Monolayers 293 cells

Methods to Detect and Quantitate Viral Agents in Fluids. In order to assess the effectiveness of membrane filtration the abihty to quantitate the amount of vims present pre- and post-filtration is critical. There are a number of techniques used. The method of choice for filter challenge studies is the plaque assay which utilizes the formation of plaques, localized areas in the cell monolayer where cell death caused by viral infection in the cell has occurred on the cell monolayer. Each plaque represents the presence of a single infectious vims. Vims quantity in a sample can be determined by serial dilution until the number of plaques can be accurately counted. The effectiveness of viral removal may be determined, as in the case of bacterial removal, by comparing the vims concentration in the input suspension to the concentration of vims in the effluent. 

Calf kidneys, dog kidneys and rhesus monkey kidneys were treated with trypsin to give suspensions of cells. The suspensions were centrifuged and the packed cells diluted with 400 volumes (calf cells) or 200 volumes (dog cells and rhesus monkey cells) of a growth medium consisting of 5% horse serum and 0.5% lactalbumen hydrolysate in Earle s saline, with 100 units/ml each of penicillin and streptomycin. These media were used separately to produce Semliki Forest/calf interferon, Semliki Forest/dog interferon and Semliki Forest/rhesus monkey interferon. The cell-containing growth medium was dispensed into 500 ml medical flat bottles (70 ml in each). The cultures were incubated at 36°C. Confluent sheets of cells (monolayers) were formed in 5 to 6 days. The growth medium was then removed and the monolayers were washed with isotonic phosphate-buffered saline, pH 7.5. 

In contrast to previous in vivo models, this in vitro model provides the possibility of dissociating experimentally two important processes of intestinal absorption cellular uptake and secretion. Under conditions mimicking the postprandial state (taurocholate/oleic acid supplementation), differentiated Caco-2 cells were able to (1) take up carotenoids at the apical sides and incorporate them into CMs and (2) secrete them at the basolateral sides associated with CM fractions. Using this approach, the extent of absorption of P-carotene through Caco-2 cell monolayers after 16 hr of incubation was 11.2%, a value falling within the in vivo range (9 to 22%). ° - Of the total amount of P-carotene secreted, 78% was associated with the two CM fractions and 10% with the VLDL fraction. ... 

Since experimental determination of intestinal absorption is quite demanding, Caco-2 cell monolayers have been successfully used to model passive drug absorption. Several models for the prediction of Caco-2 permeability using PSA were developed, including those of van de Waterbeemd et al. [5] and Palm et al. [22] who found that relationships between Caco-2 permeability and PSA is stronger than with Clog D, Krarup et al. [23] who used dynamic PSA calculated for water accessible molecular surface and Bergstrom et al. [24]. 

Production of Mucosal Damage 2.3.1.2.1 Cell culture Stimulated neutrophils are known to be cytotoxic to cells in vitro (Dull et al., 1987 Dallegri et al., 1990 Grisham et al., 1990b). Several in vitro systems have been used to demonstrate oxidative damage to intestinal cells. Xanthine/XO increased Cr release and decreased [ H]thymidine uptake by IEC-18 small intestinal epithelial cell monolayers in a dose-dependent manner (Ma et al., 1991). Rat enterocytes show decreased trypan blue exclusion and increased protein release when incubated with neutrophils stimulated... 

Ma, T.Y., Hollander, D., Freeman, D., Nguyen, T. and Krugliak, P. (1991). Oxygen free radical injury of IEC-18 small intestinal epithelial cell monolayers. Gastroenterology 100, 1533-1543. 

The in vitro system we have been using to study the transepithelial transport is cultured Madin-Darby canine kidney (MDCK) epithelial cells (11). When cultured on microporous polycarbonate filters (Transwell, Costar, Cambridge, MA), MDCK cells will develop into monolayers mimicking the mucosal epithelium (11). When these cells reach confluence, tight junctions will be established between the cells, and free diffusion of solutes across the cell monolayer will be markedly inhibited. Tight junction formation can be monitored by measuring the transepithelial electrical resistance (TEER) across the cell monolayers. In Figure 1, MDCK cells were seeded at 2 X 104 cells per well in Transwells (0.4 p pore size) as described previously. TEER and 14C-sucrose transport were measured daily. To determine 14C-sucrose... 

