Isolated sheep heart hypothermic (5–13 °C) perfusion with fresh blood: Successful preservation for 24–72 hours with continuous strong ventricular activity

Isolated lamb hearts perfused with fresh whole blood at 10 and 13 °C in an ex vivo perfusion circuit continuously contracted at a rate of 15 to 20 times/min with a peak left ventricular systolic pressure (LVPSP) up to 70 mm Hg. These contractions persisted for the duration of the hypothermic study, up to three days with no change in vascular resistance. On rewarming to 38 °C, the hearts resumed regular and efficient contractions. Hearts perfused at 5 °C, however, exhibited no electrical or mechanical activity during hypothermic preservation and were uniformly poorly preserved.Quality of heart preservation was improved if, prior to final cooling, hearts were first rewarmed to 38 °C, followed by cooling. Change of the support animal, or interruption of flow of fresh blood into the perfusion circuit, resulted in cessation of ventricular contractions, ventricular fibrillation, and poor organ preservation.     

Steps for the Autologous Ex vivo Perfused Porcine Liver-kidney Experiment

The use of ex vivo perfused models can mimic the physiological conditions of the liver for short periods, but to maintain normal homeostasis for an extended perfusion period is challenging. We have added the kidney to our previous ex vivo perfused liver experiment model to reproduce a more accurate physiological state for prolonged experiments without using live animals. Five intact livers and kidneys were retrieved post-mortem from sacrificed pigs on different days and perfused for a minimum of 6 hr. Hourly arterial blood gases were obtained to analyze pH, lactate, glucose and renal parameters. The primary endpoint was to investigate the effect of adding one kidney to the model on the acid base balance, glucose, and electrolyte levels. The result of this liver-kidney experiment was compared to the results of five previous liver only perfusion models. In summary, with the addition of one kidney to the ex vivo liver circuit, hyperglycemia and metabolic acidosis were improved. In addition this model reproduces the physiological and metabolic responses of the liver sufficiently accurately to obviate the need for the use of live animals. The ex vivo liver-kidney perfusion model can be used as an alternative method in organ specific studies. It provides a disconnection from numerous systemic influences and allows specific and accurate adjustments of arterial and venous pressures and flow.     

Criteria for Viability Assessment of Discarded Human Donor Livers during Ex Vivo Normothermic Machine Perfusion

Although normothermic machine perfusion of donor livers may allow assessment of graft viability prior to transplantation, there are currently no data on what would be a good parameter of graft viability. To determine whether bile production is a suitable biomarker that can be used to discriminate viable from non-viable livers we have studied functional performance as well as biochemical and histological evidence of hepatobiliary injury during ex vivo normothermic machine perfusion of human donor livers. After a median duration of cold storage of 6.5 h, twelve extended criteria human donor livers that were declined for transplantation were ex vivo perfused for 6 h at 37°C with an oxygenated solution based on red blood cells and plasma, using pressure controlled pulsatile perfusion of the hepatic artery and continuous portal perfusion. During perfusion, two patterns of bile flow were identified: (1) steadily increasing bile production, resulting in a cumulative output of ≥30 g after 6 h (high bile output group), and (2) a cumulative bile production <20 g in 6 h (low bile output group). Concentrations of transaminases and potassium in the perfusion fluid were significantly higher in the low bile output group, compared to the high bile output group. Biliary concentrations of bilirubin and bicarbonate were respectively 4 times and 2 times higher in the high bile output group. Livers in the low bile output group displayed more signs of hepatic necrosis and venous congestion, compared to the high bile output group. In conclusion, bile production could be an easily assessable biomarker of hepatic viability during ex vivo machine perfusion of human donor livers. It could potentially be used to identify extended criteria livers that are suitable for transplantation. These ex vivo findings need to be confirmed in a transplant experiment or a clinical trial.     

