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     

Delivery of the bioactive gas hydrogen sulfide during cold preservation of rat liver: effects on hepatic function in an ex vivo model

The insults sustained by transplanted livers (hepatectomy, hypothermic preservation, and normothermic reperfusion) could compromise hepatic function. Hydrogen sulfide (H₂S) is a physiologic gaseous signaling molecule, like nitric oxide (NO) and carbon monoxide (CO). We examined the effect of diallyl disulfide as a H₂S donor during hypothermic preservation and reperfusion on intrahepatic resistance (IVR), lactate dehydrogenase (LDH) release, bile production, oxygen consumption, bromosulfophthalein (BSP) depuration and histology in an isolated perfused rat liver model (IPRL), after 48 h of hypothermic storage (4°C) in University of Wisconsin solution (UW, Viaspan). Livers were retrieved from male Wistar rats. Three experimental groups were analyzed: Control group (CON): IPRL was performed after surgery; UW: IPRL was performed in livers preserved (48 h—4°C) in UW; and UWS: IPRL was performed in livers preserved (48 h—4°C) in UW in the presence of 3.4 mM diallyl disulfide. Hypothermic preservation injuries were manifested at reperfusion by a slight increment in IHR and LDH release compared with the control group. Also, bile production for the control group (1.32 µL/min/g of liver) seemed to be diminished after preservation by 73% in UW and 69% in UW H₂S group at the end of normothermic reperfusion. Liver samples analyzed by hematoxylin/eosin clearly showed the deleterious effect of cold storage process, partially reversed (dilated sinusoids and vacuolization attenuation) by the addition of a H₂S delivery compound to the preservation solution. Hepatic clearance (HC) of BSP was affected by cold storage of livers, but there were no noticeable differences between livers preserved with or without diallyl disulfide. Meanwhile, livers preserved in the presence of H₂S donor showed an enhanced capacity for BSP uptake (k_ACON = 0.29 min^?1; k_AUW = 0.29 min^?1; k_AUWS = 0.36 min^?1). In summary, our animal model suggests that hepatic hypothermic preservation for transplantation affects liver function and hepatic depuration of BSP, and implies that the inclusion of an H₂S donor during hypothermic preservation could improve standard methods of preparing livers for transplant.     

Carolina rinse solution--a new strategy to increase survival time after orthotopic liver transplantation in the rat

Recently, we described a new solution, Carolina rinse, that prevents nonparenchymal cell injury in vitro after reperfusion of livers stored in University of Wisconsin cold solution (Currin RT, Toole JG, Thurman RG, Lemasters JJ. Transplantation 1990; 50: 1076). The present study was designed to examine the effect of Carolina rinse on graft survival in vivo. Unlike UW cold storage solution, which is high in potassium, Carolina rinse contains extracellular inorganic ions at levels similar to blood, a calcium channel blocker and a radical scavenger. Carolina rinse also contains fructose and mildly acidotic pH to reduce hypoxic cell death. Livers from Lewis rats were explanted, stored in UW cold storage solution under nonsurvival conditions, and rinsed with either 15 ml of Ringer's, UW solution, Carolina rinse, or Carolina rinse saturated with nitrogen prior to completion of implantation surgery. In the Ringer's rinse group, only 4% of recipients survived 30 days postoperatively. In this group, SGOT levels reached maximal values of about 5000 U/L. Survival was also poor (25%) when grafts were rinsed with UW solution. In the Carolina rinse group, however, 9 of 16 rats (56%) survived indefinitely, and maximal postoperative SGOT levels were reduced 3-fold. Liver injury indexed histologically was also decreased about 3-fold by Carolina rinse compared with the control group rinsed with Ringer's solution. Carolina rinse diminished postoperative sinusoidal endothelial cell damage assessed by electron microscopy and reduced carbon particle phagocytosis due to Kupffer cells significantly. Moreover, Carolina rinse diminished graft swelling and improved postoperative hepatic microcirculation compared with the Ringer's rinse group. Taken together, these results indicate that Carolina rinse is a superior alternative to Ringer's solution in vivo to protect liver grafts from reperfusion injury when removing high-potassium-containing cold storage solutions clinically prior to implantation.     

