Altered ATP-dependent mitochondrial Ca2+ uptake in cold ischemia is attenuated by ruthenium red

BACKGROUND: Graft dysfunction as a result of preservation injury remains a major clinical problem in liver transplantation. This is related in part to accumulation of mitochondrial calcium (Ca(2+)), which has been linked to activation of proapoptotic factors. We hypothesized that cold ischemia increases mitochondrial Ca(2+) uptake in a concentration dependent fashion and that ruthenium red (RR) will attenuate these changes by inhibiting the mitochondrial Ca(2+) uniporter. METHODS: Rat livers perfused with cold University of Wisconsin (UW) solution (4 degrees C) with or without RR (10 microM) via the portal vein (n = 3 per group) were processed immediately (no ischemia) or after 24 h cold-storage (24 h cold ischemia). Mitochondria were separated by differential centrifugation, and adenosine triphosphate (ATP)-dependent (45)Ca(2+) uptake was determined in the presence of ATP (5 mM), adenosine diphosphate (ADP), or adenosine 5'-beta,gamma-imidotriphosphate (AMP-PNP); variable concentrations of extramitochondrial (45)Ca(2+) were used. All measurements were performed in triplicate. Student's t test with P < 0.05 was taken as significant. RESULTS: Our data demonstrate the following: 1) ATP-dependent (45)Ca(2+) uptake in mitochondria separated from livers following 24 h of cold ischemia in UW alone was higher than in mitochondria isolated from non-ischemic livers; the increased uptake was dependent on the concentration of (45)Ca(2+) in the incubation buffer. 2) There was no difference in ATP-dependent (45)Ca(2+) uptake between nonischemic mitochondria and those separated from livers stored in UW-RR for 24 h. 3) (45)Ca(2+) uptake in mitochondria from livers subjected to 24 h of cold ischemia in UW-RR was significantly lower compared to those from livers stored in UW alone when (45)Ca(2+) concentrations were greater than 1 microM. CONCLUSION: 1) Cold ischemia affects mitochondrial Ca(2+) handling, especially when it is challenged by high extramitochondrial Ca(2+) concentrations. 2) The addition of RR in preservation solution attenuates the effects of cold ischemia on mitochondrial Ca(2+) handling. 3) Inhibition of mitochondrial Ca(2+) uniporter with RR protects mitochondria from Ca(2+) overload at high Ca(2+) concentrations. These findings may offer a potentially effective strategy for prevention of ischemia-reperfusion injury in liver transplantation.     

大鼠供肝冷保存时间延长损伤移植肝肝细胞和肝窦内皮细胞

目的 探讨供肝冷保存时间与肝移植后肝细胞和肝窦内皮细胞（SEC）损伤的关系。方法 选取健康雄性SD大鼠作为供、受者，建立原位肝移植（OLT）模型。随机分为3组，冷保存1h组（H=48）：供肝获取后，置于4C的冷保存液中保存1h，再行OLT。冷保存12h组（n=48）：供肝获取后，置于4℃的UW液中保存12h，再行OLT。对照组（H=6）：大鼠只打开腹腔，不进行移植。前2组分别于术后1、6、12、24、48、72、96和168h采取血液及组织标本，对照组仅在开腹时取血液及组织标本，检测各组、各时点血清丙氨酸转氨酶（ALT）、天冬氨酸转氨酶（AST）及透明质酸（HA）的水平；观察移植肝的病理形态学变化，透射电镜观察其超微结构改变；原位末端脱氧核糖核酸转移酶标记法（TUNEL）检测移植肝细胞的凋亡情况；观察术后168h时的大鼠存活率。结果 冷保存1h和冷保存12h组肝移植后各时点血清ALT、AST及HA均较对照组明显升高（P〈0．05），并且冷保存12h组又明显高于冷保存1h组（P〈0．05）。冷保存12h组术后24h移植肝组织出现片状坏死，而冷保存1h组病理学改变不明显。冷保存12h组肝窦内皮细胞凋亡指数（AI）明显高于冷保存1h组（F=63．58，P〈0．01），两组大鼠移植肝组织均于术后6h出现凋亡高峰，且肝窦内皮细胞的凋亡指数明显高于肝细胞。冷保存1h组和冷保存12h组大鼠肝移植后168h时的存活率分别为100％和50％，两组比较，差异有统计学意义（F=6．39，P〈0．05）。结论 肝移植后肝细胞和肝窦内皮细胞的损伤程度与冷保存时间密切相关。肝窦内皮细胞对冷保存及再灌注损伤的敏感性高于肝细胞，其损伤方式以细胞凋亡为主。     

