Subzero nonfreezing preservation in a murine limb replantation model

This study was designed to examine the most effective temperature for hypothermic storage, without freezing, to prolong ischemic tolerance in an amputated murine hindlimb model. We measured freezing points in the calf muscle and the subcutaneous tissue of the foot in the amputated limbs of Fisher 344 strain male inbred rats. The highest freezing point was -1.5 degrees C, which was recorded in the calf muscle. To prevent freezing in any of the tissues in the amputated limb, the temperature for the lowest nonfreezing preservation was defined as -1 degrees C. The amputated limbs were preserved at subzero nonfreezing temperature (-1 degrees C) and at 4 degrees C for 4, 8, 12, 24, 48, and 72 h, and were then transplanted to other inbred rats by microsurgical techniques. We evaluated the vascular patency of the anastomoses by direct observation and performed histological examinations on the seventh day after replantation. Subzero nonfreezing preservation of a limb at -1 degrees C for 72 h was significantly superior to hypothermic preservation at 4 degrees C for 72 h in terms of anastomotic patency rates (P < 0.05). The histology of skeletal muscles preserved at -1 degrees C for 8 h showed greater similarity to the normal situation than the histology of those preserved at 4 degrees C for 8 h. Bone viability with osteoblastic activity was maintained in grafted limbs preserved at -1 degrees C for 72 h, but in the limbs preserved at 4 degrees C for 72 h the bone was not viable, showing no osteoblastic activity. Clinically, the period of ischemia in major limb replantation at normal ambient temperatures is limited to about 6 h. In this study, the maximum ischemia time for replantation of a limb containing muscle tissue was prolong to 8 h at -1 degrees C, but the maximum ischemia time at 4 degrees C could not be prolonged to 8 h. Our results suggest that, in the major replantation of a limb containing muscular tissue, hypothermic preservation at -1 degrees C would be more useful than preservation at 4 degrees C.     

Hypothermic ischaemia of the liver: a re-perfusion phenomenon

BACKGROUND: The effects of hypothermic injury to the liver were investigated on an isolated perfusion circuit by comparing porcine livers with varying degrees of preservation injury. METHODS: A group of unstored livers (n = 5) were compared to livers stored in University of Wisconsin (UW) solution for 18 h (n = 5), and a group of livers stored in Hartmann's solution for 18 h (n = 5). RESULTS: We observed that the degree of platelet sequestration was directly related to the severity of the preservation injury. After 2 h of isolated liver perfusion, the perfusate platelet count fell from 148 +/- 14 x 10(9)/L to 84 +/- 13 x 10(9)/L for control livers. In comparison for livers stored in UW solution, the platelet count fell from 173 +/- 43 x 10(9)/L to 61 +/- 14 x 10(9)/L representing a 64.8% fall, while for those stored in Hartmann's solution, an even more profound fall from 152 +/- 36 x 10(9)/L to 19 +/- 9 x 10(9)/L (87.5% fall) was observed. The difference between the UW-stored and Hartmann's-stored livers was significant (P < 0.05). However, using this model, the degree of leukocyte sequestration did not differentiate the groups. Both histological and ultrastructural examination of liver biopsies taken immediately following revascularization demonstrated that for mild degrees of preservation injury following hypothermic storage, changes occur to the sinusoidal lining cells well before changes to the parenchymal elements. CONCLUSIONS: These findings substantiate the hypothesis that the primary injury associated with hypothermia involves the sinusoidal lining cells (non-parenchymal elements), that it is predominantly a reperfusion phenomenon and that efforts at improving preservation should therefore be targeted primarily at these cells and not the hepatocytes.     

Intracellular volumes and membrane permeability in rat hearts during prolonged hypothermic preservation with St Thomas and University of Wisconsin solutions