Effects of hypothermic kidney preservation on the isolated perfused kidney: a comparison of reperfusion methods

Two isolated-perfused kidney methods were used to study the effects of hypothermic preservation on renal function in dog kidneys. The isolated-machine-perfused kidney (IMPK) used an in vitro perfusion technique--the perfusate was a Krebs-bicarbonate type delivered to the kidney at 37 degrees C by a mechanical pump at a constant pressure (100 mm Hg). The isolated-blood-perfused kidney (IBPK) utilized transplantation of the preserved kidney to the femoral vasculature. Renal function (urine analysis) was determined over a 1-hr reperfusion interval and included GFR (creatinine clearance), urine formation, and Na+ reabsorption. Kidneys preserved for only 24 hr by cold storage in either Collins'--C3 solution or in hypotonic citrate and kidneys hypothermically perfused for 24 hr demonstrated greater retention of renal function when reperfused by blood (IBPK) than with the in vitro perfusate (IMPK). The GFR was reduced by 38-58% when tested with the IBPK, but by 80-90% when tested with the IMPK. Na+ reabsorption was normal (97%) with blood reperfusion but was reduced to 36-50% in cold-stored kidneys and 82% in hypothermically perfused kidneys determined by machine reperfusion (IMPK). However, kidneys perfused for 72 hr demonstrated more similar renal functions when tested by either IMPK or IBPK. GFR was reduced to 20% (IBPK) and 11% (IMPK) and Na+ reabsorption averaged 76-85% (IBPK or IMPK). These results suggest that either reperfusion method is suitable for determining the effects of renal preservation on kidney function in kidneys preserved for 72 hr but, for short-term preserved kidneys (24 hr), the IBPK model may be preferred.     

Renal preservation by hypothermic perfusion. III. The lack of influence of pulsatile flow

Rabbit kidneys were perfused at 5 °C with a plasma-like solution containing dextran 70 and bovine serum albumin, and were autografted 24 hr later. One experimental group was perfused at a constant pressure of 40 mm Hg, while the second group was perfused with a pulsatile pressure having a root-mean-square (rms) equivalent of 40 mm Hg; the pulse pressure was 15 mm Hg and the pulse rate 60 min^?1 The behaviour of the two groups during perfusion and after transplantation was similar. It is concluded that pulsatile flow is without benefit during renal preservation by hypothermic perfusion.     

Functional preservation of the mammalian kidney. IV. Functional effects of perfusion with dimethyl sulfoxide (DMSO) at normothermia

Rabbit kidneys were perfused at 37 °C with various concentrations of DMSO in a K⁺-Mg²⁺-rich perfusate. The effects of DMSO on various functional parameters of the rabbit kidney perfused for 60 min were compared with the functional effects of perfusion without DMSO under the same conditions. DMSO produced deviations in vascular resistance and perfusate flow rate from control values. In kidneys perfused with 1.4 and 2.8 m DMSO these vascular changes resulted in changes in GFR at relatively unchanged filtration fractions. The closely parallel relationship between changes in GFR and urine flow rate in all groups indicates that perfusion per se or perfusion with DMSO may shift the regulation of urine flow rate from tubular reabsorption, which obtains in the in vivo situation, to glomerular filtration. This view was supported by the relatively unchanged parameters of Na⁺ reabsorption and fractional water excretion during perfusion with all concentrations of DMSO. Additionally, DMSO perfusion resulted in significantly greater weight gains than those observed in kidneys perfused without DMSO, and significantly depressed clearances of PAH, with 2.1 and 2.8 m DMSO.     