ET-Kyoto solution plus dibutyryl cyclic adenosine monophosphate is superior to University of Wisconsin solution in rat liver preservation

ET-Kyoto solution (ET-K) is an extracellular-type organ preservation solution containing the cytoprotective disaccharide, trehalose. A previous study reported the supplement of dibutyryl cyclic adenosine monophosphate (db-cAMP) in conventional ET-K to attenuate lung ischemia-reperfusion injury. In this study, the efficacy of this modified ET-K for liver preservation was investigated by comparison with University of Wisconsin solution (UW). ET-K was supplemented with db-cAMP (2 mmol/L). Lewis rats were randomly assigned to two groups, and liver grafts were flushed and stored at 40C for 24 h with ET-K or UW before syngeneic liver transplantation. The graft function and histological changes at 4 h posttransplant as well as 7-day survival were evaluated. Recipient rat survival rate was significantly higher in the ET-K group than in the UW group. Preservation in ET-K resulted in a significant reduction in serum parenchymal transaminase level and promotion of bile production in comparison with UW. The serum hyaluronic acid level, an indicator of sinusoidal endothelial cell injury, was significantly lower after ET-K preservation than that in UW. Histologically, at 4 h after transplantation, the liver grafts preserved in UW solution demonstrated a greater degree of injury than those in ET-K, which appeared to be apoptosis, rather than necrosis. The continuity of the sinusoidal lining was better preserved in ET-K than in UW. In conclusion, ET-K supplemented with db-cAMP is superior to UW in rat liver preservation. This modified ET-K might therefore be a novel candidate for the procurement and preservation of multiple organs.     

Extended preservation and effect of nitric oxide production in liver transplantation

Abstract Liver transplantation (Ltx) has become a routine procedure for patients with enD-stage liver disease. Despite ongoing progress on short- and long-term graft survival, primary dysfunction (PDF) remains a major problem. PDF is significantly associated with the duration of cold ischemia- and, possibly, with reperfusion-related injury. Nitric oxide (NO) has many physiological functions and plays an important role in modulating tissue injury. However, the mechanism of NO action in ischemia/reperfusion injury after Ltx is thus far unknown. In this study we investigated the role of inducable NO synthase (iNOS) in the liver after preservation with UW solution using the orthotopic Ltx model in the rat. Male Brown Norway rats were used for the Ltx procedure. After donor hepatectomy, livers were stored on ice-cold UW solution for 24 or 40 h and subsequently transplanted. A control group consisted of rats with Ltx after less than 1 h storage. Post-transplant blood samples were taken at 48 h to determine standard parameters for liver injury (aspartate transaminase, lactate dehydrogenase). Liver biopsies were obtained for detection of expression of iNOS (western blot) 24 and 48 h post-transplant. We observed that a preservation time of 24 h in UW solution presents no problem for graft survival after Ltx in rats with some brain function and in healthy animals. After 40 h preservation, liver damage is obvious and graft survival reduced, indicating the limits of cold storage may be within reach. With longer preservation times, more NOs was detected in liver tissue. This finding suggests that NO has a role in ischemia/reperfusion-related injury. Current intervention with NOS inhibitors will reveal whether NO has a negative or a positive effect on graft survival after Ltx.     