The study aims to determine a possible relationship between intracellular water, energy metabolism, functional recovery and membrane permeability, during and after hypothermic cardiac preservation. Isolated rat hearts were stored for 12 h at 4 degrees C with University of Wisconsin (UW), St Thomas Hospital (ST) and Krebs-Henseleit (KH) solutions, and were reperfused for 1 h. Cellular volumes were measured by 1H NMR of water and 59Co NMR of the extracellular marker cobalticyanide, and energetic profiles by 31P NMR spectroscopy. Storage in ST solution reduced ischemic swelling from 2.50 +/- 0.06 to 2.73 +/- 0.09 (P < 0.001 v 3.56 +/- 0.10 ml/g dry weight in KH), while UW solution caused cellular shrinkage to 2.12 +/- 0.08 ml/g dry weight. Intracellular ATP concentrations and pH values were higher in UW as compared to ST solution. At reperfusion, hearts stored in ST shrank while those stored in UW expanded, resulting in similar intracellular volumes. Storage with UW was superior to ST in post-ischemic function 65 +/- 5% (P < 0.01 v 49 +/- 4% with ST) and in recovery of ATP 46 +/- 3% (P < 0.001 v 25 +/- 4% with ST). Storage with both ST and UW solutions did not prevent interstitial edema. Sarcolemmal membrane integrity, as assessed by cellular swelling in response to a hypo-osmotic shock (210 mmol/l), was significantly improved by ST and UW solutions as compared to KH (P < 0.05). Creatine kinase efflux was reduced by ST and UW as compared to KH (P < 0.05), and by UW as compared to ST (P < 0.05). Coronary flow was higher following storage with UW than ST solutions. 66 +/- 6 and 45 +/- 4%, respectively (P < 0.01). According to these data, the beneficial effects of UW and ST solutions on hypothermic ischemic storage of rat hearts included prevention of cellular edema and preservation of sarcolemmal membrane integrity. It is concluded: (a) UW and ST solutions reduce ischemic and reperfusion cellular volumes: (b) both solutions, and UW in particular were efficient in preservation of membrane integrity: (c) prevention of cellular edema is not the single or main mechanism responsible for the improved preservation with UW and ST solutions.     

Effect of different solutions of preservatives on the endothelial function of coronary arteries in rats

The effects of cold storage and type of preservation solution on coronary endothelial function are not well established. Experiments were designed to evaluate coronary endothelial-dependent relaxation after a 4-hour cold (4 degrees C) storage in different preservation solutions. Rat hearts, mounted in the Langendorff apparatus, were arrested with a 10-minute perfusion of 4 degrees C crystalloid hyperkaliemic cardioplegic solution (CHCS) (KCl 24 mEq/l) and stored for 4 hours in the following preservation solutions: CHCS (n = 6), Krebs-Ringer solution (KR) (n = 6), 0.9% NaCl (NS) (n = 6) and the University of Wisconsin solution (UW) (n = 6). A fifth group (n = 6) was perfused and stored in UW solution. Endothelium-dependent and independent coronary artery vasorelaxations were respectively tested by infusing 5-hydroxytryptamine (5-HT) (10(-6) mol/l) and sodium nitroprusside (SNP) (10(-5) mol/l) before and after the storage period. In hearts stored with CHCS or KR, coronary artery flow increase to 5-HT and SNP infusions were not significantly affected. However, in hearts preserved with NS or UW solutions, 5-HT coronary response was significantly decreased, indicating endothelial dysfunction. In addition to these findings, coronary flow increase to SNP infusion was decreased in the group perfused and stored with UW, suggesting smooth muscle dysfunction. These experiments suggest that 4-hour cold storage in NS or UW impairs endothelial-dependent coronary relaxation in the isolated rat heart model.     

Hysteresis in force probe measurements: a dynamical systems perspective

BACKGROUND: This study was designed to investigate the effects of a modified University of Wisconsin (UW) solution supplemented with one of four buffering agents (histidine, bicine [N,N-bis(2-hydroxyethyl)glycine], tricine [N-tris(hydroxymethyl)methylglycine], and Tris) on liver metabolism during cold ischemic storage. METHODS: Rat livers were flushed and stored for a maximum period of 24 hr at 4 degrees C, and tissue energetics, substrate, and anaerobic end-products were assessed; the group exhibiting the best results during storage was recovered in a 60-min period of warm reperfusion. Relative buffering capacities of the experimental solutions (measured over physiological pH range, in mM H+/L) were: UW, 4.1; histidine+UW, 9.8; Tris+UW, 19.0; bicine+UW, 22.5; tricine+UW, 26.8. RESULTS: In the UW group, ATP levels dropped rapidly over the first 4 hr; 1.0 micromol/g (40% of initial) remained after 4 hr of storage. By 2 hr, ATP levels in bicine- and tricine-treated groups were 0.5 and 1.1 micromol/g greater than in the UW-stored livers and by 10 hr, ATP in bicine-treated livers was twofold that of the control (UW) group. Total adenylate levels also reflected a superior elevation of cellular energetics; even after 24 hr, quantities were 1.4 and 2.0 micromol/g higher than the UW group in bicine- and histidine-supplemented organs. The increase in energetics occurred as a result of increased flux through the major anaerobic energy-producing pathway, glycolysis. The glycolytic rate was significantly greater at storage times > 10 hr with solutions supplemented with bicine, histidine, and tricine. Final values for net lactate accumulation over the entire 24-hr storage period were: UW, 10.1 micromol/g; histidine, 14.3 micromol/g; bicine, 15.2 micromol/g; tricine, 13.8 micromol/g. Activities of glycogen phosphorylase revealed that the activity of this enzyme dropped by 50% within 2 hr of storage in UW. However, histidine and bicine supplementation resulted in a substantial elevation of phosphorylase "a" over 4 hr and 10 hr, respectively. The best buffer of the four examined in this study was bicine; energetics, glycolytic flux, and patterns of adenylate regeneration upon reperfusion were markedly superior to modified UW solution. CONCLUSION: The results of this study suggest that supplementing the "gold standard" UW solution with an additional buffering agent (in order of efficacy: bicine>tricine>histidine) may improve the metabolic status of livers during clinical organ retrieval/storage.     