Reperfusion rather than storage injury predominates following long-term (48 h) cold storage of grafts in UW solution: studies with Carolina Rinse in rat liver

Both storage injury and reperfusion injury have been reported in association with liver transplantation; however, which predominates is not clear. Therefore, these studies were designed to evaluate whether Carolina Rinse, which minimizes reperfusion injury following orthotopic liver transplantation in the rat, would be effective after long-term (48 h) storage of grafts in University of Wisconsin (UW) cold storage solution where sufficient time for development of storage injury exists. Livers were rinsed with either Ringer's solution or Carolina Rinse solution immediately prior to completion of implantation surgery. In the Ringer's group, 30-day survival was high following 24 h of cold storage (4/5) but was very low after 48 h (1/16). Importantly, survival was increased significantly (5/14) when grafts were rinsed with carolina Rinse following 48 h of cold storage. In both groups, parenchymal cells appeared normal by scanning electron microscopy, excluded trypan blue, and released SGOT at values only slightly above the normal range immediately (i. e., less than 5 min) after 48 h of cold storage. However, SGOT values rose steadily during the 1st hour postoperatively following reperfusion in the Ringer's rinse group and reached levels around 1,000 U/1. In addition, non-parenchymal cells were not labelled with trypan blue following storage, but significant labelling occurred within 1 h. Both SGOT release and nonparenchymal cell injury were reduced significantly when grafts were rinsed with Carolina Rinse prior to completion of surgery. Liver injury assessed histologically 24 h postoperatively was also reduced about 50% by Carolina Rinse. Oxidative stress appeared to be involved, since radical adducts, most likely of lipid origin, were trapped during the first 5 min after reperfusion with the spin trapping technique and detected by electron paramagnetic resonance spectroscopy. Lipid radical formation was reduced nearly completely on reperfusion by Carolina Rinse. Since Carolina Rinse improved survival of liver grafts following long periods of cold storage and reduced lipid radical formation and hepatocellular injury, we concluded that a reperfusion injury rather than a storage injury predominates following orthotopic transplantation of livers stored for long periods of time in cold UW solution.     

Cold preservation of the small intestine with the new Celsior-solution

The aim of the present study was to evaluate the potential of Celsior, a recently developed cardioplegic and heart storage solution, to protect the small bowel during ischemic storage. Small bowel segments were isolated from rats, flushed with either UW or Celsior solution, and cold-stored for 18 h at 4 °C in the respective solution. After ischemic storage, some preparations were freeze-clamped for analysis of tissue metabolites while other preparations were tested for structural and functional integrity by isolated perfusion in vitro using a previously validated model. After 18 h of ischemic storage no significant differences were seen between Celsior and UW with regard to the development of edema, energy charge, or creatine phosphate, but lactate accumulation was significantly reduced in the Celsior group, although glucose catabolism was not inhibited. Histological evaluation of the cold-stored organs showed no differences with regard to structural integrity between the two groups. Total vascular resistance upon reperfusion was significantly lower in the Celsior group (666 ± 126 vs 827 ± 88 MPa s m^{–3 *}), as was the intestinal release of LDH (9.7 ± 4.4 vs 18.2 ± 4.6 U/l *). Carbohydrate absorption from the intestinal lumen amounted to venous effluent concentrations of 0.58 ± 0.24 vs 0.18 ± 0.15 mg% ^* of galactose in the Celsior and UW groups, respectively. Within the limits of this in vitro pilot study, Celsior provided better postischemic recovery of the small bowel than UW in terms of vascular perfusion characteristics, enzyme release, and carbohydrate absorption and may, thus, be considered a suitable alternative for intestinal organ preservation. Received: 13 June 1997 Received after revision: 19 September 1997 Accepted: 8 October 1997     