Protection Against Ischemia/Reperfusion Injury in Cardiac and Renal Transplantation with Carbon Monoxide, Biliverdin and Both

Both carbon monoxide (CO) and biliverdin, products of heme degradation by heme oxygenase, have been shown to attenuate ischemia/reperfusion (I/R) injury. We hypothesized in this study that dual-treatment with CO and biliverdin would induce enhanced protective effects against cold I/R injury. Heterotopic heart and orthotopic kidney transplantation were performed in syngeneic Lewis rats after 24-h cold preservation in UW solution. While monotherapy with CO (20 ppm) or biliverdin (50 mg/kg, ip) did not alter the survival of heart grafts, dual-treatment increased survival to 80% from 0% in untreated recipients, with a significant decrease of myocardial injury and improved cardiac function. Similarly, dual-treatment significantly improved glomerular filtration rates of renal grafts and prolonged recipient survival compared to untreated controls. I/R injury-induced up-regulation of pro-inflammatory mediators (e.g. TNF-alpha, iNOS) and extravasation of inflammatory infiltrates were significantly less with dual-treatment than untreated controls. In addition, dual-treatment was effective in decreasing lipid peroxidation and improving graft blood flow through the distinctive action of biliverdin and CO, respectively. The study shows that the addition of byproducts of heme degradation with different mechanisms of action provides enhanced protection against transplant-associated cold I/R injury of heart and kidney grafts.     

Apoptosis and regeneration of sinusoidal endothelial cells after extended cold preservation and transplantation of rat liver

BACKGROUND: Sinusoidal endothelial cells (SECs) are particularly susceptible to cold ischemia-reperfusion (I/R) injury. We have examined the process of injury and recovery of graft after cold-preserved liver transplantation, with special focus on the proliferation of SECs and regulatory mechanisms involved. METHODS: Male SD rats were divided into two groups according to length of cold preservation time in University of Wisconsin [UW] solution of graft: UW1h group and UW12h group. Graft function, incidence of apoptosis, proliferation of SECs and the expression of related regulatory factors were assessed after orthotopic liver transplantation (OLT). RESULTS: SECs are more sensitive to apoptosis induced by cold I/R injury compared with hepatocytes. Using bromodeoxyuridine and rat endothelial cell antigen-1 double immunostaining assay, SECs exhibited a delayed proliferation in comparison with hepatocytes, reaching a peak at 72 hr in UW1h group and 96 hr in UW12h group, respectively. Vascular endothelial growth factor increased at 24 hr after reperfusion, and peaked at 72 hr in both groups. Flt-1 and flk-1 expression was found to be mainly limited to SECs, with a peak in expression occurring between 72 and 96 hr, which coincided with the peak in SEC proliferation in UW1h group. However, flt-1 was found to be reduced significantly at any time throughout the experiments in UW12h group compared to sham. CONCLUSION: The delayed recovery of rat liver after extended cold preservation and transplantation correlates with a retarded regeneration of SECs due to increased apoptosis and reduced expression of flt-1. These results suggest that SECs play an important role in cold-preserved liver transplantation.     

大鼠肝脏保存中不同器官保存液对肝细胞凋亡的影响

目的 研究３种目前国内常用的器官保存液对供肝细胞凋亡的影响。方法 分别用ＵＷ液、ＨＣ－Ａ液和ＷＭＯ－１号液灌洗并保存大鼠肝脏,于保存后０、１２、２４ｈ用原位末端标记法检测供肝细胞凋亡情况,并将保存２４ｈ的肝及行大鼠原位全肝移植,观察受者的３ｄ存活率。结果 ３种保存液保存的肝脏均在保存１２ｈ时出现细胞凋亡,ＨＣ－Ａ液级瑟ＷＭＯ－１号液组的凋亡指数（ＡＩ）高于ＵＷ液组（Ｐ〈０．００１）,而ＨＣ－Ａ液组     

Comparison of histidine-tryptophan ketoglutarate solution and University of Wisconsin solution in prolonged cold preservation of kidney allografts

