The impact of liver preservation in HTK and UW solution on microcirculation after liver transplantation

Severe microcirculatory disturbances due to endothelial cell damage and leukocyte adherence during reperfusion of transplanted livers are considered to contribute to early graft failure. Since the degree of reperfusion injury after liver transplantation depends on the length of preservation time and the solution used for preservation, the aim of our study was to assess three solutions with respect to microvascular perfusion and leukocyte adhesion. Therefore, rat livers were stored up to 24 h in Euro-Collins (EC), University of Wisconsin (UW), or histidin-tryphtophan-ketoglutarate (HTK) solutions prior to orthotopic transplantation. The livers were studied in situ 60 min postoperatively using intravital fluorescence video microscopy. Using simple syringe flushing (10 ml), sinusoidal perfusion decreased below 50% in EC preserved livers after 8 h preservation, in HTK preserved livers after 16 h preservation, and remained higher than 70% in livers preserved in UW up to 24 h. Permanent adhesion of leukocytes was increased more rapidly in organs after 1, 8, 16, and 24 h preservation in HTK (16%, 15%, 34%, and 49.7% ± 4.7%) compared to those preserved in UW (15%, 18%, 17%; and 32.7% ± 3.3%; P < 0.05). Using a 10-fold volumn of the organ weight of HTK solution during the harvesting procedure, with an 8 min equilibration period, sinusoidal perfusion (39.6 ± 4.7%) and leukocyte adhesion (42.7 ± 3.1%) were not improved after 24 h. In contrast, equilibration with a volumn of approximately 40-times the liver weight improved sinusoidal perfusion (70.8% ± 2.7%; P < 0.01) and leukocyte adhesion (24.9% ± 3.1%; P < 0.01) significantly. Thus, using HTK solution, simple flushing prior to long-term cold storage resulted in microcirculatory disturbances when compared to UW solution. Larger volumns of HTK solution with an additional equilibration period of 8 min, however, reduced leukocyte adhesion and improved sinusoidal perfusion to a similar degree as UW solution.     

UW is superior to Celsior and HTK in the protection of human liver endothelial cells against preservation injury.

Celsior solution (CS), a new preservation solution in thoracic organ transplantation, was evaluated for its efficacy in cold preservation of human liver endothelial cells (HLEC) and was compared to University of Wisconsin solution (UW) and histidine-tryptophan-ketoglutarate solution (HTK, Custodiol). HLEC cultures were preserved at 4 degrees C in CS, UW, and HTK, for 2, 6, 12, 24, and 48 hours, with 6 hours of reperfusion. Levels of lactate dehydrogenase (LDH), 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT), and adenosine 5'-triphosphate (ATP) were measured after each interval of ischemia and the respective phase of reperfusion. Preservation injury of HLEC as measured by LDH release, intracellular ATP level, and MTT reduction were overall significantly (P CS > HTK.     

Celsior solution compared with University of Wisconsin solution (UW) and histidine–tryptophan–ketoglutarate solution (HTK) in the protection of human hepatocytes against ischemia–reperfusion injury

Celsior, a new preservation solution in thoracic organ transplantation was evaluated for efficacy in cold preservation of human hepatocytes and compared with University of Wisconsin solution (UW) and histidine-tryptophan-ketoglutarate solution (HTK, Custodiol). Human hepatocyte cultures were preserved at 4 degrees C in Celsior, UW and HTK for 2, 6, 12, 24 and 48 h with 6 h of reperfusion. Levels of lactate dehydrogenase (LDH; cell necrosis), 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT; mitochondrial function), and adenosine 5'-triphosphate (ATP; loss of intracellular energy) were measured. Cell necrosis, mitochondrial dysfunction, and loss of ATP were significantly ( P<0.001, P<0.001, P<0.002, respectively) lower in Celsior than in HTK. The amount of cell necrosis and mitochondrial dysfunction in Celsior solution (CS) and UW was equal ( P=n.s.) up to 24 h and significantly lower in UW after 48 h ( P<0.001). Additionally, the intracellular level of ATP was significantly higher after ischemia ( P<0.001) and reperfusion from long-term ischemia (24, 48 h) ( P<0.002). We can conclude that Celsior was superior to HTK and equal to UW in the protection of human hepatocytes against cold preservation injury from ischemia and reperfusion. Furthermore, Celsior was effective in long-term preservation of human hepatocytes.     

