An isolated tumor perfusion model in mice

The role of stromal cells in the tumor microenvironment has been extensively characterized. We and others have shown that stromal cells may participate in several steps of the metastatic cascade. This protocol describes an isolated tumor perfusion model that enables studies of cancer and stromal cell shedding. It could also be used to study the effects of therapies interfering with the shedding of tumor cells or fragments, circulating (stem) cells or biomarkers. Primary tumors are grown in a microenvironment in which stromal cells express GFP ubiquitously. Tumors are implanted orthotopically or can be implanted ectopically. As a result, all tumor-associated stromal cells express GFP. This technique can be used to detect and study the role of stromal cells in tumor fragments within the circulation in mice. Studying the role of stromal cells in circulating tumor fragments using this model may take 2-10 weeks, depending on the growth rate of the primary tumor.     

Metabolic capability of rat hepatocytes isolated by perfusion and tissue slice techniques

The metabolic capability of hepatocytes prepared by the perfusion method (P cells) and the tissue slice method (S cells) has been compared using standardised procedures. Yields of P cells were four times greater than for S cells. Trypan blue exclusion viability and oxygen utilization were similar although the viability of S cells deteriorated faster with time. P cells had a lower endogenous rate of glycogenolysis and showed better glucagon stimulation than S cells. Similarly, P cells performed gluconeogenesis at a higher rate. However, there was no significant difference in the metabolism of the xenobiotic ethoxycoumarin. It is concluded that while S cells are probably satisfactory for studies of drug metabolism their use for work involving surface receptor binding and energy demanding processes should be questioned.     

Colorimetric assay for pluronic F-68 as measured in isolated rat liver perfusion systems

A colorimetric assay has been developed for the quantitation of Pluronic F-68, a nonionic detergent (surfactant) which is a polyoxypropylene-polyoxyethylene (POP-POE) block copolymer. We measured this substance in organic extracts of rat liver perfusates from livers which had been perfused with an oxygenated perfluorocarbon, FC-43 Emulsion (Oxypherol).     

Regulation of lactate and pyruvate levels in perfusion medium by the isolated rat liver

MAINTAINING a constant level of a metabolite in the blood presupposes a regulation mechanism. In our experiments with the isolated liver, in which we eliminated the peripheral tissue as donor and acceptor of substrates, the same lactate and pyruvate content is maintained in the perfusion medium as in rat blood. This discovery suggests a mechanism of coordination and control of blood substrates by the isolated organ.     

A comparative analysis of thermal blood perfusion measurement techniques

The object of this study was to devise a unified method for comparing different thermal techniques for the estimation of blood perfusion rates and to perform a comparison for several common techniques. The approach used was to develop analytical models for the temperature response for all combinations of five power deposition geometries (spherical, one- and two-dimensional cylindrical, and one- and two-dimensional Gaussian) and three transient heating techniques (temperature pulse-decay, temperature step function, and constant-power heat-up) plus one steady-state heating technique. The transient models were used to determine the range of times (the time window) when a significant portion of the transient temperature response was due to blood perfusion. This time window was defined to begin when the difference between the conduction-only and the conduction-plus-blood flow transient temperature (or power) responses exceeded a specified value, and to end when the conduction-plus-blood flow transient temperature (or power) reached a specified fraction of its steady-state value. The results are summarized in dimensionless plots showing the size of the time windows for each of the transient perfusion estimation techniques. Several conclusions were drawn, in particular: (a) low perfusions are difficult to estimate because of the dominance of conduction, (b) large heated regions are better suited for estimation of low perfusions, (c) noninvasive heating techniques are superior because they have the potential to minimize conduction effects, and (d) none of the transient techniques appears to be clearly superior to the others.     

Histone binding to isolated rat liver nuclei

Calf thymus histone H3 bound irreversibly to the isolated rat liver nuclei. The rate and extent of binding was a function of the incubation period and the concentration of both H3 and nuclei, but independent of the temperature. The binding was saturable and was inhibited by simultaneous presence of various histones. Approximately 94% of the bound H3 was associated with nuclear membrane fraction.     

Kinetic analysis of the preserved rat liver by isolated perfusion with ammonium chloride as a load

Oxygen consumption and urea synthesis from ammonium chloride (NH4Cl) were investigated in the liver preserved in University of Wisconsin solution at 4 degrees C for 24 hours using an isolated rat liver perfusion system in which the perfusate contained five different concentrations of NH4Cl. When a Michaelis-Menten equation was applied to oxygen consumption and urea synthesis against NH4Cl concentration, the preserved liver showed smaller increase in oxygen consumption rate and larger Km of urea synthesis for NH4Cl than the fresh liver. The ratio of respiration velocity without any substrate to maximal velocity (v/Vmax), which reflects the mitochondrial functional reserve, was 55.9 +/- 4.1% and 41.5 +/- 4.8% in the preserved and fresh liver, respectively (p less than 0.05). From the viewpoint of work-cost relationship, it was shown that the mitochondrial function in the preserved liver was deteriorated. On the other hand, conventional mitochondrial study after rewarming and reoxygenation but before NH4Cl load revealed no deterioration of mitochondrial function after preservation. These results indicate that it is necessary to take the metabolic load on the reperfused liver into account when assessing graft viability, and that high v/Vmax suggests decrease in the reserve of mitochondrial function under consideration of the metabolic load.     