Although University of Wisconsin (UW) solution is the standard preservation solution for organ transplantation, Histidine-Tryptophan Ketogluatarate (HTK) solution has been increasingly used. This study compared HTK or UW for cold static storage of kidney allografts. In all, 149 renal transplants were performed with cold ischemic times (CI) greater than 16 hr (UW 87, HTK 62) and a subset analysis was performed with CI over 24 hr (HTK 31, UW 38). Data from receiving renal transplant centers focused on delayed graft function (DGF), patient and allograft survival. In CI greater than 16 hr, graft and patient survival were comparable. HTK cohort had lower DGF. In CI greater than 24 hr, there was no difference in patient survival, a trend towards improved graft survival in HTK, and decreased rate of DGF in HTK. This data suggests that UW and HTK have at least similar efficacy in kidney preservation at longer ischemic times.     

Improved preservation of the rat liver for orthotopic liver transplantation: use of University of Wisconsin-lactobionate solution and retrograde reflushing

This study investigated cold preservation and reflushing before orthotopic liver transplantation by examining (1) new University of Wisconsin solution (UW) versus Euro-Collins solution (EC), (2) retrograde reflushing (RR) versus antegrade reflushing (AR), and (3) the addition of a platelet-activating inhibitor (PAF), superoxide disumatase (SOD), or SOD + catalase to UW. Syngeneic, male Lewis rats (200 to 400 gm) were used. Preservation for 9, 12, 18, or 24 hours in UW or EC with RR (through the inferior vena cava) was used. The 9- and 12-hour groups experienced a significant decrease in the weight of the grafts preserved in UW. The 3-week survival rate after 9 hours of preservation (n = 6) in UW was 66%, and the survival rate with EC was 0% (p less than 0.025). After 12 hours of preservation, recipient survival rate was 70% (n = 10) with UW versus 0% (n = 4) with EC (p less than 0.025). RR of the graft with cold lactated Ringer's solution immediately before reimplantation significantly improved 3-week survival in the 12-hour group to the level of the control group (no preservation time, 69%). Preservation for 12 hours in UW followed by AR yielded a 3-week survival of 14%; 3-week survival for the RR group was 70% (p less than 0.025). Furthermore, RR allowed a 3-week survival of 33% and 20% after 18 and 24 hours of UW preservation, respectively. In the 24-hour RR/UW group, donor pretreatment with SRI 63-441 (20 mg/kg, intravenously) and recipient treatment with SOD (15 mg/kg, intravenously) or SOD + catalase (15 mg/kg and 5000 units/kg, intravenously) produced a 3-week survival comparable to preservation in UW followed by RR alone. These studies show that UW is a profound improvement over EC for cold preservation of liver and that the new application of RR to rat orthotopic liver transplantation improves survival. However, the addition of free-radical scavengers or PAF does not improve organ function or recipient survival in this model.     

Human small bowel storage: the role for luminal preservation solutions

BACKGROUND: Graft injury incurred during periods of cold storage remains a factor affecting the success of small bowel (SB) transplantation. No one preservation solution, including the gold standard University of Wisconsin (UW) solution, has been able to maintain graft integrity for storage periods paralleling that of other commonly transplanted intra-abdominal organs. We investigated the role for the luminal administration of preservation solutions in a small animal model, documenting significantly improved graft quality. The current study addresses direct clinical applicability using human SB. METHODS: Human SB was obtained at the time of standard multiviscera procurement. After a common intra-arterial UW flush, the SB was immediately removed from the abdomen, randomly divided into three segments, and treated as follows (n=6-9): group 1, no luminal flush; group 2, luminal flush with UW solution; and group 3, luminal flush with an amino acid- enriched solution. Analysis of cellular energetics, permeability, and histologic injury was performed throughout 24 hr of cold storage. RESULTS: Mucosal barrier function, measured by mannitol permeability, was significantly better overall in groups 2 and 3, with 24-hr values measuring 31 and 34 nmol/cm2/hr versus 57 nmol/cm2/hr, respectively (both P<0.05). Significantly less morphologic injury was also noted in the luminally treated specimens (groups 2 and 3) compared with the clinical standard (vascular flush with UW solution). Damage in group 1 reached gross villus denudation with an obvious elevated risk of villus tissue loss, whereas groups 2 and 3 only exhibited epithelial clefting to varying degrees. CONCLUSION: This study supports luminal administration of preservation solutions for improvement of human SB graft quality during clinically relevant periods of cold storage.     