Renal preservation by hypothermic perfusion. IV. The use of gelatin polypeptides as the sole colloid

Rabbit kidneys were perfused with a solution of extracellular electrolyte composition, rendered hypertonic with glucose and containing 1.75% Haemaccel (Hoechst) as the sole colloid. Perfusions were carried out at 10 °C for 24 and 48 hr using perfusion pressures of 20 or 40 mm Hg. Function, was tested by autografting with immediate contralateral nephrectomy. All the kidneys perfused at 20 mm Hg for 24 hr showed excellent life-sustaining function and 7 of 10 survived in the 40 mm Hg group; the difference was not statistically significant. However, all the kidneys perfused for 48 hr failed to sustain life, and histological examination revealed extensive breakdown of the microcirculation. The 24 hr results were similar to those previously obtained with an albumin-based perfusate, but the 48-hr results were inferior: However, the obvious advantages of a well-standardised, cheap, and easily stored perfusate are such as to justify further study of gelatin-derived colloids for organ preservation.     

Persufflation (or gaseous oxygen perfusion) as a method of organ preservation

Improved preservation techniques have the potential to improve transplant outcomes by better maintaining donor organ quality and by making more organs available for allotransplantation. Persufflation, (PSF, gaseous oxygen perfusion) is potentially one such technique that has been studied for over a century in a variety of tissues, but has yet to gain wide acceptance for a number of reasons. A principal barrier is the perception that ex vivo PSF will cause in vivo embolization post-transplant. This review summarizes the extensive published work on heart, liver, kidney, small intestine and pancreas PSF, discusses the differences between anterograde and retrograde PSF, and between PSF and other conventional methods of organ preservation (static cold storage, hypothermic machine perfusion). Prospective implications of PSF within the broader field of organ transplantation, and in the specific application with pancreatic islet isolation and transplant are also discussed. Finally, key issues that need to be addressed before PSF becomes a more widely utilized preservation strategy are summarized and discussed.     

The application of fluidics technology for organ preservation

A prototype design of a portable, pulsatile, perfusion preservation device based on a novel application of fluidics technology was tested to evaluate its ability to oxygenate preservation solution and to examine the relationship between organ resistance, perfusion pressure, and perfusion flow characteristics. The effects of organ resistance on pulse rate, perfusion pressure, and perfusion flow were modeled. Interstitial PO2 in canine hearts stored at 4 degrees C for 12 hours in the fluidics device (n = 5) and in static hypothermic storage (n = 5) was also compared. Increasing outflow resistance did not have an effect on operating frequency of the fluidics actuator. Perfusion pressure rose as outflow resistance was increased, and the flow of preservation solution decreased proportionately. The PO2 of the preservation solution increased to 300 mm Hg in two hours and reached a plateau that exceeded 400 mm Hg within six hours. The aortic flow profile during pulsatile perfusion resembled a square wave function with a mean pulse duration of 0.30 +/- 0.05 seconds. Oxygen delivery by the fluidics perfusion device exceeded the oxygen requirements of the hypothermically preserved organs at all resistance levels. Initial interstitial PO2 in the hearts of both groups was greater than 150 mm Hg. In perfused hearts, PO2 declined 30% by the 12th hour, whereas complete depletion of oxygen was noted in the static storage group within six hours. The fluidics organ perfusion/transport apparatus weighs less than 18 kg, uses no electrical power, and can operate continuously for 10 to 12 hours expending 780 L of oxygen.     

Technique of Subnormothermic Ex Vivo Liver Perfusion for the Storage,Assessment, and Repair of Marginal Liver Grafts

The success of liver transplantation has resulted in a dramatic organ shortage. In most transplant regions 20-30% of patients on the waiting list for liver transplantation die without receiving an organ transplant or are delisted for disease progression. One strategy to increase the donor pool is the utilization of marginal grafts, such as fatty livers, grafts from older donors, or donation after cardiac death (DCD). The current preservation technique of cold static storage is only poorly tolerated by marginal livers resulting in significant organ damage. In addition, cold static organ storage does not allow graft assessment or repair prior to transplantation.These shortcomings of cold static preservation have triggered an interest in warm perfused organ preservation to reduce cold ischemic injury, assess liver grafts during preservation, and explore the opportunity to repair marginal livers prior to transplantation. The optimal pressure and flow conditions, perfusion temperature, composition of the perfusion solution and the need for an oxygen carrier has been controversial in the past.In spite of promising results in several animal studies, the complexity and the costs have prevented a broader clinical application so far. Recently, with enhanced technology and a better understanding of liver physiology during ex vivo perfusion the outcome of warm liver perfusion has improved and consistently good results can be achieved.This paper will provide information about liver retrieval, storage techniques, and isolated liver perfusion in pigs. We will illustrate a) the requirements to ensure sufficient oxygen supply to the organ, b) technical considerations about the perfusion machine and the perfusion solution, and c) biochemical aspects of isolated organs.     