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.     

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.     

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.     

体外持续肝脏灌注常温保存和HTK液低温保存无心跳供肝效果的比较

目的 比较应用组氨酸-色氨酸-酮戊二酸(HTK)液低温保存和体外持续肝脏灌注(ECLP)系统常温保存无心跳供肝的效果.方法 按保存方法不同将供肝随机分为A组和B组:供肝切取后,A组用HTK液在低温下保存10 h;B组用ECLP系统在常温下用稀释的自体血液持续灌注10 h.两组供肝再经过60 min冷缺血期后,连接ECLP系统用稀释的自体血液再灌注4 h.观察再灌注后1、2、3、4 h四个时间点的胆汁分泌量,门静脉和肝动脉的压力,肝脏耗氧率的变化,灌注液中丙氨酸转氨酶(ALT)、乳酸脱氢酶(LDH)、葡萄糖水平以及灌注后供肝的常规病理和超微病理变化.结果 B组再灌注后1、2、3、4 h时间点的胆汁分泌量,门静脉和肝动脉的压力,灌注液中ALT、LDH和葡萄糖水平,以及2、3、4 h时间点的耗氧率与A组比较,差异均有统计学意义(P＜0.05或P＜0.01);B组供肝的病理损害程度较A组轻.结论 供肝切取后10 h内,利用ECLP系统持续灌注常温保存比用HTK液单纯低温保存在维持无心跳供肝的功能和生理活性方面效果更好.     

Protective effects of ambroxol in hypothermic liver preservation: a transplant study.

The bronchosecretolytic agent ambroxol added to histidine-tryptophan-ketoglutarate (HTK) solution has recently been shown to protect cold stored rat hepatocytes. The aim of the present study was to confirm these observations in a rat liver transplantation model. Before orthotopic liver transplantation, donor livers from 30 syngeneic Wistar rats were assigned to three groups (n = 10): (A) in situ flush (ISF) and 1/2-h cold storage (CS) with HTK solution, (B) ISF and 3-h CS with HTK, and (C) ISF and 3-h CS with HTK + 10(-3) mol/L ambroxol. The efficacy of the drug was evaluated by postoperative survival (> 14 days) and liver enzyme release (ALT), bile flow, histomorphological injury, and malondialdehyde (MDA) level in the grafts 15 min after reperfusion. After 1/2-h CS with HTK solution (A), 90% of the transplanted rats survived. In comparison with donor conditions, bile flow in the reperfused grafts decreased to 87 +/- 5.3%, whereas postoperative ALT levels slightly increased. After 3-h HTK preservation (B), the survival rate decreased to 60%, while ALT values markedly increased and bile flow after reperfusion declined to 82 +/- 6.6%. Ambroxol added to HTK solution (C) enhanced bile flow to 106 +/- 3.4%(p < .05), and reduced ALT and MDA levels and histomorphological injury of the transplanted livers, so that its beneficial effect in organ preservation has been confirmed in the transplant model. However, survival rate was not improved by the agent, probably because of the low cold ischemia tolerance of the Wistar rat livers used.     

Value of energy substrates in HTK and UW to protect human liver endothelial cells against ischemia and reperfusion injury