A comparison of histadine lactobionate solution with University of Wisconsin solution for rat liver and heart preservation

We developed a new solution mainly composed of Na-lactobionate and histidine (HL) and compared the effectiveness of this solution with that of University of Wisconsin (UW) solution using orthotopic liver and heterotopic heart transplantation in rats. The new solution has a higher sodium content and a lower potassium content (Na, 90 mEq/l; K, 45 mEq/l) than UW. Hydroxyethyl starch, adenosine, dexamethasone and insulin are not included. Buffering capacity is increased by adding histidine (90 mm/l) together with KH₂PO₄ (20 mm/l). Rat liver was perserved in either UW or HL solution hypothermically for 24 h and then transplanted orthotopically into the recipient rat. The heart was preserved in either solution for 18 h and transplanted heterotopically into the recipient rat. The 1-week survival rate for rats receiving livers preserved in UW for 24 h at 4°C was 29% (5/17). In contrast, the new solution (HL) gave a 78% (11/14) survival rate (P < 0.01). The 1-week heart graft survival rate, using UW solution was 50% (3/6), following 18-h cold preservation, whereas all hearts (7/7) continued to beat for over a week using new HL solution (P < 0.05). These results demonstrated that the new HL solution, with a substantial buffering capacity, was superior to UW solution in rat liver and heart preservation.     

Limitations of heart preservation by cold storage.

Clinical heart preservation is currently limited to only 4-6 hr, while the kidney, liver, and pancreas can tolerate 24-48 hr of cold ischemia. A fundamental difference between these organs is that the heart is contractile, containing large quantities of actin and myosin, and is susceptible to contracture-induced injury caused by energy deprivation. We have quantified and correlated the onset of contracture with levels of ATP and glycogen during cold storage in rabbit hearts flushed with UW solution, with and without 1 mM calcium (Ca), or 3 mM iodoacetate (IAA). A fluid-filled left ventricular balloon was used to generate pressure-volume curves (compliance) at 1, 6, 12, 18, and 24 hr of cold storage. Onset of contracture occurred in UW stored hearts at 18 hr, contracture in hearts exposed to Ca occurred between 6 and 12 hr. Compliance was significantly less in hearts exposed to Ca at 12, 18, and 24 hr (P less than .01) than in hearts without Ca. ATP levels were well maintained for up to 18 hr in the hearts preserved in UW solution (78%), but fell more rapidly in the presence of Ca at 12 hr (P less than .005), 18 hr (P less than .005), and 24 hr (P less than .05). In comparison, the ATP supply of the liver and kidney was exhausted by only 4 hr of cold storage. Onset of myocardial contracture correlated with a decrease in ATP to less than 80% of control, and contracture accelerated ATP decline 3-6-fold. IAA caused nearly complete myocardial contracture and ATP depletion within 2 hr. Isolated heart function was 77% and 73% at 6 and 12 hr of storage, but fell to 54% and 42% at 18 and 24 hr, respectively, coinciding with development of contracture. We conclude that ischemic contracture in this model is a major cause of myocardial damage during cold storage, and is accelerated by the presence of Ca. Other organs can be successfully stored despite exhaustion of ATP reserves. Thus successful cold-storage of the heart is highly ATP-dependent. Since cold storage inevitably leads to ATP depletion, extension of myocardial ischemic tolerance will depend on either reversible inhibition of ATP hydrolysis during storage, reversible uncoupling of contracture development from ATP depletion, or maintaining ATP production by continuous hypothermic perfusion.     