Impact of normothermic preservation with extracellular type solution containing trehalose on rat kidney grafting from a cardiac death donor

Background

The aim of this study was to investigate factors that may improve the condition of a marginal kidney preserved with a normothermic solution following cardiac death (CD) in a model of rat kidney transplantation (RTx).

Methods

Post-euthanasia, Lewis (LEW) donor rats were left for 1 h in a 23°C room. These critical kidney grafts were preserved in University of Wisconsin (UW), lactate Ringer''s (LR), or extracellular-trehalose-Kyoto (ETK) solution, followed by intracellular-trehalose-Kyoto (ITK) solution at 4, 23, or 37°C for another 1 h, and finally transplanted into bilaterally nephrectomized LEW recipient rats (n = 4–6). Grafts of rats surviving to day 14 after RTx were evaluated by histopathological examination. The energy activity of these marginal rat kidneys was measured by high-performance liquid chromatography (HPLC; n = 4 per group) and fluorescence intensity assay (n = 6 per group) after preservation with UW or ETK solutions at each temperature. Finally, the transplanted kidney was assessed by an in vivo luciferase imaging system (n = 2).

Results

Using the 1-h normothermic preservation of post-CD kidneys, five out of six recipients in the ETK group survived until 14 days, in contrast to zero out of six in the UW group (p<0.01). Preservation with ITK rather than ETK at 23°C tended to have an inferior effect on recipient survival (p = 0.12). Energy activities of the fresh donor kidneys decreased in a temperature-dependent manner, while those of post-CD kidneys remained at the lower level. ETK was superior to UW in protecting against edema of the post-CD kidneys at the higher temperature. Luminescence intensity of successful grafts recovered within 1 h, while the intensity of grafts of deceased recipients did not change at 1 h post-reperfusion.

Conclusions

Normothermic storage with extracellular-type solution containing trehalose might prevent reperfusion injury due to temperature-dependent tissue edema.     

Effect of temperature upon heart preservation for transplantation.

In this work we studied the effect of three different temperatures (7 °, 15 °, and 30 °C) on heart preservation. The best temperature for 24 hr pulsatile perfusion of canine hearts was 7 °C. Hearts perfused at this temperature showed no evidence of abnormal preservation changes nor of histological damage immediately upon transplantation. If the temperature was increased to 15 ° or 30 °C, moderate to severe preservation and histological damage were observed, and only three out of 10 dogs survived upon heart implantation.     

Modulating biochemical perturbations during 72-hour machine perfusion of kidneys: role of preservation solution

This study documents renal biochemistry during hypothermic machine perfusion of kidneys. It is intended to demonstrate that a comprehensive evaluation of organ viability during ex-vivo preservation is needed to increase the number of organs available for transplantation and to reduce the current renal discard rate. Porcine kidneys were hypothermically machine perfused for 72 h with either Unisol-UHK or Belzer-Machine Perfusion Solution, (Belzer-MPS). Renal perfusate samples were periodically collected and biochemically analyzed. Significant differences were measured in the renal metabolic activity between the two experimental groups while similar values for traditional parameters such as renal flow rate and vascular resistance values were recorded. The effluent of UHK perfused kidneys showed strong metabolites and NH(4)(+) dynamics (P<0.05 vs. baseline), while the Belzer-MPS kidneys metabolic activity led to little or no change of the effluent biochemistry relative to baseline.     

