities of the original UW solution. Received: 26 August 1997 Received after revision: 12 November 1997 Accepted: 28 November 1997     

Enzymatic and morphological evaluation of the hepatic cytoprotective effect of somatostatin and octreotide during extended experimental liver preservation

Cytoprotective effects on the liver of somatostatin (ST) and octreotide (OT) have been previously described in normothermic ischemia-reperfusion models. The purpose of this study was an enzymatic and morphological assessment of hepatic cytoprotective effects during extended cold storage. Rat livers were washed in situ via the portal vein with University of Wisconsin solution (UW) UW+ST, or UW+OT. After 24 or 48 hours of cold ischemia time (CIT), livers were reperfused for 2 hours via the portal vein with oxygenated KHB at 37 degrees C using a nonrecirculating ex situ isolated perfusion system. Levels of aspartate aminotransferase (AST), alanine aminotransferase (ALT), lactate dehydrogenase (LDH), and creatinine kinase (CK) were assessed in the perfusate during ex situ isolated reperfusion. After a 24-hour cold ischemia time (CIT) ALT, LDH, and CK levels were significantly lower (P < .05) in the UW+ST and the UW+OT livers than the UW livers. After 48-hour CIT, AST, ALT, LDH, and CK levels were significantly lower (P < .05) in the UW+ST and the UW+OT livers than the UW livers. Histopathological examination revealed mild differences after 24-hour CIT but an evidently less ischemically damage organ after 48-hour CIT. With the limitations of an in vitro model, ST and OT showed enzymatic and morphological effects during extended liver preservation.     

Correlation of donor nutritional status with sinusoidal lining cell viability and liver function in the rat

We have demonstrated that the sinusoidal lining cell injury sustained by rat liver allografts during hypothermic storage is a critical determinant of graft viability. The present study was designed to examine the effect of donor nutritional status on hepatic microcirculation and graft function. Rat livers from four nutritional groups (group I, fasted; group II, fed; group III, intraperitoneal glucose; and group IV, fed plus intraperitoneal glucose) were excised and stored for 24 hr in Marshall's isotonic citrate solution. Then the livers were perfused under anoxic conditions with trypan blue. The percentage of nonviable SLC in each group was 26.7 +/- 8.1, 24.9 +/- 7.9, 17.6 +/- 6.9, and 5.9 +/- 1.9 in groups I, II, III, and IV respectively; i.e., there was a significant improvement in SLC viability with nutritional repletion in group IV. Electron microscopy was performed on livers from groups I and IV following 30-hr preservation in University of Wisconsin solution and after 16-hr preservation in Marshall's isotonic citrate solution. Biopsies were taken at the end of storage and after 1 hr of reperfusion at 37 degrees C. At the end of preservation group IV livers contained glycogen and had much more normal liver ultrastructure than group I livers. After reperfusion there was partial recovery of normal SLC morphology in both groups and depletion of glycogen in group IV. Liver function was studied on the isolated perfused rat liver system at 37 degrees C following 30-hr storage in UW solution. Transaminase release into the perfusate was significantly lower in nutritionally repleted livers than in livers from fasted animals. A significant reduction in perfusate platelet count occurred only in livers from fasted animals. The results show that nutritional repletion can reduce the injury of cold preservation to both hepatocytes and endothelial cells and improve liver function in the postpreservation period.     

Induction of necrosis and DNA fragmentation during hypothermic preservation of hepatocytes in UW,HTK, and Celsior solutions

Donor cells can be preserved in University of Wisconsin (UW), histidine-tryptophan-ketoglutarate (HTK), or Celsior solution. However, differences in efficacy and mode of action in preventing hypothermia-induced cell injury have not been unequivocally clarified. Therefore, we investigated and compared necrotic and apoptotic cell death of freshly isolated primary porcine hepatocytes after hypothermic preservation in UW, HTK, and Celsior solutions and subsequent normothermic culturing. Hepatocytes were isolated from porcine livers, divided in fractions, and hypothermically (4 degrees C) stored in phosphate-buffered saline (PBS), UW, HTK, or Celsior solution. Cell necrosis and apoptosis were assessed after 24- and 48-h hypothermic storage and after 24-h normothermic culturing following the hypothermic preservation periods. Necrosis was assessed by trypan blue exclusion, lactate dehydrogenase (LDH) release, and mitochondrial 3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyltetrazolium bromide (MTT) reduction. Apoptosis was assessed by the induction of histone-associated DNA fragments and cellular caspase-3 activity. Trypan blue exclusion, LDH release, and MTT reduction of hypothermically preserved hepatocytes showed a decrease in cell viability of more than 50% during the first 24 h of hypothermic preservation. Cell viability was further decreased after 48-h preservation. DNA fragmentation was slightly enhanced in hepatocytes after preservation in all solutions, but caspase-3 activity was not significantly increased in these cells. Normothermic culturing of hypothermically preserved cells further decreased cell viability as assessed by LDH release and MTT reduction. Normothermic culturing of hypothermically preserved hepatocytes induced DNA fragmentation, but caspase-3 activity was not hanced in these cells. Trypan blue exclusion, LDH leakage, and MTT reduction demonstrated the highest cell viability after storage in Celsior, and DNA fragmentation was the lowest in cells that had been stored in PBS and UW solutions. None of the preservation solutions tested in this study was capable of adequately preventing cell death of isolated porcine hepatocytes after 24-h hypothermic preservation and subsequent 24-h normothermic culturing. Culturing of isolated and hypothermically preserved hepatocytes induces DNA fragmentation, but does not lead to caspase-3 activation. With respect to necrosis and DNA fragmentation of hypothermically preserved cells, UW and Celsior were superior to PBS and HTK solutions in this model of isolated porcine hepatocyte preservation.     