肝移植术中应用S-腺苷-L-蛋氨酸对供肝热缺血损伤的影响

目的探讨术中S-腺苷-L-蛋氨酸（SAMe）加入UW液和血浆冲洗液对热缺血损伤供肝及其恢复的影响。方法建立10min热缺血大鼠肝移植模型，分为A组：UW液灌注＋乳酸钠林格氏液冲洗、B组：UW液灌注＋血浆冲洗、C组：SAMe加入UW液灌注＋血浆冲洗和D组：UW液灌注＋SAMe加入血浆冲洗4组，观察肝组织组织病理学变化和电子显微镜下超微结构变化，并检测血清AST和透明质酸。结果C组和D组术后24h血清AST均低于B组（P〈0．05）。A组术后3h和24h血清HA高于B组（P〈0．05），B组复流后3h及24h血清HA均高于C组和D组（P〈0．05）。组织病理学表现B组复流后3h和24h肝细胞损伤和微循环紊乱较C组和D组明显；超微结构表现，A组复流后3h线粒体肿胀，肝窦内皮细胞肿胀，细胞核不规则，可见内皮细胞凋亡，大部分区域肝窦状隙明显狭窄，内皮层结构模糊，红细胞淤积，受压变形，白细胞附壁，可见内皮层完整性破坏；复流后24h，可见线粒体嵴断裂，核融解。B组内皮细胞损伤较A组轻，C组和D组超微结构表现微循环紊乱和肝细胞损伤表现较B组轻。结论供肝切取术中UW液中加入SAMe灌注保存，血浆冲洗液中加入SAMe可改善热缺血供肝微循环，减轻缺血再灌注损伤，并减轻肝细胞热缺血损伤，有利于10min热缺血供肝功能的恢复。     

Fibrinolytic preflush upon liver retrieval from non-heart beating donors to enhance postpreservation viability and energetic recovery upon reperfusion.

BACKGROUND: Our objective was to evaluate graft equilibration with high viscosity (University of Wisconsin solution [UW]) or low viscosity (Bretschneider's histidine-tryptophan-ketoglutarate [HTK]) during liver procurement from non-heart beating donors (NHBD) and the potential impact of a preceding fibrinolysis with streptokinase on postpreservation viability. METHODS: After 60 min of cardiac arrest, rat livers were perfused by gravity (60 cm H2O) via the portal vein with either 60 ml of HTK, 20 ml of UW, or 20 ml of Ringer's solution (22 degrees C including 7500U of streptokinase) and, subsequently, 20 ml of UW. After 24 h of storage at 4 degrees C, viability of the livers was assessed upon isolated reperfusion in vitro. RESULTS: Magnetic resonance imaging revealed severe perfusion deficits, which were mildly attenuated with HTK, upon flush-out with UW. After preflush with streptokinase, a mostly homogenous distribution of the preservation solution was observed throughout the liver tissue. The choice of the flush-out solution (UW or HTK) had no influence on parenchymal enzyme leakage, hepatic bile production, or tissue levels of ATP after reperfusion of the livers. Fibrinolytic preflush, however, resulted in a relevant and significant improvement of structural integrity as well as functional and metabolic recovery. CONCLUSIONS: Compromised vascular tissue perfusion upon organ harvest in NHBD triggers graft dysfunction after cold storage and can easily be circumvented by temporary fibrinolysis before graft retrieval.     