Adenosine 5'-triphosphate (ATP) depletion is a major cause of cellular injury during ischemia and reperfusion in organ transplantation. Therefore, histidine-tryptophan-ketoglutarate solution (HTK; alpha-ketoglutarate) and University of Wisconsin solution (UW; adenosine) were supplied with energy substrates to achieve graft viability. Nevertheless, their efficacy for maintaining the ATP level, particularly in human liver endothelial cells, was uncertain. Furthermore, it is of interest whether a high ATP level is beneficial in human liver endothelial cell viability. We used human liver endothelial cells between the 3rd and 6th passages in a cell culture model. Human liver endothelial cells were exposed to hypothermic preservation (4 degrees C) in HTK and UW for 2, 6, 12, 24 and 48 h with subsequent reperfusion of 6 h. ATP and lactate dehydrogenase (LDH) were measured after each interval. In comparison to HTK, UW demonstrates a statistically significantly higher level of ATP after each interval of ischemia (p < 0.001) and reperfusion (p < 0.002). Additionally, UW-preserved human liver endothelial cells exceed the ATP level of the warm control during all intervals of ischemia. The loss of cell viability (LDH) was statistically significantly higher after ischemia (p < 0.01) and reperfusion (p < 0.01) in HTK than in UW except after the interval of 48 h. In conclusion, adenosine was more effective than alpha-ketoglutarate in maintaining a high ATP level in human liver endothelial cells after ischemia and reperfusion. Different pathways of energy substrate utilization were a contributing factor. The beneficial effect of the higher ATP level caused by adenosine to human liver endothelial cell viability was limited to 24 h of ischemia. Beyond this ischemia time we could not prove a favorable impact of adenosine on human liver endothelial cells.     

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.     

自制CMU-1液保存大鼠肝脏的实验研究

目的　探讨CMU 1液保存大鼠肝脏的效果。方法　根据灌注液和保存液的种类将Wistar大鼠分为两组 :UW组和CMU 1组 ,每组分 6h、12h、2 4h 3个保存时限 ,每亚组 6只大鼠。采用离体循环灌注模型 ,研究CMU 1保存液对保存肝脏能量代谢、生化功能、胆汁分泌及形态学方面的影响。结果　随着保存时间延长 ,肝组织TAN含量及AEC逐渐降低 ,CMU 1组较UW组下降略缓慢 ,保存 2 4h后高于UW组 (P <0 0 5 )。再灌注 12 0min后CMU 1组的肝脏分泌胆汁量较UW组多 (P <0 0 5 )。相同时限相比 ,灌出液中ALT、LDH值两组之间无显著差异 (P >0 0 5 )。肝脏组织学变化两组间无明显差异。保存 6h后 ,保存液pH值无明显变化 ;保存 12h后pH值下降 ,两组无明显差异 ;保存2 4h后 ,UW组pH值下降较CMU 1组明显。结论　CMU 1保存液保存大鼠肝脏效果与UW液相似 ,在改善保存肝脏能量代谢、预防细胞内酸中毒、胆汁分泌方面略优于UW液。     

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.     

Greater Hemodynamic Instability With Histidine-Tryptophan-Ketoglutarate Solution Than University of Wisconsin Solution During the Reperfusion Period in Living Donor Liver Transplantation

Objective

University of Wisconsin (UW) and histidine-tryptophan-ketoglutarate (HTK) solutions are the 2 most commonly used liver preservation solutions. The aim of this study was to compare cardiovascular stability, acid-base status, and potassium concentrations between patients who received grafts preserved in either UW or HTK solution in orthotopic liver transplantation (OLT).

Patients and Methods

In this retrospective study, 87 patients who underwent living donor OLT were divided into 2 groups: UW (n = 28) and HTK (n = 59). Group HTK was subdivided into group NF-HTK (n = 31; nonflushed before reperfusion) and group F-HTK (n = 28; flushed before reperfusion). We determined mean arterial pressure (MAP) and heart rate every minute for 5 minutes after reperfusion and the maximum change in these values and incidence of postreperfusion syndrome (PRS). Body temperature, cardiovascular and acid-base parameters, as well as potassium concentrations were compared at 5 minutes before and 5 and 30 minutes after reperfusion.

Results

The maximum decreases in MAP within 5 minutes after reperfusion were significantly greater in both the NF-HTK and the F-HTK groups. The rate of PRS was significantly greater in the NF-HTK compared with the UW group. Flushing with HTK solution decreased the rate of PRS; there was no significant difference between the F-HTK and UW groups. All serial changes in body temperature, cardiovascular and acid-base parameters, as well as potassium concentrations were similar among the 3 groups.