Markers of allograft viability in the rat. Relationship between transplantation viability and liver function in the isolated perfused liver

The relationship between transplant viability and liver function has been examined. Wistar rat livers were preserved at 4 degrees C for increasing intervals and then transplanted into Wistar rat recipients. Two critical times were identified, the longest preservation period with 100% transplantation success (4 hr) and the shortest preservation period with 100% transplant failure (8 hr). The comparable critical times were also identified in livers preserved at 37 degrees C (1 hr and 2 hr). Liver functions were studied by the isolated perfused liver technique in other rat livers stored at 4 degrees C or 37 degrees C for the critical times. Two liver function tests, AST and LDH concentration in perfusate, discriminated between viable and nonviable livers across as well as within preservation groups. AST gave the best separation between viable and nonviable livers. Some functions such as ALT concentration in perfusate separated viable from non viable allografts only within preservation groups. Other liver functions were more sensitive to preservation temperature than allograft viability. Oxygen consumption after cold preservation for either critical time was about twice control levels. Urea production was far below control levels in warm-preserved livers but almost normal in cold-preserved livers. Our results indicate that AST release into perfusate can be used as a screening technique to optimize preservation methods, reserving transplantation for confirming the most promising results.     

Seventy-two-hour preservation of porcine liver by continuous hypothermic perfusion with UW solution in comparison with simple cold storage

Porcine livers preserved for 72 hr using continuous hypothermic perfusion (CHP) were studied in order to compare the effects of CHP on energy metabolism with those of simple cold storage (SCS). The livers of the CHP group were perfused in situ for 72 hr at 7 degrees C with University of Wisconsin (UW) solution and FC-43 as an oxygen carrier, while those of the S1 group were stored ex situ for 48 hr at 4 degrees C in UW solution, and those of the S2 group for 72 hr. They were then recirculated with human blood at 37 degrees C for 2 hr for the evaluation of their viability. At the end of preservation, significantly higher levels of total adenine nucleotides (TAN) and energy charge (EC) were observed in the CHP group compared with the S1 and S2 groups. At 2 hr recirculation, the level of TAN was significantly higher in the CHP group than in the S1 and S2 groups. The EC level was also higher in the CHP group than in the S2 group. During recirculation, the ketone body ratio (acetoacetate/beta-hydroxybutyrate) was higher in the CHP group than in the S2 group. The values in the CHP group were above 1.0 after 45 min recirculation. There were no significant differences in the pyruvate/lactate ratio and lactate level between the CHP and S1 groups. However, these values were significantly different from those in the S2 group. The present findings demonstrate that CHP using UW solution and the oxygen carrier was better able to preserve the energy metabolism of the porcine liver for 72 hr than 48-hr SCS in UW solution.     

Effect of ursodeoxycholate in University of Wisconsin solution on long term preservation of rat livers.

OBJECTIVE: To find out whether the addition of ursodeoxycholate (UDC) to University of Wisconsin (UW) solution reduces injury during preservation of the liver. DESIGN: Controlled laboratory study. SETTING: University hospital, Germany. MATERIALS: Preserved livers from 12 rats. METHODS: Livers were flushed with 10 ml of ice-cold (0-1 degrees C) UW or iso-osmolar UW containing 5 mmol/l UDC. After preservation for 30 hours at 0-1 degrees C and 1 hour at 22 degrees C the livers were reperfused for 4 hours. Aspartate amino-transaminase, alanine aminotransferase, glutamate lactate dehydrogenase, and white blood cell (WBC) and platelet counts were measured during reperfusion. Bile flow and total bile salt secretion rate were also measured. RESULTS: Addition of UDC to UW reduced the release of liver enzymes, slightly increased platelet adherence, and reduced bile flow and bile salt secretion rate. CONCLUSION: The membrane-stabilising effect of UDC may explain the reduction in enzyme release. However, liver function, as expressed by bile salt secretion rate and bile flow was adversely affected.     

Comparison of HTK- and UW-solution for liver preservation tested in an orthotopic liver transplantation model in the pig

The aim of this experimental study was to compare the preservation potency of University of Wisconsin (UW) and HTK (Bretschneider) solutions in an orthotopic liver transplantation (OLT) model in pigs. Livers were harvested using an in situ perfusion technique, where organs were flushed with the solution being tested, stored on ice — cold storage (CS) — for 2 or 24 h and then transplanted. Parameters monitored were liver enzymes in serum, hepatic water content, high energy phosphates, nuclear magnetic resonance (NMR) relaxation time T2, light microscopy and bile production. CS for 24 h is an extreme in pig liver preservation and is not compatible with animal survival. Biopsies showed drastic morphological changes and grafts did not produce bile in either group. (Bile production 2 h CS: HTK, 5.6 ± 1.8 ml/h; UW, 4.7 ± 2.3 ml/h) Enzyme release after reperfusion (ASGOT, ?LDH) was higher in long-term preservation. Hepatic tissue water content significantly decreased during CS in UW preserved livers. Edema alter reperfusion (?H₂0: HTK 24 h = + 5.6%, UW 24 h= + 4.8%) and regeneration capacity after reperfusion (UW 2 h = 63%, HTK 2 h = 55%, UW 24 h = 30%, HTK 24 h = 30%) were not significantly different. However, we did not observe major differences in preservation potency between the solutions tested. Differences were correlated, rather, with length 9 time of CS, than with the solution used. Therefore, HTK solution seemed to be a low potassium containing alternative to UW solution.