Evidence that graft survival is not related to parenchymal cell viability in rat liver transplantation. The importance of nonparenchymal cells

Injury to parenchymal and nonparenchymal cells of livers stored in cold Euro-Collins solution was assessed following reperfusion and compared with graft survival following orthotopic rat liver transplantation. Parenchymal cells maintained their viability nearly completely after up to 24 hr of cold storage as assessed by trypan blue exclusion (97% of cells) and LDH release (4% of total) from livers reperfused for 20 min following storage. Furthermore, hepatic glycolysis (rates of lactate plus pyruvate production), oxygen uptake and NADH redox state (lactate:pyruvate ratio) were in the normal range at all time points studied up to 24 hr of cold storage. In contrast, nonparenchymal cells lost viability as assessed from trypan blue staining beginning after 8 hr of storage: 40% were nonviable after 24 hr of storage. Since injury to nonparenchymal cells occurs only upon reperfusion, oxygen radicals may be involved. Accordingly, xanthine and hypoxanthine, substrates for oxygen radical formation, were measured in perfusate upon reperfusion. Both purines accumulated (up to 80 microM) with time of storage and were washed out rapidly (less than 10 min) upon reperfusion. Although parenchymal cell function was in the normal range in livers stored in the cold for 24 hr, liver grafts stored for 6 hr and longer in Euro-Collins solution could not be transplanted successfully. Thus, we conclude that viability of parenchymal cells in liver grafts prior to transplantation is a poor parameter to predict the outcome of transplantation. Therefore, assessment of parenchymal cell energy state (e.g., with 31P NMR and other methods) most likely will not predict survival reliably. On the other hand, nonparenchymal cells lose their viability significantly earlier following storage and reperfusion. These data suggest that preservation of nonparenchymal cell viability is critical for successful liver transplantation.     

Warm flush at 37 °C following cold storage attenuates reperfusion injury in preserved rat livers

Abstract Pretransplant rinse solutions have been shown to reduce reperfusion injury in cold-stored liver grafts, especially at the nonparenchymal level in sinusoidal endothelial cells (SEC). In this study, different rinse temperatures were tested in a rat liver preservation model. Livers were washed out in situ via the portal vein with cold (4°C) University of Wisconsin (UW) solution, and after hepatectomy (t0), were stored for 8,16, or 24 h of cold ischemia time (CIT). After storage, livers were flushed with UW solution at either 4 °C, 20 °C, or 37 °C and reperfused for 90 min (37 °C). Control livers were reperfused at t0 without preflush. Levels of hyaluronic acid (HA), purine nucleoside phosphorylase (PNP), AST, and LDH were measured in the reperfusion medium. Bile production was monitored during reperfusion. At the end of reperfusion, liver biopsies were taken for enzyme histochemistry (5′-nucleotidase and LDH). After 8-h CIT and a flush at 4°C, a release of endogenous HA (-7 %) was observed, whereas uptake of exogenous HA occurred after the 20°C flush (2 %, P = NS) and after the 37°C flush (24 %, p < 0.001). HA release occurred at all three preflush temperatures after the 16-h CIT but was significantly lower when flushed at 37 °C (-10 %) that at 4 °C and 20 °C (-64 % and -17 %, respectively, p =0.05). After the 24-h CIT, the release of endogenous HA increased in the 4 °C and 20 °C preflush groups, but not in the 37 °C group. Levels of PNP and AST increased until the 24-h CIT in all groups but were significantly lower after preflush at 37 °C. Release of LDH did not increase with increasing periods of cold storage in any of the flush series. Compared to control livers, mean bile production during reperfusion was significantly decreased following preflush at 4°C or 37 °C after all periods of CIT. No differences in mean bile production could be demonstrated in the three preflush groups after any period of CIT. LDH activity in liver tissue was best preserved after the 8 and 16-h CIT in combination with the 37 °C preflush, indicating less hepatocellular damage. In conclusion, in cold stored rat livers flushed at 37 °C before reperfusion, SEC and hepatocellular damage is attenuated.     

