Cryopreservation of precision-cut tissue slices for application in drug metabolism research.

Cryopreservation of tissue slices greatly facilitates their use in drug metabolism research, leading to efficient use of human organ material and a decrease of laboratory animal use. In the present review, various mechanisms of cryopreservation such as equilibrium slow freezing, rapid freezing and vitrification, and their application to cryopreservation of tissue slices are discussed as well as the viability parameters often used to evaluate the success of cryopreservation. Equilibrium freezing prevents intracellular ice formation by inducing cellular dehydration, but (large) ice crystals are still formed in the interstitial space of the slices. Upon rapid freezing, (small) intra- and extracellular ice crystals are formed which slices from some tissues can resist. Vitrification prevents the formation of both intra- and extracellular ice crystals while an amorphous glass is formed of the slice liquid constituents. To vitrify, however, high molarity solutions of cryoprotectants are required that may be toxic to the slices. The use of mixtures of high molarity of cryoprotectants overcomes this problem. We conclude that vitrification is the approach that most likely will lead to the development of universal cryopreservation methods for tissue slices of various organs from various animal species. In the future this may lead to the formation of a tissue slice bank from which slices can be derived at any desirable time point for in vitro experimentation.

Incubation at 37 degrees C prior to cryopreservation decreases viability of liver slices after cryopreservation by rapid freezing.

Precision-cut liver slices are to some extent resistant to ice formation induced by rapid freezing. Susceptibility to rapid freezing damage has been shown to be (partly) dependent on intrinsic properties of cells. In the present study an attempt was made to decrease the susceptibility of rat liver slices for rapid freezing damage: the slices were pre-incubated at 37 degrees C under oxygen, prior to cryopreservation to recover from low ATP levels, impaired ion regulation and cell swelling induced by their preparation. It was shown that, unexpectedly, recovery of cellular homeostasis prior to the cryopreservation procedure by the 37 degrees C pre-incubation markedly decreased viability of rapidly frozen slices (in which ice was formed), but not of vitrified slices (in which no ice was formed), in a time- and temperature-dependent manner. UW was found to protect slices from this 'warm pre-incubation phenomenon.' Apparently, pre-incubation prior to freezing causes certain cellular alterations that render slices more susceptible to rapid freezing damage.

Comparison of in vitro preparations for semi-quantitative prediction of in vivo drug metabolism.

Various in vitro preparations were compared with respect to their ability to mimic in vivo metabolism. For this purpose, S9-liver homogenate, microsomes, cryopreserved hepatocytes, cryopreserved liver slices and fresh liver, lung, kidney, and intestinal slices were incubated with three drugs in development, which are metabolized in vivo by a wide range of biotransformation pathways. Metabolites were identified and quantified with liquid chromatography-mass spectometry/UV from the in vitro incubations and compared with metabolite patterns in feces, urine, and bile of dosed rats. In vitro systems with intact liver cells produced the same metabolites as the rat in vivo and are a valuable tool to study drug metabolism. Phase I metabolites were almost all conjugated in intact cells, whereas S9-homogenate only conjugated by sulfation and N-acetylation. Microsomes and S9-homogenate are useful to study phase I metabolism but not for the prediction of in vivo metabolism. Extra-hepatic organ slices did not form any metabolites that were not produced by liver cells, but the relative amounts of the various metabolites differed considerably. Small intestinal slices were more active than liver slices in the formation of the N-glucuronide of compound C, which is the major metabolite in vivo. When the relative contribution of liver and small intestinal slices to the metabolism of this compound was taken into account, it appeared that the in vivo metabolite pattern could be well predicted. Results indicate that for adequate prediction of in vivo metabolism, fresh or cryopreserved liver slices or hepatocytes in combination with slices of the small intestines should be used.

Water crystallization within rat precision-cut liver slices in relation to their viability.

This study examined whether tissue vitrification, promoted by partitioning within the tissue, could be the mechanism explaining the high viability of rat liver slices, rapidly frozen after preincubation with 18% Me2SO or VS4 (a 7.5 M mixture of Me2SO, 1,2-propanediol, and formamide with weight ratio 21.5:15:2.4). To achieve this, we first determined the extent to which crystallization or vitrification occurred in cryoprotectant solutions (Me2SO and VS4) and within liver slices impregnated with these solutions. Second, we determined how these events were related to survival of slices after thawing. Water crystallization was evaluated by differential scanning calorimetry and viability was determined by histomorphological examination of the slices after culturing at 37 degrees C for 4 h. VS4-preincubated liver slices indeed behaved differently from bulk VS4 solution, because, when vitrified, they had a lower tendency to devitrify. Vitrified VS4-preincubated slices that were warmed sufficiently rapid to prevent devitrification had a high viability. When VS4 was diluted (to 75%) or if warming was not fast enough to prevent ice formation, slices had a low viability. With 45% Me2SO, low viability of cryopreserved slices was caused by cryoprotectant toxicity. Surprisingly, liver slices preincubated with 18% Me2SO or 50% VS4 had a high viability despite the formation of ice within the slice. In conclusion, tissue vitrification provides a mechanism that explains the high viability of VS4-preincubated slices after ultrarapid freezing and thawing (>800 degrees C/min). Slices that are preincubated with moderately concentrated cryoprotectant solutions (18% Me2SO, 50% VS4) and cooled rapidly (100 degrees C/min) survive cryopreservation despite the formation of ice crystals within the slice.