Long-term preservation of the rat isolated heart with staurosporine and 2,3-butanedione monoxime

The present study was designed to investigate the effectiveness of staurosporine and 2,3-butanedione monoxime (BDM) in preserving cardiac function of long-term hypothermic-stored hearts. Rat isolated hearts were perfused very slowly at 4 degrees C for 16 hr with a storage buffer solution containing staurosporine and BDM. Heart functions were then examined during 2 hr of normothermic reperfusion. Isovolumetric left ventricular-developed pressure (LVDP), its differential, heart rate, and coronary flow were measured in 5 groups of hearts: controls (fresh unstored hearts), stored drug-free hearts, stored staurosporine-treated hearts, stored BDM-treated hearts, and stored BDM + staurosporine-treated hearts. Hearts that had been perfused with staurosporine or BDM during hypothermic storage attained LVDP values that were 37% or 70%, respectively, of that shown by the control group. Hearts perfused without any drug in the storage buffer attained an LVDP value that was 20% of the control value. Heart rates of stored and then normothermically reperfused hearts were lower than, but not significantly different from, values in the control group. Coronary flow values in all stored hearts were significantly lower than the control values. Thus, BDM, and to a lesser extent staurosporine, applied during prolonged hypothermic storage improved cardiac function during normothermic reperfusion.     

Enhancement of extended lung preservation with a vasoactive intestinal peptide-enriched University of Wisconsin solution

Vasoactive intestinal peptide (VIP) is a known pulmonary and bronchial vasodilator as well as an oxygen free radical scavenger. Since its effect as an additive to University of Wisconsin (UW) solution for lung preservation has been shown previously, the aim of this study was to determine the ability of VIP to improve lung preservation followed by reperfusion. Four groups of excised Sprague-Dawley rat lungs (n = 24) were studied using an isolated blood perfused working lung model. The first 3 groups of lungs were flushed and stored in UW solution at 4 degrees C for: (1) 4 hr, (2) 18 hr, and (3) 24 hr. Group 4 lungs were flushed with UW solution + VIP (1 microgram/ml) and stored in UW solution + VIP (0.5 microgram/ml) for 24 hr. After preservation, the lungs were reperfused to evaluate their functions for 2 hr or until lung failure occurred (arterial oxygen saturation less than 90% and/or appearance of bronchial fluid in the bronchial cannula). In the lungs stored in UW solution for 24 hr, failure occurred after 10 min of reperfusion and all functions were significantly altered. The addition of VIP to UW solution maintained the functional capacity of the lungs, recorded by lung resistance, lung compliance, elastic work, flow resistive work, shunt fraction, and blood oxygen tension. No statistical difference in these parameters other than shunt fraction was found when the VIP group was compared with the group preserved for 4 hr in UW solution. We conclude that lung preservation can be extended to 24 hr with the maintenance of lung functional capacity if VIP is added to UW solution.     