Conclusions

The incidence of PRS was greater using HTK compared with UW solution during the reperfusion period. Therefore, careful hemodynamic management is advised when using HTK solution.     

Physiologic and metabolic results of pancreatic cold storage with Histidine-Tryptophan-Ketoglutarate-HTK solution (Custodiol)® in the porcine autotransplantation model

Delayed graft function (DEGF) remains an obscure phenomenon in organ transplantation. For the optimal washing of the compounds of the different organ flush solutions, adequate temperature and equilibrium of electrolytes have to be provided. A total of 29 landrace pigs weighing 37.3–5.4 kg were included in this study. According to the model, the left hemipancreas was perfused with Histidine-Tryptophan-Ketoglutarate (HTK)-solution and autotransplanted after 24 h (G1, n = 13) and 48 h (G2, n = 4) of cold storage (CS). Results were compared with grafts perfused with UW-solution and autotransplanted after 24 h (G3, n = 8) and 48 h (G4, n = 4) CS respectively. Daily measurements of glycemia, glucosuria, amylase and lipase were carried out. HTK perfusion resulted in an increase in wet weight of the grafts after 24 h and 48 h CS (P = 0.031 vs UW). Postoperative glycemia levels in pancreases flushed with HTK-solution were higher after 48 h than after 24 h CS until the 6th postoperative day, when the glycemia returned to normal range (P = 0.02), suggesting a delayed endocrine graft function. The mean IVGTT values attained after full function were comparable in G1 and in G3 (–1.22 ± 0.23 vs. –1.5 ± 0.65). The rises in serum amylase and lipase levels were more pronounced after 48 h CS in both HTK and UW groups, (P = n.s.). Appearance of interstitial and intracellular edema after CS and reperfusion did not influence the function.¶Conclusion: HTK-solution is suitable for 24 h pancreatic preservation in vivo; the perfusion requires at least 4 min for electrolyte equilibration. Long preservation time (48 h) resulted in a transitory DEGF.     

Celsior液与UW液对无心跳大鼠供肝保存效果的比较

目的 比较Celsior(CS)液与UW液对大鼠无心跳供者(NHBD)供肝的保存效果.方法 选取健康雄性SD大鼠作为肝移植的供、受者.通过阻断大鼠主动脉和膈上下腔静脉10 min的方法,制备和获取NHBD供肝,并采用不同的器官保存液灌注和冷保存供肝.随机将受者分为4组.CS8 h组:受者采用经CS液灌注和冷保存8 h的供肝移植;UW8 h组:受者采用经UW液灌注和冷保存8 h的供肝移植;CS16 h组:受者采用经CS液灌注和冷保存16 h的供肝移植;UW16 h组:受者采用经UW液灌注和冷保存16 h的供肝移植.受者门静脉开放前、开放后1、3及6 h,取各组受者的静脉血检测血清丙氨酸转氨酶(ALT)、天冬氨酸转氨酶(AST)、内皮素1(ET-1)、白细胞介素1(IL-1)及肿瘤坏死因子α(TNF-α)水平;观察和比较各组受者的胆汁生成量、移植肝组织病理学改变及术后7 d内的存活率.结果 NHBD供肝经UW液灌注后呈"花斑"状,肝叶边缘灌注不良,经CS液灌注后肝叶边缘灌注良好.CS8 h组和UW8 h组受者的胆汁生成量分别为(0.21±0.01)ml和(0.10±0.02)ml(P<0.05).门静脉开放后1、3及6 h,CS8 h组受者的血清ALT及AST水平明显低于UW8 h组(P<0.05),门静脉开放后1、3h,CS8 h组受者的血清ET-1、IL-1及TNF-α水平均明显低于UW8 h组(P<0.05);CS8 h组受者移植肝肝窦扩张、门静脉充血及炎症细胞浸润等病理学改变明显轻于UW8 h组,CS8 h组和UW8 h组受者术后7 d的存活率分别为58.3%和25.0%(P<0.05).CS16 h组和UW16 h组受者各时点的胆汁分泌量、血清ALT、AST、ET-1、IL-1及TNF-α水平的比较,差异均无统计学意义(P>0.05),两组受者均在术后3 d内死亡,两组受者移植肝组织病理学改变无明显差异.结论 CS液对大鼠NHBD供肝的保存效果优于UW液,这可能与UW液较CS液粘稠及CS液能够减少枯否细胞的激活有关;NHBD供肝的冷保存时间不宜超过16 h.     