The isolated perfused rat liver: standardization of a time-honoured model

For many years, the isolated perfused rat liver (IPRL) model has been used to investigate the physiology and pathophysiology of the rat liver. This in vitro model provides the opportunity to assess cellular injury and liver function in an isolated setting. This review offers an update of recent developments regarding the IPRL set-up as well as the viability parameters that are used, with regards to liver preservation and ischaemia and reperfusion mechanisms.A review of the literature was performed into studies regarding liver preservation or liver ischaemia and reperfusion. An overview of the literature is given with particular emphasis on perfusate type and volume, reperfusion pressure, flow, temperature, duration of perfusion, oxygenation and on applicable viability parameters (liver damage and function).The choice of IPRL set-up depends on the question examined and on the parameters of interest. A standard technique is cannulation of the portal vein, bile duct and caval vein with pressure-controlled perfusion at 20 cm H2O (15 mmHg) to reach a perfusion flow of approximately 3 mL/min/g liver weight. The preferred perfusion solution is Krebs-Henseleit buffer, without albumin. The usual volume is 150-300 cm3, oxygenated to a pO2 of more than 500 mmHg. The temperature of the perfusate is maintained at 37 degrees C. Standardized markers should be used to allow comparison with other experiments.     

Contribution of perfusion techniques to the evaluation of the hemostatic effectiveness of platelet concentrates.

Perfusion systems allowing the morphometric analysis of platelet interactions with vessel subendothelium under flow conditions have been applied to evaluate the quality and function of stored platelets. Studies performed in vitro indicate that despite the existence of storage lesions, platelets in concentrates stored for up to 5 days retain their ability to interact with the subendothelium. Perfusion studies ex vivo with nonanticoagulated blood from anemic-thrombocytopenic patients have shown the critical hemorrheological role of red blood cells facilitating platelet interactions with subendothelium. Similar studies performed on severely thrombocytopenic patients who received transfusions of platelets stored at 4 degrees C indicate that incompletely viable platelets can contribute to primary hemostasis through procoagulant mechanisms. The latter results suggest that storage lesions which contribute to impairment of platelet function may result in enhancement of platelet procoagulant activities. Perfusion techniques have contributed to the evaluation of the hemostatic effectiveness of platelet concentrates. These techniques will provide a useful model to test the impact of new storage technologies on platelet hemostatic function.     

An evaluation of ways of using equilibrium dialysis to quantify the binding of ligand to macromolecule.

1. The effect of systematic error (loss of ligand, complex or macromolecule) on three of the experimental designs by which equilibrium dialysis may be used to quantify the interaction of ligand and macromolecule is examined theoretically, and the design that is least sensitive to systematic error is identified. 2. Thirteen methods for fitting the binding isotherm to experimental data are compared by using them to analyse simulated data containing random error, and the most reliable method is identified.     

Perfusion of isolated rat liver. Utilization of a perfusion without heparin. Validity of the preparation]

The blood and liver giver animals are given "Tromexan" for a period of three days. The blood defibrination is finished off by shaking. The perfusion is made of defibrinated blood to which is added a compounding of mineral salts, albumin and glucose in adequate proportions. The fluid is used during 150 minutes with a biliary flow of 4 ul/minute (instead of 8 in perfusions with heparine). The validity of the preparation is tested by biliary acids, cholesterol and Brom Sulfon Phtalein biliary elimination research. This fluid can be used when heparin is avoided: for example in a case of investigation of fat emulsion scrubbing.     

Long-term perfusion of the isolated rat liver maintenance of its functional state by use of a fluorocarbon emulsion

In order to establish a long-term perfusion system a fluorocarbon emulsion was developed and employed for the perfusion of isolated rat liver up to 20 h. Its suitability for maintaining some specific organ functions was compared with that of a commonly used red cell-containing medium. All livers perfused with the fluorocarbon medium released phosphoglucose isomerase, glutamate-oxaloacetate transaminase and glutamate dehydrogenase almost linearly at a low basal rate, glutamate dehydrogenase release beginning after 5 h perfusion. In contrast to that, a certain percentage of the livers perfused with the red cell-containing medium showed an exponential enzyme release which was over two standard deviations above the mean of the livers perfused with fluorocarbon medium, the values being 25% for phosphoglucose isomerase, 38% for glutamate-oxaloacetate transmiinase and 87% for glutamate dehydrogenase after 10 h of perfusion. In each case the exponential release of phosphoglucose isomerase signaled the functional impairment of the preparation.Thus, defining those livers as “intact” only if their phosphoglucose isomerase release was within two standard deviations of the means of the fluorocarbon-perfused livers, the following liver functions were examined in fluorocarbon-perfused and, for comparison, in “intact” cell-perfused livers during a 10-h period: Metabolite state, galactose elimination from the perfusate, induction of tyrosine aminotransferase by dexamethasone, and gluconeogenesis from lactate and bile production. It was found that the fluorocarbon medium provided at least the same or an even better hepatic function than did the red cell-containing medium. However, while in red cell-perfused livers functional impairment always occurred at various percentages under the conditions mentioned above, this was never observed with the fluorocarbon medium.Electron microscopic examination of the livers perfused with the fluorocarbon medium showed no disturbance of the mitochondrial matrix and cristae after a 10 h perfusion. While within a large number of liver cells the ergastoplasm was seen in normal appearance, in other liver cells the cisternae of rough endoplasmic reticulum were vacuolated.Some important physicochemical data of the fluorocarbon medium such as O₂ capacity, viscosity and particle size are reported, and the technique and the problems of its preparation are described. The advantages of the fluorocarbon medium for long as well as short term perfusion experiments are discussed.     

The attachment of UDP-hexosamines to the ribosomes isolated from rat liver

The binding of UDP-N-acetylhexosamines with purified ribosomes was studied and it was found that the radioactive nucleotides can be attached to these particles. The radioactivity of the purified ribosomal pellet depends on the amounts of ribosomes and UDP-N-acetylhexosamines. Some characteristics of the binding system indicate that the attachment of UDP-sugar to ribosome does not require the participation of glycosyltransferases. The results of the competition experiment would suggest that there are specific sites on ribosomes for the binding of UDP-N-acetylglucosamine.