Insulin in University of Wisconsin solution exacerbates the ischemic injury and decreases the graft survival rate in rat liver transplantation

BACKGROUND: Insulin keeps the liver in a metabolically vigorous state. However, organ preservation aims to decrease the metabolic rate. The objective of this study was to clarify the effect of insulin used in University of Wisconsin (UW) preservation solution on the liver graft. METHODS: The liver grafts were preserved by UW solution with or without insulin for 7, 9, and 24 hr, respectively. The influence of insulin was studied by 7-day survival rate, liver function, morphology, and intragraft gene expression 24 hr after transplantation. Morphology was studied on the preserved grafts. RESULTS: The morphology of the graft in the insulin group showed more severe ischemia-reperfusion injury. The 7-day graft survival rates of the 7-hr subgroups with and without insulin were 55% and 93%, respectively (P=0.02). In the 9-hr subgroups, the survival rates were 0% and 78%, respectively (P=0.002). The serum levels of aspartate aminotransferase (AST) (P=0.008) and alanine aminotransferase (ALT) (P=0.032) were higher in the 7-hr subgroup with insulin. The same trend was found in the 9-hr subgroups (AST, P=0.016; ALT, P=0.016). The expression level of 215 genes were much lower at 24 hr after transplantation in the grafts preserved with insulin than in those preserved without insulin, and most of the genes were related to metabolic activities. CONCLUSIONS: Insulin in UW solution may exacerbate graft ischemic injury and decrease the graft survival rate in rat liver transplantation. Insulin, in the absence of glucose in UW solution, may exhaust the metabolic activity of the liver graft. It is harmful rather than helpful for isolated rat liver grafts preserved in UW solution.     

A comparison of Collins and UW solutions for cold ischemic preservation of the rat liver

A new solution which can extend successful preservation times for hepatic allografts was recently developed at the University of Wisconsin (UW). To examine the mechanism of improved viability using this solution, we developed a model of orthotopic hepatic transplantation in the rat. As a baseline study, we compared parameters of viability of allografts preserved in Collins solution to those preserved in UW, including survival, bile output, peak AST, and allograft weight change during storage. Seventy-four rats were transplanted following storage in Collins solution and 70 rats were transplanted after storage in UW. Cold-storage time varied between 2 and 24 hr. The survival with preservation in UW was significantly better than that with Collins when storage time was greater than 2 hr. The preservation time for a viable organ using UW was greater than double that using Collins. The peak AST using UW was lower than that with Collins for cold ischemic times (CIT) up to 10 hr, with significance demonstrated at 5-6 and 7-8 hr when compared with Collins. Prolonged CIT resulted in an increase in liver weight with Collins-preserved livers and a decrease in weight with UW-preserved livers. Using a model of orthotopic liver transplantation in the rat, we demonstrated a doubling of preservation time when UW solution was substituted for Collins. Similar improvements in recipient survival and biochemical parameters of injury have been demonstrated in the canine model and in human clinical trials.     

Advantages of normothermic perfusion over cold storage in liver preservation

BACKGROUND: To minimize the ischemia-reperfusion injury that occurs to the liver with the current method of preservation and transplantation, we have used an extracorporeal circuit to preserve the liver with normothermic, oxygenated, sanguineous perfusion. In this study, we directly compared preservation by the standard method of simple cold storage in University of Wisconsin (UW) solution with preservation by perfusion. METHODS: Porcine livers were harvested from large white sows weighing between 30 and 50 kg by the standard procedure for human retrieval. The livers were preserved for 24 hr by either cold storage in UW solution (n=5) or by perfusion with oxygenated autologous blood at body temperature (n=5). The extracorporeal circuit used included a centrifugal pump, heat exchanger, and oxygenator. Both groups were then tested on the circuit for a 24 hr reperfusion phase, analyzing synthetic function, metabolic capacity, hemodynamics, markers of hepatocyte and reperfusion injury, and histology. RESULTS: Livers preserved with normothermic perfusion were significantly superior (P=0.05) to cold-stored livers in terms of bile production, factor V production, glucose metabolism, and galactose clearance. Cold-stored livers showed significantly higher levels of hepatocellular enzymes in the perfusate and were found to have significantly more damage by a blinded histological scoring system. CONCLUSIONS: Normothermic sanguineous oxygenated perfusion is a superior method of preservation compared with simple cold storage in UW solution. In addition, perfusion allows the possibility to assess viability of the graft before transplantation.     