Evaluation of preservation solutions by ESR-spectroscopy: superior effects of University of Wisconsin over Histidine-Tryptophan-Ketoglutarate in reducing renal reactive oxygen species

Despite the causative role of oxidative stress in renal ischemia-reperfusion (I-R) injury effects of preservation solutions on reactive oxygen species (ROS) release have not been sufficiently evaluated. We compared the effects of most common solutions in kidney transplantation, University of Wisconsin (UW) and Histidine-Tryptophan-Ketoglutarate (HTK). ROS formation in isolated perfused rat kidney was detected by electron spin resonance spectroscopy using spin label 1-hydroxy-3-methoxycarbonyl-2,2,5,5-tetramethyl-pyrrolidine. Donor kidneys from Lewis rats were pretreated with saline (controls), in therapeutic groups, kidneys underwent 18 h of cold storage (CS) preserved by HTK or UW solution. Experimental protocol included a stabilization period followed by additional I-R. Kidneys preserved by HTK produced highest ROS values in the control period after CS, whereas levels in UW and control group did not vary significantly. A peak release induced by additional I-R was also significantly highest in HTK kidneys, and UW did not differ from controls. During reperfusion, levels in HTK exceeded control and UW values. Renal vascular resistance, caspase-3-activity, and tissue hydration were enhanced in HTK compared with UW group, whereas ATP concentration was less reduced in UW-preserved tissue. These data show the greater antioxidative potential of UW solution, which also attenuated organ impairment after CS in the early reperfusion period.     

Evaluation of a Novel Cold Storage Solution (HBS) in a Rat Kidney Transplant Model

We developed an improved solution for hypothermic storage (0–4°C) of kidneys. The cold storage solution (HBS) was composed of macromolecules, high-energy cellular substrates, and a mixture of antiproteolytic amino acids, antioxidants, and anti-inflammatory compounds. The objectives in developing this solution were to achieve superior metabolic support of the kidney during cold storage and to protect against ischemic injury. Inbred Brown Norway rats, weighing 225–250 g, were subjected to orthotopic ultrarapid technique for kidney isotransplantation to minimize warm ischemia and to test the preservation process. The kidney was transplanted after 12 h of preservation. The animals were divided into three groups based upon the preservation solution utilized: HBS solution, HTK solution (Custodiol), and UW solution (UWS)(ViaSpan). Among the recipients, each group had two subsets. The first subset of animals was used to assess survival at 7 days as well as the reperfusion damage index (RDI) based on the macroscopic physical characteristics of the kidney at the time of transplantation. The second subset in each group was utilized to measure serum creatinine and blood urea nitrogen at 4 and 7 days, and histology at death or sacrifice. Mean ± standard deviation (M ± SD) was used for all parameters studied. The HBS solution showed significantly better protection at 12 h when compared to HTK and UW solutions. The reperfusion damage index (RDI) showed excellent preservation in the HBS (14 ± 1), good preservation in UWS (13 ± 1.5), and moderate preservation in the HTK (11 ± 2) group. Histology was in concordance with the RDI, showing better histological findings with HBS and UW solutions than with the HTK group. Serum creatinine was significantly better in the HBS group when compared to HTK and UWS. Survival was statistically different, with 80% survival at 7 days in the HBS group, 20% survival in the HTK group, and 50% survival in the UWS group (p <. 05). The HBS solution offered a new alternative for kidney cold storage with significantly better results when compared to the current gold standards of HTK and UW solutions in Brown Norway rats. This solution warrants further testing in other mammals.     