SPC-100270, a protein kinase C inhibitor, reduced hypoxic injury due to reperfusion following orthotopic liver transplantation in the rat

Abstract Recently, we reported that SPC-100270, a sphingosine derivative and inhibitor of protein kinase C (50–90 μM) in mixed micelle assays, reduced reperfusion injury resulting from hypoxia in a low-flow, reflow model of liver perfusion [8]. Here we report that SPC-100270 has similar beneficial effects following liver transplantation in vivo. Rat liver transplantation was performed using nonarterial and rearterial techniques. Livers from syngenic rats were harvested surgically, prepared with vascular cuffs and a splint, and stored for 24 or 48 h in University of Wisconsin (UW) cold storage solution. Just prior to completion of vascular reconstruction, the organ was rinsed with 3 or 10 ml of Ringer's solution, vehicle, or a solution containing SPC-100270 (up to 500 μM). Following implantation surgery, low doses of SPC-100270 were ineffective at reducing both parenchymal and nonparenchymal cell death, yet significant ( P < 0.05) reductions were observed with 500 μM. Further, nonparechnymal cell viability was improved nearly four fold by the drug. SPC-100270 (500 μM) tended to increase survival following 48 h cold storage in UW solution, but the improvement was not statistically significant. SPC-100270 also did not diminish carbon-centered free radical formation in transplanted livers from alcohol-treated rats. Collectively, these data support the hypothesis that pretreatment of donor livers with an inhibitor of protein kinase C is effective in vivo at reducing reperfusion injury, particularly to nonparenchymal cells, following orthotopic liver transplantation in the rat.     

Effects of warm Carolina rinse on microvascular reperfusion injury in rat liver transplantation

Abstract Recently, it has been demonstrated that the use of both cold Carolina rinse (CR, 4°C) as well as warm Ringer's lactate (RL, 37°C) attenuates microvascular perfusion failure and leukocyte (WBC) accumulation in liver grafts. The aim of this study was to analyse in vivo whether warming of CR can also lead to a reduction in microvascular reperfusion injury in rat liver transplantation. Syngeneic orthotopic liver transplantation, including arterial reconstruction, was performed in male Lewis rats (180–300 g). Livers were stored in University of Wisconsin (UW) solution for 24 h and rinsed with 15 ml CR which was either cold 4 °C ( n = 7) or warm 37 °C ( n = 8) prior to reperfusion. Hepatic microcirculation and WBC accumulation were assessed by intra-vital fluorescence microscopy, and graft function was determined by analysis of bile flow during the 90-min reperfusion period. Warm CR yielded significantly ( P < 0.01) improved sinusoidal perfusion when compared with cold CR; however, the extent of WBC adherence in both sinusoids and postsinusoidal venules did not vary between the groups. In addition, bile flow was slightly increased after warm CR. We conclude that after 24 h of cold storage in UW solution, warming of CR may offer additional benefit in the prevention of microcirculatory reperfusion injury without affecting WBC accumulation.     

Functional and histological comparison of rat liver preserved in University of Wisconsin solution compared with tissue preserved in a novel solution

An isolated perfused rat liver model was used to investigate biochemical and histologic changes during 2 hours of reperfusion after 24 hours of cold storage to compare Leeds solution (LS) with University of Wisconsin solution (UW). Compared with livers stored in UW, those perfused with LS showed significantly higher bile flow and lower enzyme production (P < .05 by 1-way analysis of variance). For example, after 120 minutes, alanine aminotransferase results were: LS 38.9 U/L vs UW 66.8 U/L and bile flows were LS 10.3 μg/15 min/g liver vs UW 9.2 μg/15 min/g liver. Histologically the reticulin breakdown was greater and its reformation slower in UW-preserved livers. Liver tissue was viable in both groups, as shown by the increased glycogen content after reperfusion in both groups, but seen at a higher rate among LS, perfused livers. In conclusion, LS compared favorably with UW to prevent ischemic damage and so could offer an alternative perfusion medium to UW.     