Figure 1. The correlation of transepithelial electrical resistance (TEER) with the transepithelial transport of 14C-sucrose in MDCK cell monolayers grown on microporous filters.

Figure 3. Transcellular transport of HRP-S-PLL in filter-grown MDCK cell monolayers. Confluent MDCK monolayers in Transwells were treated at the basal compartment (closedsquares)or the apical compartment (open squares) with 3 pg/mL HRP-S-PLL conjugate.

Figure 6. Transcellular transport of HRP-SS-PDL in a filter-grown MDCK cell monolayer. HRP-SS-PDL was added to the apical medium (closed squares) or to the basal medium (open squares).

In PAMPA measurements each well is usually a one-point-in-time (single-timepoint) sample. By contrast, in the conventional multitimepoint Caco-2 assay, the acceptor solution is frequently replaced with fresh buffer solution so that the solution in contact with the membrane contains no more than a few percent of the total sample concentration at any time. This condition can be called a physically maintained sink. Under pseudo-steady state (when a practically linear solute concentration gradient is established in the membrane phase see Chapter 2), lipophilic molecules will distribute into the cell monolayer in accordance with the effective membrane-buffer partition coefficient, even when the acceptor solution contains nearly zero sample concentration (due to the physical sink). If the physical sink is maintained indefinitely, then eventually, all of the sample will be depleted from both the donor and membrane compartments, as the flux approaches zero (Chapter 2). In conventional Caco-2 data analysis, a very simple equation [Eq. (7.10) or (7.11)] is used to calculate the permeability coefficient. But when combinatorial (i.e., lipophilic) compounds are screened, this equation is often invalid, since a considerable portion of the molecules partitions into the membrane phase during the multitimepoint measurements. 

Hilgers, A. R. Conradi, R. A. Burton, P. S., Caco-2 cell monolayers as a model for drug transport across the intestinal mucosa, Pharm. Res. 7, 902-910 (1990). 

Hidalgo, I. J. Hillgren, K. M. Grass, G. M. Borchardt, R. T., A new side-by-side diffusion cell for studying transport across epithelial cell monolayers, in Vitro Cell Dev. Biol. 28A, 578-580 (1992). 

Adson, A. Burton, P. S. Raub, T. J. Barsuhn, C. L. Audus, K. L. Ho, N. F. H., Passive diffusion of weak organic electrolytes across Caco-2 cell monolayers Uncoupling the contributions of hydrodynamic, transcellular, and paracellular barriers, J. Pharm. Sci. 84, 1197-1204 (1995). 

Shah et al. [51] demonstrated the use of a donor-receptor compartment apparatus separated by a cell monolayer to estimate membrane transport parameters. Permeability coefficients, P, were calculated as... 

MV Shah, KL Audus, RT Borchardt. The application of bovine brain micro vessel endothelial-cell monolayers grown onto polycarbonate membranes in vitro to estimate the potential permeability of solutes through the blood-brain barrier. Pharm Res 6 624-627, 1989. 

I Hidalgo, K Hillgreen, G Grass, R Borchardt. Characterization of the unstirred water layer in Caco-2 cell monolayers using a novel diffusion apparatus. Pharm Res 8 222, 1991. 

Figure 5 Parallel transcellular and paracellular pathways through intestinal epithelial cell monolayer.

In whole tissue or cell monolayer experiments, transcellular membrane resistance (Rm = Pm1) lumps mucosal to serosal compartment elements in series with aqueous resistance (R = P ). The operational definition of Lm depends on the experimental procedure for solute transport measurement (see Section VII), but its magnitude can be considered relatively constant within any given experimental system. Since the Kp range dwarfs the range of Dm, solute differences in partition coefficient dominate solute differences in transcellular membrane transport. The lumped precellular resistance and lumped membrane resistance add in series to define an effective resistance to solute transport ... 

