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

The consequence of regional gradients of P-gp and CYP3A4 for drug-drug interactions by P-gp inhibitors and the P-gp/CYP3A4 interplay in the human intestine ex vivo

Intestinal P-gp and CYP3A4 work coordinately to reduce the intracellular concentration of drugs, and drug-drug interactions (DDIs) based on this interplay are of clinical importance and require pre-clinical investigation. Using precision-cut intestinal slices (PCIS) of human jejunum, ileum and colon, we investigated the P-gp/CYP3A4 interplay and related DDIs with P-gp inhibitors at the different regions of the human intestine with quinidine (Qi), dual substrate of P-gp and CYP3A4, as probe. All the P-gp inhibitors increased the intracellular concentrations of Qi by 2.1–2.6 fold in jejunum, 2.6–3.8 fold in ileum but only 1.2–1.3 fold in colon, in line with the different P-gp expression in these intestinal regions. The selective P-gp inhibitors (CP100356 and PSC833) enhanced 3-hydroxy-quinidine (3OH-Qi) in jejunum and ileum, while dual inhibitors of P-gp and CYP3A4 (verapamil and ketoconazole) decreased the 3OH-Qi production, despite of the increased intracellular Qi concentration, due to inhibition of CYP3A4. The outcome of DDIs based on P-gp/CYP3A4 interplay, shown as remarkable changes in the intracellular concentration of both the parent drug and the metabolite, varied among the intestinal regions, probably due to the different expression of P-gp and CYP3A4, and were different from those found in rat PCIS, which may have important implications for the disposition and toxicity of drugs and their metabolites. © 2016 Elsevier Lt

Human and rodent ex vivo model for intestinal fibrosis in inflammatory bowel disease (IBD)

Background: One of the major complications in IBD is intestinal fibrosis (IF). It is the result of the chronic inflammation of intestinal tissue. IF causes narrowing of the intestinal lumen and potential stricture formation. For the study of the cellular and molecular mechanism of IF in IBD adequate animal models are lacking. Our aim is to develop an ex vivo model for IF by using human and rodent precision-cut intestinal slice (PCIS). In PCIS all cell types are present in their original tissue-matrix environment and can be used as a model to study the early onset of IF. Methods: Rat, mouse and human jejunum were excised and prepared as a segment embedded in agarose. PCIS (estimated 300-400 mm) was prepared and incubated up to 24 hr (rat) or 48 hr (human and mouse). ATP content of the PCIS was used to assess the general viability. Moreover, morphology (rat and human) was evaluated. The gene expression of different fibrosis markers including Pro-Collagen 1 A1 (COL1A1), Heat Shock Protein 47 (HSP47), alpha-Smooth Muscle Actin (SMA), connective tissue growth factor (CTGF), Synaptophysin (SYN) and Fibronectin (FIB) were determined. Results: Mouse PCIS were viable up to 48 hr. However, for rat and human PCIS ATP content was decreased to 25% (24hr) and 70% (48 hr), respectively. ATP content of rat and human PCIS correlated well with morphology of the PCIS. In rat PCIS, after 24 hr, HSP47 (3.2 fold) and FIB (2.1 fold) gene expressions were significantly increased. In the presence of 5 ng/mL TGF-β, COL1A1 (1.8 fold), SMA (1.5 fold) and CTGF (2.1 fold) were significantly up-regulated compared to 24 hr control. Meanwhile HSP47 gene expression was slightly decreased (0.8 fold). Similarly, in mouse PCIS, gene expression of HSP47 (3.9 fold) and FIB (4.3 fold) was significantly increased after 48 hr. When incubated with 5 ng/mL TGF-β, COl1A1 and FIB were significantly up-regulated (2.0 fold) compared to 48 hr control, HSP47 and CTGF gene expression were slightly, but significantly increased (1.2 fold). In human PCIS, after 48 hr, HSP47 (3.5-fold) and SYN (2.5 fold) were significantly up-regulated. However, incubation of human PCIS with 5 ng/ml of TGF-β, none of the investigated fibrosis genes was affected. Conclusions: In rat, mouse and human PCIS an increase in gene expression of early-onset of fibrosis makers was found. In addition, TGF-β was able to induce fibrosis markers in rat and mouse, but not in human PCIS. Rodent and human PCIS are promising ex vivo models to study the early onset of intestinal fibrosis

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

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

Prediction of whole-body metabolic clearance of drugs through the combined use of slices from rat liver, lung, kidney, small intestine and colon

1. The aim was to investigate whether precision-cut rat tissue slices could be used to predict metabolic drug clearance in vivo. To obtain a complete picture, slices not only from liver, but also from lung, kidney, small intestine and colon were included.2. The metabolic clearances of 7-ethoxycoumarin, 7-hydroxycoumarin, testosterone, methyltestosterone and warfarin were determined by measuring the disappearance of these compounds during incubation with slices prepared from liver, lung, kidney, small intestine and colon.3. The total in vitro metabolic clearance was determined by adding the individual in vitro organ clearances from the slices. Prediction based on the in vitro clearance was within an order of magnitude to the corresponding in vivo values. Interestingly, the relative contribution of extrahepatic metabolic clearance of the studied compounds to total clearance was remarkably high, ranging from 35 to 72% of the total metabolic clearance.4. It is concluded that the model of multi-organ precision-cut slices is a useful in vitro tool for prediction of in vivo metabolic clearance. In addition, it provides information about the relative contribution of the liver, lung, kidney, small intestine and colon to the total metabolic clearance

Prediction of whole-body metabolic clearance of drugs through the combined use of slices from rat liver, lung, kidney, small intestine and colon

1. The aim was to investigate whether precision-cut rat tissue slices could be used to predict metabolic drug clearance in vivo. To obtain a complete picture, slices not only from liver, but also from lung, kidney, small intestine and colon were included. 2. The metabolic clearances of 7-ethoxycoumarin, 7-hydroxycoumarin, testosterone, methyltestosterone and warfarin were determined by measuring the disappearance of these compounds during incubation with slices prepared from liver, lung, kidney, small intestine and colon. 3. The total in vitro metabolic clearance was determined by adding the individual in vitro organ clearances from the slices. Prediction based on the in vitro clearance was within an order of magnitude to the corresponding in vivo values. Interestingly, the relative contribution of extrahepatic metabolic clearance of the studied compounds to total clearance was remarkably high, ranging from 35 to 72% of the total metabolic clearance. 4. It is concluded that the model of multi-organ precision-cut slices is a useful in vitro tool for prediction of in vivo metabolic clearance. In addition, it provides information about the relative contribution of the liver, lung, kidney, small intestine and colon to the total metabolic clearance