Improved microcirculation by low‐viscosity histidine– tryptophan–ketoglutarate graft flush and subsequent cold storage in University of Wisconsin solution: results of an orthotopic rat liver transplantation model

As previously shown in a model of isolated rat liver perfusion, the combined use of an initial graft flush with low‐viscosity histidine–tryptophan–ketoglutarate (HTK) solution followed by cold storage in University of Wisconsin (UW) solution markedly improved the preservation during an extended cold storage period. In this study, we aimed to transfer our results into an in vivo model of orthotopic rat liver transplantation, and to elucidate the potential mechanism of the improved preservation by focusing on the hepatic microcirculation. Livers were harvested from male Wistar rats. Aortic perfusion with a pressure of 100 cm H₂O was performed with either UW (group UW) or HTK (groups UW and HTK_UW), followed by additional back‐table perfusion with UW (group HTK_UW). After 20‐h cold storage at 4 °C, livers were orthotopically transplanted with reconstructing the hepatic artery. As measured by bile flow and liver enzymes, HTK flush followed by UW storage was superior compared to single use of either UW or HTK solution. The hepatic microcirculation was significantly improved, as shown by the increased percentage of reperfused sinusoids and reduced sinusoidal leucostasis. HTK and UW effectively reduce ischaemia‐reperfusion injury after liver transplantation. By combining the comparative advantages of both solutions, a cumulative effect resulting in an improved preservation was shown. Thus, this mechanism improves microcirculatory reperfusion.     

Warm Carolina rinse solution prevents graft failure from storage injury after orthotopic rat liver transplantation with arterialization

An injury to nonparenchymal cells, characterized by loss of viability of sinusoidal endothelial cells and activation of Kupffer cells, occurs after reperfusion of livers stored for transplantation. Recently, a new solution, Carolina rinse solution, was shown to prevent reperfusion injury to endothelial cells in vitro almost completely and to improve graft survival after orthotopic rat liver transplantation (ORLT) without arterialization. ORLT with arterialization permits longer cold storage of donor livers and more closely models human surgery. Therefore, we evaluated the effects of Carolina rinse solution on graft survival after ORLT with arterialization in syngeneic Lewis rats. Just prior to implantation, donor livers stored in University of Wisconsin (UW) solution were rinsed with 30 ml of Ringer's solution, saline, or Carolina rinse solution at 1°–4°C. In livers stored for 15 h and rinsed with Ringer's or saline solution, long-term graft survival was only 8%. Using Carolina rinse solution containing 1 mmol and 200 mol adenosine per liter, graft survival improved to 40% and 80%, respectively. Graft survival did not improve when using Carolina rinse solution with adenosine omitted or Ringer's solution containing 200 mol adenosine per liter. Livers were also rinsed with Carolina rinse solution containing 200 mol adenosine per liter at 28°–30°C rather than at 1°–4°C. With warm Carolina rinse solution, survival improved further to 100%, 80%, and 50% after 15, 18, and 21 h of storage. After 18 h of storage, light and electron microscopy demonstrated marked denudation of the sinusoidal lining and activation of Kupffer cells in grafts rinsed with Ringer's solution. Use of Carolina rinse solution greatly improved endothelial structure but did not reduce Kupffer cell activation. In conclusion, these findings show that Carolina rinse solution substantially improves graft survival after ORLT with arterialization. Adenosine and warm temperature are important factors contributing to efficacy. A mechanism of protection appears to be prevention of reperfusion-induced endothelial cell injury.     