A comparison of the new preservation solution Celsior to Euro-Collins and University of Wisconsin solutions in lung reperfusion injury

BACKGROUND: The lung is particularly susceptible to reperfusion injury, both experimentally and clinically after transplantation. The extracellular-type preservation solution Celsior, which has been predominantly studied in cardiac preservation, has components designed to prevent cell swelling, free radical injury, energy depletion, and calcium overload. Using an isolated blood-perfused rat lung model, we investigated whether Celsior would decrease preservation injury and improve lung function after cold ischemic storage and reperfusion compared to Euro-Collins (EC) and University of Wisconsin (UW) solutions. METHODS: Lewis rat lungs were isolated, flushed with the respective cold preservation solution, and then stored at 4 degrees C for 6 or 12 hr. After ischemic storage, the lung block was suspended from a force transducer, ventilated with 100% O2, and reperfused for 90 min with fresh blood via a cannula in the pulmonary artery. Lung compliance, alveolar-arterial oxygen difference, and outflow oxygen tension were all measured. The capillary filtration coefficient (Kf), a sensitive measure of changes in microvascular permeability, was determined. RESULTS: For 6 hr of cold storage, lungs stored in Celsior had lower Kf values than those stored in EC, indicating decreased microvascular permeability. No other significant differences were noted between Celsior and EC or UW. For 12 hr of cold storage, Celsior provided increased oxygenation, decreased alveolar-arterial O2 differences, increased compliance, and decreased Kf values as compared to both EC and UW. CONCLUSIONS: Celsior provides better lung preservation than EC or UW as demonstrated by increased oxygenation, decreased capillary permeability, and improved lung compliance, particularly at 12-hr storage times. These results are highly relevant, inasmuch as EC and UW are the most common clinically used lung preservation solutions. Further studies of Celsior in experimental and clinical lung transplantation, as well as in other solid organs, are indicated.     

Effect of protein kinase C inhibitors and 2,3-butanedione monoxime on the long-term hypothermic preservation of isolated rat hearts

1. This study examines the protective effect of staurosporine, chelerythrine, Ro 31-8220 and 2,3-butanedione monoxime in rat hearts during hypothermic storage. 2. Hearts were microperfused at 4 degrees C for 24 or 48 h with a storage buffer that in some cases contained one of these protein kinase C inhibitors either alone or in combination with 2,3-butanedione monoxime. After hypothermic storage, hearts were rewarmed to 37 degrees C with Krebs-Henseleit buffer. Cardiac function was then assessed in either Langendorff mode or working heart mode. 3. Compared with values from fresh non-stored hearts, hypothermic stored hearts showed a significant decrease in both coronary flow and left ventricular developed pressure when the stored hearts were reperfused in Langendorff mode. The decrease in coronary flow and left ventricular developed pressure was more pronounced in hearts stored for 48 h than in those stored for 24 h. 4. Hearts stored for 24 or 48 h, with or without the protein kinase C inhibitors, and then perfused in working mode generated less aortic flow and less cardiac output than fresh unstored hearts. 5. Hearts preserved in solutions containing staurosporine, chelerythrine, Ro 31-8220 or 2,3-butanedione monoxime had significantly higher left ventricular developed pressure values on reperfusion than hearts stored without any such drug. 6. Addition of 2,3-butanedione monoxime to a storage buffer containing either staurosporine, chelerythrine or Ro 31-8220 further improved left ventricular developed pressure, aortic flow and cardiac output values in these stored hearts. The group of hearts stored in a buffer containing 2,3-butanedione monoxime and chelerythrine gave the highest left ventricular developed pressure value seen during reperfusion. 7. The ATP and creatine phosphate concentrations of hearts stored in buffer alone were significantly lower than those of fresh unstored hearts, irrespective of the duration of storage. ATP concentrations were better preserved in hearts stored in a buffer containing 2,3-butanedione monoxime or/and one of the protein kinase C antagonists than those stored without such antagonists. A positive correlation was found between peak cardiac output values and the concentrations of combined high-energy phosphates in various groups of stored and reperfused hearts. 8. The present study showed that inhibition of protein kinase C during long-term hypothermic storage significantly increased high-energy phosphate concentrations and also improved contractile function during reperfusion.     

Enhancement of endogenous cyclic AMP signal: a new approach to allow for cold preservation of rat livers from non-heart-beating donors?