Increased post-thaw viability and phase I and II biotransformation activity in cryopreserved rat liver slices after improvement of a fast-freezing method.

An existing cryopreservation method for liver slices applies 12% dimethylsulfoxide and rapid freezing. We found that cells in rat liver slices cryopreserved in this manner deteriorated rapidly upon culturing. To improve this cryopreservation method, we varied the dimethylsulfoxide concentration (0, 12, 18, and 30%), the cryopreservation medium (Williams medium E, fetal calf serum, and University of Wisconsin medium), slice thickness, and the storage period at 4 degrees C during slice preparation before cryopreservation. After thawing, slices were cultured for 4 h at 37 degrees C before their viability was evaluated by their potassium content and the number of intact cells determined histomorphologically. The biotransformation capacity of liver slices cryopreserved by the improved method was assessed by testosterone oxidation, hydroxycoumarin sulfation, and glucuronidation. Best results were obtained with 18% dimethylsulfoxide in Williams medium E: the potassium content of cryopreserved slices was higher than 65%, and the number of intact cells was higher than 60% of that in fresh slices; with 12% dimethylsulfoxide, potassium content was less than 40%, and the number of intact cells was less than 30%. Results did not differ between the three cryopreservation media. Viability of thin slices (8-10 cell layers) was better maintained than that of thicker slices (>14 cell layers). Storage at 4 degrees C of slices before cryopreservation decreased viability after cryopreservation. Both oxidative and conjugation activities were better than 60% of fresh values. Although results varied, slices cryopreserved with this improved method and cultured for 4 h retained viability between 50 and 80%, and biotransformation activity between 60 and 90% of fresh slices.

Assessment of some critical factors in the freezing technique for the cryopreservation of precision-cut rat liver slices.

A number of studies on the cryopreservation of precision-cut liver slices using various techniques have been reported. However, the identification of important factors that determine cell viability following cryopreservation is difficult because of large differences between the various methods published. The aim of this study was to evaluate some important factors in the freezing process in an effort to find an optimized approach to the cryopreservation of precision-cut liver slices. A comparative study of a slow and a fast freezing technique was carried out to establish any differences in tissue viability for a number of endpoints. Both freezing techniques aim at the prevention of intracellular ice formation, which is thought to be the main cause of cell death after cryopreservation. Subsequently, critical variables in the freezing process were studied more closely in order to explain the differences in viability found in the two methods in the first study. For this purpose, a full factorial experimental design was used with 16 experimental groups, allowing a number of variables to be studied at different levels in one single experiment. It is demonstrated that ATP and K(+) content and histomorphology are sensitive parameters for evaluating slice viability after cryopreservation. Subsequently, it is shown that freezing rate and the cryopreservation medium largely determine the residual viability of liver slices after cryopreservation and subsequent culturing. It is concluded that a cryopreservation protocol with a fast freezing step and using William's Medium E as cryopreservation medium was the most promising approach to successful freezing of rat liver slices of those tested in this study.

Importance of AMPA receptors for hippocampal synaptic plasticity but not for spatial learning.

Gene-targeted mice lacking the L-alpha-amino-3-hydroxy-5-methylisoxazole-4-propionate (AMPA) receptor subunit GluR-A exhibited normal development, life expectancy, and fine structure of neuronal dendrites and synapses. In hippocampal CA1 pyramidal neurons, GluR-A-/- mice showed a reduction in functional AMPA receptors, with the remaining receptors preferentially targeted to synapses. Thus, the CA1 soma-patch currents were strongly reduced, but glutamatergic synaptic currents were unaltered; and evoked dendritic and spinous Ca2+ transients, Ca2+-dependent gene activation, and hippocampal field potentials were as in the wild type. In adult GluR-A-/- mice, associative long-term potentiation (LTP) was absent in CA3 to CA1 synapses, but spatial learning in the water maze was not impaired. The results suggest that CA1 hippocampal LTP is controlled by the number or subunit composition of AMPA receptors and show a dichotomy between LTP in CA1 and acquisition of spatial memory.

A rapid and simple method for cryopreservation of human liver slices.