Cold storage sensitizes hepatocytes to oxidative stress injury

Liver cold storage leads to oxygen free radical production and reperfusion injury. Antioxidants are effective in suppressing reperfusion injury in rat livers when used in the reperfusion medium. However, in clinical liver transplantation their effectiveness is not clear, which may be due to the way they are used (in the recipient). In this study we compare the effectiveness of antioxidants when used in the reperfusion medium versus the cold storage solution in isolated hepatocytes and the isolated perfused liver. Hepatocytes were cold stored in UW solution for 24 h. Oxidative stress, induced by t-butyl hydroperoxide (tBHP), was measured in the presence of one of five different antioxidants – deferoxamine (DFO), dithiothreitol (DTT), trolox, tocopherol, dimethylthiourea (DMTU) – in the reperfusion buffer or UW solution. Efficacy was judged by reduction in membrane damage (LDH release) during rewarming. Also, rat livers were cold stored for 48 h in UW solution ( ± antioxidant) and reperfused ( ± antioxidants). Efficacy was judged by the effect on enzyme release and bile production. Cold storage of hepatocytes for 24 h sensitized them to oxidative stress. The concentration of tBHP required to induce maximal cell death (80 %–90 % LDH release) was reduced from 1.3 mM (fresh cells) to 0.37 mM (LD-50 values). All antioxidants except DMTU suppressed oxyradical-induced LDH release when used in the reperfusion medium, but only DFO was effective when used in the UW solution. In the isolated perfused liver, DFO, DTT, and trolox were effective and suppressed enzyme release when added to the reperfusion buffer, but none were effective when used in the UW solution. We conclude that cold storage sensitizes liver cells to oxidative stress. The most effective antioxidant was the iron chealator, DFO, which was effective in the reperfusion buffer (isolated perfused liver or hepatocytes) but not in the UW solution when tested in the isolated perfused liver. Suppression of reperfusion injury in liver transplantation could be obtained by antioxidant therapy. However, it is unclear how best to deliver the antioxidants to the site of oxyradical generation. Received: 23 December 1996 Received after revision: 14 April 1997 Accepted: 13 May 1997     

Evaluation of a high sodium-low potassium cold-storage solution by the isolated perfused rat kidney technique

The isolated perfused rat kidney (IPK) model was used to assessinitial renal function after 24 h preservation in 3 differentcold storage solutions: EuroCollins (EC), a solution preparedaccording to the formulation of Belzer's solution (High-K⁺ UW)and a high Na⁺-low K⁺ Belzer UW solution (High Na⁺ UW). GFR and FR_Na were measured after 24 h cold storage in each ofthe solutions during 60 min, and were compared to values obtainedin a control group in which renal function was measured immediatelyafter the kidneys had been harvested. ATP and CP were measuredin fresh renal tissue, in kidneys preserved for 24 h in eachsolution, in control IPK, and in reperfused IPK after they hadbeen preserved for 24 h. Main results showed that preservationin either solution caused a dramatic decrease in GFR and inFR_Na within the first 60 min following reperfusion of cold-storedkidneys. However FR_Na was significantly higher in the High-Na⁺UW group. ATP and CP content were decreased to 10% of basalvalues in all experimental groups after cold-storage. Normothermicreperfusion of IPK after cold-storage induced a restorationof ATP levels, but CP content decreased further. There was nosignificant difference in ATP and CP content between cold-storagesolutions, nor any correlation between metabolic and functionalparameters.     

Low viscosity histidine-tryptophan-ketoglutarate graft flush improves subsequent extended cold storage in University of Wisconsin solution in an extracorporeal rat liver perfusion and rat liver transplantation model.

Adequate flushing for liver donation requires large fluid volumes delivered at a high flow. This can be achieved more effectively with crystalloid solutions than with colloid-based solutions. This study examined the combination of initial histidine-tryptophan-ketoglutarate solution (HTK) graft flush and subsequent storage in University of Wisconsin solution (UW) to that of the single use of each solution. Livers from inbred Wistar rats were procured using aortic perfusion with UW or HTK for initial perfusion and reflushed after 30 minutes using either solution. In a third group, after perfusion with HTK, organs were reflushed with UW. A 60-minute in-vitro recirculating perfusion was performed after 24 hours of cold storage in the subsequent solution, as well as allotransplantation after 18 and 24 hours of cold storage. In extracorporeal perfusion, the HTK flush followed by UW storage was superior compared to the single use of either UW or HTK solution, as measured by portal venous pressure, bile flow, liver enzymes released into the effluent perfusate, glycerol leakage, and histological examinations. These data were consistent with the transplantation study. Histological damage and enzyme release after 5-day survival were lowest in the HTK flush and subsequent UW storage groups following 18 hours of cold storage; likewise, the 5-day survival was superior following 24 hours of cold storage. In conclusion, the combined use of HTK solution for initial graft rinse and subsequent storage in UW solution resulted in a cumulative protection. Choosing low-viscosity HTK solution for the initial organ flush may represent a feasible improvement in liver preservation, which also further reduces the required amount of UW solution.     