Randomized clinical assay for hepatic grafts preservation with University of Wisconsin or histidine-tryptophan-ketoglutarate solutions in liver transplantation

University of Wisconsin (UW) solution has been the standard for preservation of liver transplantation grafts since 1989. However, some studies demonstrated that histidine-tryptophan-ketoglutarate (HTK) solution is also effective. The purpose of this study was to compare the efficacy of both solutions in liver transplantation. From January 2003 to August 2004 the livers of deceased donors were randomized into HTK and UW groups. The 102 studied patients included 65 (63.7%) in the UW group and 37 (36.3%) in the HTK group. Sex, race, hemodynamic state, use of adrenergic drugs, and presence of steatosis in the donor were similarly distributed in the two groups (P > .05). The mean age of the donors was 38.1 years (SD +/-14.4) in the UW group and 44.6 years (SD +/-14.2) in the HTK cohort (P = .036). Sex, race, age, etiology of the cirrhosis, retransplant, acute liver failure, portal thrombosis, and Child-Pugh and MELD scores in the recipients were similarly distributed in the two recipient samples (P > .05). Among 89 patients who completed 4 months of follow-up, the HTK group included eight cases (25.8%) of biliary complications versus five cases (8.6%) in the UW group (P = .033; OR = 2.0 95% CI = 1.2-3.5). The incidence of graft dysfunction was 2.8% in the HTK group and 9.4% in the UW group (P = .15). In conclusion, UW and HTK solutions were equally effective for the preservation of the hepatic graft. The routine use of HTK solution can reduce the costs of liver transplantation.     

Comparison of histidine-tryptophan-ketoglutarate (HTK) solution versus University of Wisconsin (UW) solution for organ preservation in human liver transplantation

Over a 30-month period, 60 patients (30 in each group) suffering from end-stage liver disease or primary hepatic malignancy and scheduled for liver transplantation were enrolled in a prospective, randomized study to compare two methods of liver preservation: histidinetryptophan-ketoglutarate (HTK) solution versus University of Wisconsin (UW) solution. Entry criteria for both groups were: age (18–65 years), elective surgery (transplantable or urgent category of the recipients), first transplantations and harvesting procedure performed by the same team. The parameters under investigation were the clinical and laboratory data preand post-transplantation, as well as follow-up data such as complications and survival. There were no significant differences in the two groups as far as the evaluation criteria were concerned, even when cold ischemia time was more than 15h (n=7). A slight, yet not significant, increase in late complications of the biliary anastomoses could be seen in the UW group. Hepatocellular injury (SGOT, SGPT, GLDH, lactate) appeared to be more marked in the HTK group. These results suggest that both HTK and UW solutions are appropriate for clinical use in liver transplantation, even if cold ischemia time is more than 15h.     

Histidine-tryptophan-ketoglutarate versus University of Wisconsin solution in living donor liver transplantation: Results of a prospective study

The grafts obtained from a living donor hepatectomy are perfused on the back table with either University of Wisconsin solution (UW) or histidine-tryptophan-ketoglutarate solution (HTK). The efficacy and safety of these solutions have been studied in cadaveric liver transplantation, however, there is no study comparing the two solutions in adult-to-adult living donor liver transplantation. In this study, UW and HTK were used in the perfusion of right living donor grafts. The grafts were perfused with a predetermined sequence and volume of one of the solutions. Liver biochemistries, complications, and graft and patient survival were analyzed. From January 2001 to September 2002, 30 grafts were alternately perfused with either UW (UW group) or HTK (HTK group). The perfusion was performed first via the artery and then via the portal vein with a predetermined volume. At a mean follow-up of 13 ± 7 months, no significant statistical difference between groups UW and HTK in posttransplantation liver biochemistries, complications, or patient and graft survival (84% and 80%, respectively) was observed. In conclusion, UW and HTK are equally effective and safe in the perfusion of the living donor liver grafts. HTK has a slight practical advantage over UW because it does not need to be flushed away before reperfusion of the graft and is less expensive. (Liver Transpl 2003;9:822-826.)