BACKGROUND: The organ donor shortage has led to a reconsideration of the use of non-heart-beating donors (NHBDs). However, graft injury due to warm ischemia in NHBD livers strongly affects posttransplant outcome. The present study was aimed at investigating the role of the cellular cyclic (c)AMP second messenger signal with regard to hepatic viability after cold preservation of NHBD livers. METHODS: Cardiac arrest was induced in Wistar rats by frenotomy of the anesthetized nonheparinized animal. After 30 min, the livers were excised and flushed with 20 ml of heparinized saline solution, rinsed with 10 ml of University of Wisconsin (UW) solution, and stored submerged in UW solution at 4 degrees C for 24 hr. In half of the experiments, UW solution was supplemented with glucagon (0.5 microg/ml) to increase the cAMP signal in the liver. Reperfusion was carried out in vitro after all livers were incubated at 25 degrees C in saline solution to replicate the period of slow rewarming during surgical implantation in vivo. RESULTS: Hepatic levels of cAMP (nmol/g dry weight) declined from 1.21+/-0.05 to 0.53+/-0.03 (P<0.01) at 30 min after cardiac arrest. Subsequent storage in UW solution resulted in a further decline to 0.35+/-0.04 after 24 hr in group A, whereas glucagon treatment enhanced cellular cAMP signal to 0.64+/-0.06 (P<0.01). Upon reperfusion, liver integrity was significantly improved after glucagon administration, with 66% reduction in alanine aminotransferase release and a threefold increase in hepatic bile production as compared with untreated livers. Moreover, liver ATP tissue levels were restored to only 2.19+/-0.51 micromol/g in the untreated group but reached 4.97+/-0.41 micromol/g (P<0.05) after treatment with glucagon. CONCLUSIONS: Posthoc conditioning of predamaged livers by glucagon enhances cAMP tissue levels during ischemic preservation and improves hepatic integrity upon reperfusion. This may represent a promising approach for the use of livers from non-heart-beating donors in clinical transplantation.     

Pneumocytes type II ultrastructural modifications after storage in preservation solutions for transplantation

Although lung transplantation represents a real therapeutic opportunity, the problem of preserving the organ for a prolonged period (> 10 h) still remains unsolved. Further studies are necessary to fully understand the behavior of different lung cell types during the ischemic period. As ultrastructural modifications of cells of lung samples stored in different means of preservation represent an index of the integrity and therefore of cellular viability, in the present work we have compared the time-related ultrastructural changes in human pneumocytes type II cells after hypothermic (10 degrees C) storage for 6 and 12 h in University of Wisconsin (UW) solution and in low potassium dextran (LPD) solution. An ultrastructural grading scale was used to quantify the damage and the results confirmed what was observed microscopically. Statistical analysis (t test) of the data showed that after 6 h in LPD solution, pneumocytes type II were less damaged than those stored in UW solution; these differences were statistically significant (p < 0.05). In our opinion, ultrastructural studies should be considered among the methods presently used to assess the effectiveness of different storage fluids.     

Excellent recovery after prolonged heart storage by preservation with coronary oxygen persufflation: orthotopic pig heart transplantations after 14-hr storage

BACKGROUND: Improvement of heart preservation is still the greatest challenge in preservation research. The unchanged severe restriction of acceptable storage periods of heart grafts since the beginning of clinical heart transplantation indicates that technical innovations are necessary if a substantial improvement is to be achieved. METHODS: Here, we present the results of hypothermic preservation using the innovative technique of coronary oxygen persufflation (COP). COP simply adds gaseous oxygen to hypothermic graft storage and requires only a "valve guard" for reversible closure of the aortic valve. Fourteen-hr preservation was followed by orthotopic transplantation and evaluations of functional as well as metabolic recovery. Mature pig hearts, a model with restricted preservation tolerance similar to the human heart, were used to guarantee the clinical relevance of this study. RESULTS: After 14-hr hypothermic storage, COP-preserved hearts were able to recover within 2 hr of cardiopulmonary bypass to a steady cardiovascular function without mechanical or pharmacologic support. The left ventricular pressure amplitude of mHTK-COP-preserved hearts as well as energy charge potential recovered to pregrafting values and the ventricular power output to 66%. Hearts simply stored in University of Wisconsin (UW), modified Bretschneider's histidine-tryptophan-ketoglurate (mHTK), or Euro-Flush with glutathione (EFG) solution had only limited recovery, with significantly lower ventricular power output of 18%, 29% or 30% of pregrafting controls on average. CONCLUSIONS: Fourteen-hr oxygenated pig heart preservation using COP results in optimal recovery. Storage preservation in solutions containing hyaluronidase (mHTK and EFG) results in higher recoveries as compared to UW solution, an effect that may support the excellent recovery after mHTK-COP preservation.     