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.     

自制HYD液对大鼠肝脏低温保存后生化功能影响的研究

目的 研制自制ＨＹＤ液对大鼠肝脏低温保存后生化功能的影响。方法 采用大鼠肝脏非循环离体灌注模型，比较ＨＹＤ液，ＵＷ液和乳酸林格液（ＬＲ液）对大鼠肝脏６，１２，２４，３０，３６ｈ保存后生化功能的影响。结果 保存１２ｈ的肝脏，其各项生化功能ＨＹＤ组明显优于ＬＲ组。三磷酸腺苷，磷酸腺苷含量及Ａｔｋｉｎｓｏｎ能荷（ＡＥＣ），ＨＹＤ组略高于ＵＷ组，且保存３６ｈ差异有显著性。     

Experimental liver preservation with Celsior: a novel alternative to University of Wisconsin and histidine-tryptophan-alpha-ketoglutarate solutions?

Celsior, a low viscosity and low potassium preservation solution, has recently been tested successfully in the cold preservation of heart, lung, kidney and small intestine. The purpose of the present study was to evaluate the potential of Celsior in the cold preservation of the liver. Livers were harvested from male Wistar rats and then flushed with either Celsior (CE), University of Wisconsin solution (UW) or histidine-tryptophan-alpha-ketoglutarate solution (HTK) and stored for 24 h at 4 degrees C in the respective solution. The reperfusion was performed in vitro using a recirculating model with oxygenated (95% O(2), 5% CO(2)) Krebs-Henseleit buffer at 37 degrees C. To simulate the slow rewarming during the surgical implantation in vivo, all livers were stored for 30 min at room temperature prior to reperfusion. After ischemic storage and also after reperfusion some samples were freeze-clamped for analysis of tissue metabolites while others were tested for structural and functional integrity by the isolated perfusion. CE vs. UW vs. HTK: Metabolic preservation of tissue ATP (micromol/g dry weight) during cold storage was best with Celsior (0. 46 +/- 0.17 vs. 0.26 +/- 0.03 vs. 0.35 +/- 0.07; p < 0.05 CE vs. UW), but upon reperfusion energetic recovery was comparable in the three groups (3.45 +/- 0.66 vs. 4.27 +/- 0.41 vs. 3.63 +/- 0.64 micromol/g/dry weight). There appeared to be structural integrity during reoxygenation irrespective of the used preservation solution with comparable values of parenchymal enzyme release (ALT: 575 +/- 82 vs. 547 +/- 106 vs. 593 +/- 38 mU/g/l), bile production (18.0 +/- 1.0 vs. 18.5 +/- 2.5 vs. 18.7 +/- 1.4 microl/g/ min), and the release of acid phosphatase, an indicator for activated Kupffer cells (89 +/- 13 vs. 90 +/- 5 vs. 123 +/- 21 mU/g/l) in this in vitro model. Vascular flow characteristics were approximated by the portal perfusion pressure, which tended to be elevated upon initial reperfusion in the UW group (8.4 +/- 0.6 mm Hg) compared to 6.6 +/- 1.0 and 7.3 +/- 0.4 mm Hg in Celsior and HTK, respectively. However, the pressure values decreased to the normal range even in the UW group with ongoing perfusion. The sensitivity of our model in detecting protective effects of the tested solution was confirmed by a negative control group of livers stored in Ringer's solution at 4 degrees C, yielding an impaired recovery which differed by one magnitude from the three other groups. Within the limits of an in vitro study it is concluded from these results that Celsior may become a suitable alternative for liver preservation and further studies including a transplantation in vivo are strongly encouraged.