1. Precision-cut liver slices represent a suitable and convenient in vitro preparation for studying metabolism and toxicity mechanisms of drugs and toxic chemicals. Particularly in the case of human liver slices, cryopreservation would enable more efficient utilization of this scarce and irregularly available tissue. 2. Liver slices from consecutive human livers were cryopreserved using a method previously developed for rat and monkey liver slices. This procedure involves incubation in 12% dimethyl sulphoxide for 30 min on ice and direct immersion into liquid nitrogen. 3. Functional integrity of cryopreserved human liver slices, as compared with that of fresh liver slices, was maintained at 66 +/- 8% (alanine aminotransferase activity retained in the slices), 78 +/- 7% (urea synthesis), 88 +/- 14% (testosterone hydroxylation), 84 +/- 7% (N-deethylation of lidocaine) and 88 +/- 10% (total O-deethylation of 7-ethoxycoumarin). The ratios of testosterone metabolites did not change on cryopreservation. 4. These results show that the cryopreserved human liver slices retained the measured drug metabolism activities. Therefore, this cryopreservation method is suitable for storing liver slices to be used for comparing drug metabolism patterns, at least qualitatively, between species.

Comparison of five incubation systems for rat liver slices using functional and viability parameters.

Precision-cut liver slices are presently used for various research objects, e.g. to study metabolism, transport, and toxicity of xenobiotics. Various incubation systems are presently employed, but a systematic comparison between these incubation systems with respect to preservation of slice function has not been performed yet. Therefore, we started a comparative study to evaluate five of these systems: the shaken flask (an Erlenmeyer in a shaking water bath), the stirred-well (24-well culture plate equipped with grids and magnetic stirrers), rocker platform (6-well culture plate with Netwell insert rocked on a platform), the roller system (dynamic organ culture rolled on an insert in a glass vial), and the 6-well shaker (6-well culture plate in a shaking water bath). The liver slices were incubated in these incubation systems for 0.5, 1.5, and 24.5 h and subsequently subjected to viability and metabolic function tests. The viability of the incubated liver slices was evaluated by: potassium content, MTT assay, energy charge, histomorphology, and LDH leakage. Their metabolic functions were studied by determination of the metabolism of lidocaine, testosterone, and antipyrine. Up to 1.5 h of incubation all five incubation systems gave similar results with respect to viability and metabolic function of the liver slices. However, after 24 h, the shaken flask, the rocker platform, and the 6-well shaker incubation systems appeared to be superior to the stirred well and the roller incubation systems.

The metabolite patterns of eltoprazine in man, dog, rat and rabbit.

To compare the metabolism of eltoprazine of dog, rat and rabbit with that in man, urine samples were collected after dosing with 14C-eltoprazine. The 14C-labelled metabolites were separated by chromatography and detected by their radioactivity. This resulted in so-called metabolite patterns. The human metabolite pattern contained peaks that were all found in that obtained from the dog's urine. The dog's metabolite pattern had two peaks that were (almost) absent in all other species. The rat's urine gave a pattern which had only two peaks in common with the human pattern. Unchanged drug was excreted in significant amounts by man, dog, and rat, but not by rabbit. This excretion was even a little more pronounced after intravenous injection of the drug. In man, the ratio between unchanged drug and metabolites was fairly constant with time after dosing, while this ratio decreased in the animal species. The major part of the metabolites were sulphate- or glucuronide conjugates, but hydrolysis of these required extraordinary amounts of enzyme. We do not yet know whether the observed species differences reflect differences in conjugating activity or (and) oxidative metabolism. We could not identify important differences in the metabolite patterns that were due to sex or route of drug administration. Also, the site of the 14C-label in the drug molecule hardly affected the metabolite patterns; the only effect was the excretion by the rat of a very polar but minor component when it was dosed with 14C-piperazine labelled eltoprazine. This component was absent when 14C-phenyl labelled eltoprazine was given.

Cholestatic effect of harmol glucuronide in the rat. Prevention of harmol-induced cholestasis by increased formation of harmol sulfate.

Harmol, a phenolic compound of low molecular weight, is conjugated either with glucuronic acid or sulfate. A clear relationship is observed between the metabolism of harmol and the occurrence of cholestasis: high concentrations of harmol glucuronide in bile induced a complete stop of bile flow, both in the rat in vivo and in the perfused rat liver. Intravenous infusion of harmol (250 mumol/hr/kg b.wt.) in vivo in the rat considerably decreased the availability of sulfate and, consequently, the amount of harmol sulfate excreted in bile and urine; this decrease was compensated for by an increase in glucuronidation, which caused complete cholestasis when the concentration of harmol glucuronide in bile became of the order of 20 mM. A sufficient supply of sulfate by infusion of sodium sulfate prevented the decrease in sulfation and the increase in glucuronidation and no cholestasis occurred. Low sulfate availability in rats fed a low-protein diet decreased the time of harmol infusion required for cholestasis to occur. Alleviation of the cholestasis in low-protein diet-fed rats was observed when after 2 hr of infusion of harmol additional sulfate was supplied. In the single-pass perfused rat liver, cholestasis occurred when large amounts of harmol glucuronide were excreted in bile. When sulfation of harmol was inhibited by 2,6-dichloro-4-nitrophenol, cholestasis occurred at lower infusion rates of harmol. These data indicate that harmol glucuronide is cholestatic when its concentration in bile increases beyond a threshold concentration; the protein content of the diet may profoundly affect the occurrence of this toxic effect.