Preservation of the heart with University of Wisconsin solution--hemodynamic and morphological evaluation in a canine heterotopically transplanted heart]

University of Wisconsin (UW) solution has been reported to extend the safe cold ischemic time in the preservation of the liver, kidney and pancreas. However, there have been few reports of safe cold ischemic time in heart preservation with UW solution. The purpose of this study was to find whether UW solution can extend the safe cold ischemic time in cardiac transplantation in dogs. Heterotopic cardiac transplantation was performed in mongrel dogs after cold ischemic preservation of the hearts with UW solution, ischemic time 8, 16 and 24 hours (Gr.UW8, Gr.UW16 and Gr.UW24, respectively) and with GIK solution, ischemic time 4 hours (Gr.G4) which is considered the safe cold ischemic time in clinical cardiac transplantation. The following was studied: 1) Emax of the LV, myocardial contraction, by pressure-volume curve with the volume measured conductance catheter method, 2) myocardial tissue blood flow of the LV (MTBF), with laser doppler tissue flow meter, 3) serum CPK and electron microscopical evaluation. Emax and MTBF were measured before transplantation and after reperfusion. Their results were expressed as percentage of the values before transplantation. As results, after 120 minutes from reperfusion, Emax was recovered to 94 +/- 13% in Gr.G4, 104 +/- 11% in Gr.UW8, 67 +/- 22% in Gr.UW16 and 66 +/- 16% in Gr.UW24. Emax in Gr.G4 and Gr.UW8 were significantly (p less than 0.01) higher than that in Gr.UW16 and Gr.UW24. After 120 minutes from reperfusion, MTBF was recovered to 90 +/- 19% in Gr.G4, 98 +/- 9% in Gr.UW8, 63 +/- 19% in Gr.UW16 and 61 +/- 6% in Gr.UW24.(ABSTRACT TRUNCATED AT 250 WORDS)     

An examination of the effects of solutions containing histidine and lactobionate for heart, pancreas, and liver preservation in the rat.

Fifty-five rat pancreas transplants, 18 rat heart transplants, and 41 rat liver transplants were performed using standard UW solution, the new HL solution (HL-I), or a modified HL solution (HL-II). Storage times of 18 hr were used in the heart preservation experiments, 24 hr in the liver preservation experiments, and 48 or 72 hr in the pancreas preservation experiments. HL-I solution was superior to both HL-II and UW solution for heart preservation (1-week graft survival rates of 100% [7/7], 0% [0/5], and 50% [3/6], respectively). HL-I and HL-II were superior to UW for 24 hr liver preservation (1-week graft survival rates of 78% [11/14], 80% [8/10], and 29% [5/17], respectively). In contrast, HL-II was superior to both HL-I and UW solutions for pancreas preservation following both 48-hr preservation and 72-hr preservation. Satisfactory graft function was achieved in 100% (7/7), 40% (6/15), and 44.4% (4/9) of pancreases transplanted after 48 hr using HL-II, HL-I, and UW solutions, respectively, and in 50% (4/8), 0% (0/8), and 0% (0/8) following 72-hr preservation. Histidine- and lactobionate-containing solutions thus represent a further improvement in organ preservation by simple cold storage.     

Pancreas preservation with University of Wisconsin and Celsior solutions: a single-center, prospective, randomized pilot study