Ex Situ Normothermic Machine Perfusion of Donor Livers

In contrast to conventional static cold preservation (0-4 °C), ex situ machine perfusion may provide better preservation of donor livers. Continuous perfusion of organs provides the opportunity to improve organ quality and allows ex situ viability assessment of donor livers prior to transplantation. This video article provides a step by step protocol for ex situ normothermic machine perfusion (37 °C) of human donor livers using a device that provides a pressure and temperature controlled pulsatile perfusion of the hepatic artery and continuous perfusion of the portal vein. The perfusion fluid is oxygenated by two hollow fiber membrane oxygenators and the temperature can be regulated between 10 °C and 37 °C. During perfusion, the metabolic activity of the liver as well as the degree of injury can be assessed by biochemical analysis of samples taken from the perfusion fluid. Machine perfusion is a very promising tool to increase the number of livers that are suitable for transplantation.     

Cold storage preservation of islet and pancreas grafts as assessed by in vivo function after transplantation to diabetic hosts

The major goal of hypothermic (4–8 °C) preservation of intact pancreases or isolated islets will be to provide sufficient time for HLA typing, cross matching, selection, and preparation of recipients—logistical efforts requiring 12–72 hr for clinical kidney transplantation, usually <48 hours. Some investigators have studied in vitro function of islets after cold storage, but the critical test of viability—permanent restoration of normoglycemia after transplantation to diabetic recipients—has been tested in only a few experiments. Reversal of hyperglycemia by syngeneic or autogenic transplants in diabetic animals has been achieved after CS of dispersed pancreatic tissue from neonatal rats in GIB media for ? 146 hr, adult dogs in TCM 199 for ?24 hr, and adult DL-ethionine-treated rats in RPMI 1640 for ?72 hr. In the neonatal rat donor model, intravenous glucose tolerance test (IVGTT) results were similar in recipients of fresh or stored islets; in the dog model, IVGTT test results were variable, but generally inferior in recipients of stored as compared to fresh islets; in the adult rat donor model, recipients of ?24-hr coldstorage islets had insulin and IVGTT K values similar to those of recipients of fresh islets, but the success rate progressively declined for CS times >24 hr. Various agents were added to the media, but the need or the optimal concentrations were not critically determined by using different recipes for different groups of recipients. Cold storage of intact pancreas autografts has been tested in dogs; simple electrolyte solutions are satisfactory for 24 hr, but only a silica gel-filtered plasma-based solution has been reliable for 48 hr. Pulsatile machine perfusion (PMP) of canine pancreas grafts for 24 hr has had a success rate similar to CS in some experiments and lower in others. PMP has been almost totally unreliable for >24 hr. Further refinements are needed if preservation of islets for >24 hr and pancreases for >48 hr are to be consistently successful. If current experimental techniques are effective for human islets or pancreases, however, these times are sufficient to complete the logistical maneuvers required before transplantation.     

The influence of storage temperature during machine perfusion on preservation quality of marginal donor livers

Background

Although non-heart-beating donors have the potential to increase the number of available organs, the livers are used very seldom because of the risk of primary non-function. There is evidence that machine perfusion is able to improve the preservation of marginal organs, and therefore we evaluated in our study the influence of the perfusate temperature during oxygenated machine perfusion on the graft quality.

Methods

Livers from male Wistar rats were harvested after 60-min warm ischemia induced by cardiac arrest. The portal vein was cannulated and the liver flushed with Lifor® (Lifeblood Medical, Inc.) organ preservation solution for oxygenated machine perfusion (MP) at 4, 12 or 21 °C. Other livers were flushed with HTK and stored at 4 °C by conventional cold storage (4 °C-CS). Furthermore two groups with either warm ischemic damage only or without any ischemic damage serve as control groups. After 6 h of either machine perfusion or cold storage all livers were normothermic reperfused with Krebs–Henseleit buffer, and functional as well as structural data were analyzed.