Trimetazidine prevents renal injury in the isolated perfused pig kidney exposed to prolonged cold ischemia

BACKGROUND: Ischemia caused by cold storage (CS) and reperfusion of the kidney is often responsible for delayed graft function after transplantation. Significant attention has been focused on the cascade of events involved in ischemia-reperfusion injury, with the objective of identifying drugs to ameliorate the functional damage that occurs. METHODS: The purpose of this study was to evaluate the renal function of isolated perfused pig kidneys after 48 hr of CS with Euro-Collins (EC) solution plus trimetazidine (EC+TMZ), standard EC solution, or University of Wisconsin (UW) solution. Normothermic isolated perfused pig kidneys were randomized into five experimental groups: (A) control group (cold flush with cold heparinized saline and immediately reperfused; n=6); (B) cold flush with cold heparinized saline with TMZ (10(-6) M), n=6; (C) 48 hr of CS with EC and reperfusion (n=8); (D) 48 hr of CS with EC+TMZ alone and reperfusion (n=8); (E) 48 hr of CS with UW and reperfusion (n=8). Proton nuclear magnetic resonance spectroscopy and biochemical studies were performed for the functional evaluation during reperfusion. Lipid peroxidation was also determined. Histological examination (optical and electron microscopy) was performed after CS and reperfusion. RESULTS: Using TMZ, the renal perfusate flow rate as well as the glomerular filtration rate and proximal tubular function were significantly improved. This improvement of renal function during reperfusion was correlated with a less significant cellular and interstitial edema. In addition, tubular injury markers were significantly lower in the group preserved with EC+TMZ, and TMZ reduced lipid peroxidation dramatically during reperfusion. CONCLUSIONS: The addition of TMZ to the EC solution increased the preservation quality and renal tubular function, and gave protection from reperfusion injury better than EC alone or UW. These results strongly suggest that TMZ has a cytoprotective effect and may therefore be useful for kidney preservation.     

Cytomegalovirus DNA can be detected in peripheral blood mononuclear cells from all seropositive and most seronegative healthy blood donors over time

1. The purpose of this study was to assess the potential of various preservation solutions, orginally designed for solid organs, to protect muscle function during cold storage. 2. The soleus (SOL) and the cutaneous trunci (CT) muscle from the rat were isolated and stored for 2, 4 or 8 h at 10 degrees C. The solutions used, listed in order from an intracellular to an extracellular-like composition, were: University of Wisconsin (UW), Euro-Collins (EC), HTK-Bretschneider (HTK), reversed St. Thomas' Hospital (ST2) and Krebs-Henseleit (KH). After cold storage, the muscles were tested by direct electrical stimulation to obtain the maximum twitch tension (Pt) and the maximum tetanus tension (P0). Subsequently, the muscles were prepared for morphological analysis. 3. In general, storage at 10 degrees C caused a gradual decrease of Pt and P0 with time. After 8 h of storage in the extracellular-like solutions KH and ST2, the P0 was about 50% (SOL) and 35% (CT) of control. Eight hours of storage in intracellular-like solutions resulted in a P0 of 50% of control for HTK, in a P0 of 40% (SOL) and 67% (CT) for UW, but in a P0 of 5% (SOL) and 26% (CT) for EC. These findings corresponded well with the morphological observations. 4. It is concluded that the effects of 10 degrees C storage on skeletal muscle function are not predominantly determined by the intra- or extracellular-like composition of the solutions used. Both UW and HTK were most effective (P0 > 50% of control) in preserving muscle function.     

Preservation with 8-bromo-cyclic GMP improves pulmonary function after prolonged ischemia

BACKGROUND: Cyclic guanosine monophosphate (cGMP) is a potent second messenger for the nitric oxide pathway in the pulmonary vasculature. Increased cytosolic cGMP levels elicit pulmonary vasodilatation resulting in decreased pulmonary vascular resistance and maximized pulmonary function after ischemia-reperfusion injury. We hypothesized that the addition of a membrane-permeable cGMP analogue (8-bromo-cGMP) to a Euro-Collins (EC) preservation solution would ameliorate pulmonary reperfusion injury better than prostaglandin E1 injection alone after prolonged hypothermic ischemia. METHODS: All lungs from New Zealand White rabbits (weight, 3 to 3.5 kg) were harvested en bloc, flushed with EC solution, and reperfused with whole blood for 30 minutes. Group 1 lungs (immediate control) were immediately reperfused. Group 2 lungs (control) were stored inflated at 4 degrees C for 18 hours before reperfusion. Groups 3 and 4 lungs were flushed with EC solution containing 200 micromol/L 8-bromo-cGMP and stored at 4 degrees C for 18 and 30 hours, respectively. Fresh, nonrecirculated venous blood was used to determine single-pass pulmonary venous-arterial oxygen gradients at 10-minute intervals. Assays for cGMP, cyclic adenosine monophosphate, nitric oxide synthase activity, and myeloperoxidase were performed on all lung tissue samples. Wet to dry weight ratios were determined after 2 weeks of passive desiccation. RESULTS: Oxygenation (venous-arterial oxygen gradient), pulmonary artery pressure, pulmonary vascular resistance, and edema formation were significantly improved in groups 3 and 4 (addition of 8-bromo-cGMP to EC plus 18 or 30 hours of hypothermic ischemia). Hypothermic storage (groups 2, 3, and 4) decreased both nitric oxide synthase activity and myeloperoxidase levels compared with immediate reperfusion (group 1). CONCLUSIONS: These results suggest that the addition of a membrane-permeable cGMP analogue to an EC pulmonary flush solution improves pulmonary function after prolonged storage compared with EC and prostaglandin (E1) preservation alone. The finding of myeloperoxidase reduced levels after hypothermic storage and subsequent reperfusion may suggest a more important role for pulmonary hemodynamic control in mitigating pulmonary reperfusion injury.     