BACKGROUND: Celsior is an extracellular-type, low-viscosity, preservation solution already used for heart, lung, liver, and kidney transplantation. We report the results of a single-center, prospective, randomized pilot study specifically designed to compare the safety profile of Celsior solution with University of Wisconsin (UW) solution in clinical pancreas transplantation. METHODS: A total of 105 consecutive procurements were randomized to graft preservation with UW (n=53) solution or Celsior (n=52) solution. The groups were comparable with regard to all donor and recipient characteristics. RESULTS: Five grafts were discarded and 100 grafts (50 UW vs. 50 Celsior) were transplanted. Mean cold and warm ischemia times were 11.0 +/- 2.1 hr and 37.2 +/- 6.0 min for UW compared with 10.8 +/- 1.8 hr and 38.1 +/- 5.9 min for Celsior (P =not significant). Delayed endocrine pancreas function was recorded in one graft preserved with UW solution. Eleven recipients (UW 12% vs. Celsior 10%, P =not significant) required a relaparotomy. The mean serum levels of glucose, amylase, and lipase remained comparable between the study arms at equivalent intervals after transplantation. One recipient died with functioning grafts in each study arm; two further grafts were lost to arterial thrombosis (Celsior) and chronic rejection (UW), respectively. Actuarial 1-year patient and graft survival rates overlapped in the two study arms (98% and 96%, respectively). CONCLUSIONS: Within the range of cold ischemia time reported in this study, UW and Celsior solutions have similar safety profiles for pancreas preservation.     

Fate of hepatocyte and sinusoidal lining cell function and kinetics after extended cold preservation and transplantation of the rat liver

We investigated the chronological profile of graft damage and recovery after liver cold ischemia-reperfusion (I/R) injury, with particular attention to the role of apoptosis on hepatocyte and sinusoidal endothelial cell (SEC) damage. Male Lewis rats underwent rearterialized orthotopic liver transplantation using grafts subjected to a short (University of Wisconsin [UW] solution for 1 hour [UW1h]) and prolonged period (UW16h) of cold preservation. Experiments were performed immediately after preservation and 4 hours, 24 hours, 3 days, and 7 days after reperfusion. At each time, graft function, incidence of apoptotic cells, expression of the epitope recognized by a monoclonal antibody specific to rat SECs (SE-1), and incidence of proliferating cells were estimated. In the UW16h group, the proportion of apoptotic SECs was markedly elevated at 4 hours. The incidence of hepatocyte apoptosis was very low, although massive hepatocyte necrosis was evident at 24 hours. The incidence of proliferating hepatocytes and SECs peaked at 3 days, then returned to normal by 7 days. SE-1 expression was reduced immediately after preservation, followed by a marked reduction at 4 and 24 hours after reperfusion, and expression returned to normal by 7 days. Although SEC apoptosis was induced in the early phase of cold I/R injury, hepatocyte damage developed without the occurrence of apoptosis. Regeneration of both hepatocytes and SECs after cold I/R injury peaked at 3 days and was complete by 7 days, whereas functional recovery of these cell populations was complete 3 days after reperfusion. (Liver Transpl 2002;8:370-381.)     

Multicenter analysis of kidney preservation

BACKGROUND: Kidney preservation is an integral part of clinical kidney transplantation. Changes in the use of preservation methods and storage solutions, ischemic preservation times, and the relationship between ischemia time and human leukocyte antigen (HLA) match have not been extensively studied in recent years. METHODS: The Collaborative Transplant Study database was used to analyze effects of kidney preservation methods and times. Graft survival and death-censored functional survival were used as endpoints. In all, 91,674 transplants from deceased donors were analyzed using univariate and multivariate methods. RESULTS: Cold storage accounted for more than 95% of kidney preservations from 1990-2005. Increasing ischemia up to 18 hr was not detrimental for graft outcome, whereas the risk of graft failure rose with ischemia 19-24 hr to relative risk (RR) 1.09, 25-36 hr to RR 1.16, and >36 hr to RR 1.30 (P<0.001). As compared to other preservation solutions, University of Wisconsin (UW) solution was associated with significantly better outcome when ischemia exceeded 24 hr. Short ischemia did not eliminate the effect of HLA matching. Kidneys from young or old donors were affected by prolonged ischemia to similar degrees. Pulsatile machine perfusion was not superior to cold storage. CONCLUSION: Kidneys from deceased donors should ideally be transplanted within 18 hr. Within the 18-hr window, the time of ischemia has no significant influence on graft survival. UW solution should be used if preservation for longer periods is envisioned. HLA matching improves graft survival regardless of length of ischemia.