Results

Contrary to livers stored by static cold storage, machine perfused livers showed independently of the perfusate temperature a significantly decreased enzyme release of hepatic transaminases (ALT) during isolated reperfusion. Increasing the machine perfusion temperature to 21 °C resulted in a marked reduction of portal venous resistance and an increased bile production.

Conclusions

Oxygenated machine perfusion improves viability of livers after prolonged warm ischemic damage. Elevated perfusion temperature of 21 °C reconstitutes the hepatic functional capacity better than perfusion at 4 or 12 °C.     

Hypothermic pulsatile perfusion of human pancreas: Preliminary technical feasibility study based on histology

BackgroundThere are currently two approaches to hypothermic preservation for most solid organs: static or dynamic. Cold storage is the main method used for static storage (SS), while hypothermic pulsatile perfusion (HPP) and other machine perfusion-based methods, such as normothermic machine perfusion and oxygen persufflation, are the methods used for dynamic preservation. HPP is currently approved for kidney transplantation.MethodsWe evaluated, for the first time, the feasibility of HPP on 11 human pancreases contraindicated for clinical transplantation because of advanced age and/or history of severe alcoholism and/or abnormal laboratory tests. Two pancreases were used as SS controls, pancreas splitting was performed on 2 other pancreases for SS and HPP and 7 pancreases were tested for HPP. HPP preservation lasted 24 h at 25 mmHg. Resistance index was continuously monitored and pancreas and duodenum histology was evaluated every 6 h.ResultsThe main finding was the complete absence of edema of the pancreas and duodenum at all time-points during HPP. Insulin, glucagon and somatostatin staining was normal. Resistance index decreased during the first 12 h and remained stable thereafter.Conclusion24 h hypothermic pulsatile perfusion of marginal human pancreas-duodenum organs was feasible with no deleterious parenchymal effect. These observations encourage us to further develop this technique and evaluate the safety of HPP after clinical transplantation.     

Incorporation of intravenously injected (2-(14)C) acetate into tissue lipids of hamsters during the last hour of 3-, 6-, and 24-hour periods of hypothermia.

The in vivo incorporation of total lipid ¹⁴C from [2-¹⁴C]acetate is decreased in kidney, liver, and small intestine tissue from 3-, 6-, and 24-hr hypothermic hamsters compared to tissues from normothermic animals. The length of time in hypothermia affects hamster tissues differently; thus, ¹⁴C activity: decreases with time in kidney; increases with time in liver; and increases at 3 and 6 hr but decreases from 6 to 24 hr of hypothermia in small intestine.Tissues from hypothermic hamsters incorporated a greater percentage of [2-¹⁴C] acetate into free sterols and diglycerides and a smaller percentage into phospholipid than did corresponding tissues from normothermic hamsters.The percentage of total fatty acid ¹⁴C activity found as polyunsaturated fatty acid ¹⁴C activity increases in hypothermic kidney, liver, and small intestine with a decrease in the percentage of ¹⁴C activity measured in the saturated fatty acids. Esterification of fatty acid was inhibited in all tissues taken from hypothermic hamsters.     

Lung transplantation protection after warm ischemia and 1 day preservation

This study attemps to determine the role of colloid hyperosmolar solutions in the preservation of nonischemic and ischemic lungs. Four groups of animals were studied: Control fresh lung allografts and lungs stored under hypothermic storage (4–7 °C) in a modified silica gel fraction (MSGF) for 24 hr with or without warm ischemia (0, 30, 60 min) prior to storage. Fresh lungs lived an average of 14.5 days after transplantation. Stored nonischemic lungs survived an average of 11.2 days, and ischemic (30, 60 min) stored lungs remained alive for an average of 10.5 and 9.2 days. There were no significant differences in survival between the fresh and preserved allografts. Pneumonia and/or rejection occurred in 71% of all groups. MSGF appears to be a good solution for 24-hr hypothermic storage of nonischemic and ischemic lungs.