Induction of tolerance to hypothermia and hyperthermia by a common mechanism in mammalian cells

Pretreatment by hypothermic (25 degrees C) cycling (PHC) of attached exponential-phase V79 Chinese hamster cells by Method 4 (24 hr at 25 degrees C + 1.5 hr at 37 degrees C + 24 hr at 25 degrees C + trypsin + 3 hr at 37 degrees C) or by Method 3 (48 hr at 25 degrees C + trypsin + 3 hr at 37 degrees C) make mammalian V79 cells significantly more resistant to 43 degrees C hyperthermia. There is no significant difference in the 43 degrees C curves whether Method 3 or 4 is used for pre-exposure. If pre-exposure at 15 or 10 degrees C, the resistance to hyperthermia is significantly reduced. PHC by Method 4 significantly increases survival of cells exposed to 5 degrees C and, to a lesser extent, to 10 degrees C. The increase in hyper- and hypothermic survival after PHC cannot be accounted for by changes in cell cycle distribution. Heat-shock protein synthesis is not induced by PHC; hence, protection does not result from newly synthesized proteins. When cells are made tolerant to hyperthermia by a pretreatment in 2% DMSO for 24 hr at 37 degrees C (Method 8), the cells are not more resistant to subsequent exposures to hypothermia, either at 5 or 10 degrees C. The results imply that there may be two mechanisms of inducing resistance to hyperthermia, only one of which also confers resistance to hypothermia.     

Storage temperature of the unbuffered rapid urease test

OBJECTIVES: The unbuffered rapid urease test (RUT) is an accurate, rapid, and inexpensive method for detecting Helicobacter pylori. However, it is generally recommended that the reagent be prepared daily. This prospective study was undertaken to evaluate the shelf life of our unbuffered RUT when stored at 4 and -20 degrees C. METHODS: Ninety-five patients were studied. Three sets of antral (X2) and body (X1) biopsy samples were taken from each patient. The samples were subjected to histological examination, with the RUTs stored at 4 and -20 degrees C. The RUT tubes were examined at 1 and 15 min. RESULTS: Fifty-six patients (59%) were infected with H. pylori as defined by histological examination. The reagent was classified according to storage time (group I, < or = 5 days; group II, > 5 days). The mean (SD) storage time of group I (n = 59) and group II (n = 36) was 3.2 (1.4) and 9.9 (5.0) days, respectively. At 15 min, the sensitivity of our RUT stored at 4 degrees C was significantly higher in group I than in group II (92 vs 47%). On the other hand, the sensitivity of our RUT stored at -20 degrees C remained consistently high in both groups (15 min: group I, 92%; group II, 100%). Our RUTs stored at 4 and -20 degrees C were highly specific in both groups. CONCLUSIONS: Our RUT remains highly sensitive and specific when it is stored at 4 degrees C for up to 5 days. When the RUT is expected to be stored for a longer period of time, the bottles should be frozen at -20 degrees C.     

Comparison of polarized and depolarized arrest in the isolated rat heart for long-term preservation