In vitro studies permit further isolation of parallel transport processes and can provide a reduction in experimental variability. Rate of absorption assessment can be measured as intestinal uptake or flux across an intestinal barrier at both the tissue and cell monolayer levels. Experimental variability is also reduced by the fact that a large number of tissue samples can be used from the same experi-... 

Solute uptake can also be evaluated in isolated cell suspensions, cell mono-layers, and enterocyte membrane vesicles. In these preparations, uptake is normalized by enzyme activity and/or protein concentration. While the isolation of cells in suspension preparations is an experimentally easy procedure, disruption of cell monolayers causes dedifferentiation and mucosal-to-serosal polarity is lost. While cell monolayers from culture have become a popular drug absorption screening tool, differences in drug metabolism and carrier-mediated absorption [70], export, and paracellular transport may be cell-type- and condition-depen-dent. 

The use of vesicle cell membranes, isolated cells, and cell monolayers and intestinal tissue studies has provided valuable correlations with in situ and in vivo drug absorption in animals as well as correlations with drug absorption in clinical studies. Most prominent among the literature sources establishing correlations between in vitro tissue and cellular systems with drug absorption in humans are the work of Dowty and Dietsch [73], Lennernas et al. [74], and Stewart et al. [75],... 

The intent of this chapter is to establish a comprehensive framework in which the physicochemical properties of permeant molecules, hydrodynamic factors, and mass transport barrier properties of the transcellular and paracellular routes comprising the cell monolayer and the microporous filter support are quantitatively and mechanistically interrelated. We specifically define and quantify the biophysical properties of the paracellular route with the aid of selective hydrophilic permeants that vary in molecular size and charge (neutral, cationic, anionic, and zwitterionic). Further, the quantitative interrelationships of pH, pKa, partition... 

Methods for quantifying both the transcellular diffusion and concurrent metabolism of drugs and the unusual transcellular diffusion of membrane-interactive molecules coupled with the influence of protein binding are described in detail. To demonstrate the utility of cultured cell monolayers as a tool for basic science investigations, a subsection is devoted to the elucidation of rate-determining steps and factors in the passive diffusion of peptides across biological membranes. The chapter concludes with a discussion on the judicious use of in vitro cell monolayer results to predict in vivo results. 

In the selection of an appropriate cell culture system, a number of criteria must be considered (Table 3). These include not only the characteristics of the cell type but also the controllable parameters of the complete transport system such as the permeants, the filter properties, and the assay conditions. In general, most transport experiments employ the experimental design shown schematically in Figure 4 with modifications as discussed below. Typically, the desired cell is seeded onto some sort of semipermeable filter support and allowed to reach confluence. The filter containing the cell monolayer separates the donor and receiver... 

All of these characteristics can be under the regulation of the cell and influenced by the cell culture conditions. The age of the cell monolayer in culture can have a profound impact on the quality of the barrier. In monolayers with actively dividing cells, resistance increases with time in culture as tight junctions form (see Fig. 15, Section III.C.4). Resistance reaches a plateau, then decreases as cell viability declines (Section III.C.4). Time in culture may also be a factor in the expression of polarity, which is related to tight junction formation as well as the state of differentiation of the cells (e.g., differential gene expression). 

The sole purpose of the filter support and any applied extracellular matrix is simply to provide a surface for cell attachment and thus to provide mechanical support to the monolayer. However, the filter and matrix also can act as serial barriers to solute movement after diffusion through the cell monolayer. The important variables are the chemical composition of the filter, porosity, pore size, and overall thickness. In some cases, pore tortuosity also can be important. It is desired that the filter, with or without an added matrix, provide a favorable surface to which the cells can attach. However, in some cases these properties can also result in an attractive surface for nonspecific adsorption of the transported solute. In these instances, the appearance of the solute in the receiver compartment of the diffusion cell will not be a true reflection of its movement across the mono-layer. Such problems must be examined on a case-by-case basis. 

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