BACKGROUND: Hypothermic hyperkalemic cardioplegic solutions are currently used for donor heart preservation. Hyperkalemia-induced depolarization of the resting membrane potential (Em) may predispose the heart to Na+ and Ca2+ loading via voltage-dependent "window currents," thereby exacerbating injury and limiting the safe storage duration. Alternatively, maintaining the resting Em with a polarizing solution may reduce ionic movements and improve postischemic recovery; we investigated this concept with the reversible sodium channel blocker tetrodotoxin (TTX) to determine (1) whether polarized arrest was more efficacious than depolarized arrest during hypothermic long-term myocardial preservation and (2) whether TTX induces and maintains polarized arrest. METHODS AND RESULTS: The isolated crystalloid-perfused working rat heart preparation was used in this study. Preliminary studies determined an optimal TTX concentration of 22 micromol/L and an optimal storage temperature of 7.5 degrees C. To compare depolarized and polarized arrest, hearts were arrested with either Krebs-Henseleit (KH) buffer (control), KH buffer containing 16 mmol/L K+, or KH buffer containing 22 micromol/L TTX and then stored at 7.5 degrees C for 5 hours. Postischemic recovery of aortic flow was 13+/-4%, 38+/-2%, and 48+/-3%* (*P<.05 versus control and 16 mmol/L K+), respectively. When conventional 3 mol/L KCl-filled intracellular microelectrodes were used, Em gradually depolarized during control unprotected ischemia to approximately -55 mV before reperfusion, whereas arrest with 16 mmol/L K+ caused rapid depolarization to approximately -50 mV, where it remained throughout the 5-hour storage period. In contrast, in 22 micromol/L TTX-arrested hearts, Em remained more polarized, at approximately -70 mV, for the entire ischemic period. CONCLUSIONS: Blockade of cardiac sodium channels by TTX during ischemia maintained polarized arrest, which was more protective than depolarized arrest, possibly because of reduced ionic imbalance.     

Protective effect of hypothermia on contractile force in skeletal muscle

The clinical success of limb replantation and tissue transfer is partly dependent on the duration of ischemia experienced by the amputated part. This study focused primarily on the damage that occurs during this ischemic period. An experimental system was implemented that allowed the observation of contractile function in totally isolated skeletal muscle after ischemia. Contractile function was selected as an indicator of ischemic damage because normal function is the ultimate goal of replantation. All experiments were performed on the rat extensor digitorum longus. The muscles were subjected to ischemic periods of 1.5, 3.0, and 5.0 hours and were stored in either a hypothermic (4 degrees C) or a room-temperature (23 degrees C) environment during the ischemic interval. After the ischemic period, all muscles were transferred to a tissue bath and were subjected to contractility testing, followed by fatigue testing. In both groups, muscle function decreased as the ischemic interval was increased. A significant difference in function between the normal control and the muscles of both ischemic groups implied that ischemic injury had occurred in the hypothermic and room-temperature muscles, even with the relatively short 1.5-hour ischemic interval. After each ischemic interval however, the hypothermic muscles produced significantly greater contractile force than the room-temperature muscles in both the contractility and the fatigue tests. After 1.5 hours of ischemia, the contractile force in the hypothermic group was about three times as great as that observed in the room-temperature group. These results indicated that muscle function after a period of totally isolated ischemia is protected by hypothermic preservation. They also support the advisability of storage of amputated parts and free muscle flaps in hypothermic environments before replantation even after relatively brief intervals of ischemia.     

Informing the patient

PURPOSE: To investigate the feasibility to use hydroxyethylstarch as an alternative deswelling additive in short-term preservation media. MATERIALS AND METHODS: Corneoscleral discs were prepared from pairs of eye balls of freshly slaughtered pigs. Corneas were stored in MEM-medium containing either 10% or 20% hydroxyethylstarch 450 000 at 4 degrees C in a refrigerator. Subsequently, the tissue was stored for 24 hours in organ culture at 37 degrees C in MEM-medium containing 10% fetal calf serum to detect latent endothelial cell damage. Mate corneas were treated the same except for being stored in Optisol GS during 4 degrees C storage. We determined corneal endothelial cell density, stromal thickness, and glucose concentration in the medium directly after preparation, after short-term storage at 4 degrees C, and after subsequent organ culture at 37 degrees C. Scanning electron microscopy of corneal endothelium was performed at each step during the experimental course. RESULTS: We did not observe any significant differences in endothelial-cell density between experimental groups and control groups. No decrease in endothelial-cell density was observed during the course of experiments. No increase in stromal thickness was determined in any group after short-term storage at 4 degrees C. Corneas stored in medium containing 20% hydroxyethylstarch showed a decrease in stromal thickness after short-term storage. After subsequent organ culture all corneas displayed a uniform stromal swelling. Glucose concentrations in the media decreased in all groups during the experiment. In scanning-electron microscopy we observed a reversible degeneration of cell borders after storage at 4 degrees C. Additionally, corneas stored in Optisol GS showed a reversible cobblestone appearance at this stage of the experiments. CONCLUSION: Hydroxyethylstarch appears to be an alternative to the use of dextran and chondroitin sulfate as a deswelling additive in corneal preservation media.