Alvetex®: polystyrene scaffold technology for routine three dimensional cell culture.

A broad range of technologies have been developed to enable three dimensional (3D) cell culture. Few if any however are adaptable for routine everyday use in a straightforward and cost effective manner. Alvetex(®) is a rigid highly porous polystyrene scaffold designed specifically to enable routine 3D cell culture. The scaffold is engineered into thin membranes that fit into conventional cell culture plasticware. The material is inert and offers a polystyrene substrate familiar to cell biologists worldwide. The 3D geometry of the scaffold provides the environment in which cells grow, differentiate, and function to form close relationships with adjacent cells thus creating the equivalent of a thin tissue layer in vitro. This chapter introduces the features required by a technology that enables routine 3D cell culture. Using Alvetex(®) as a product that satisfies these requirements, its application is demonstrated for the growth of a recognised cell line. Procedures detailing the use of Alvetex(®) for 3D cell culture are provided. This is followed by a series of detailed methods describing ways to analyse such cultures including histological techniques, immunocytochemistry, and scanning electron microscopy. Examples of data generated from these methods are shown in the corresponding figures. Additional notes are also included where further information about certain procedures is required. The use of Alvetex(®) in combination with these methods will enable investigators to routinely produce complex 3D cultures to research the growth, differentiation, and function of cells in new ways.

Culture of HepG2 liver cells on three dimensional polystyrene scaffolds enhances cell structure and function during toxicological challenge.

Cultured cells are dramatically affected by the micro-environment in which they are grown. In this study, we have investigated whether HepG2 liver cells grown in three dimensional (3-D) cultures cope more effectively with the known cytotoxic agent, methotrexate, than their counterparts grown on traditional two dimensional (2-D) flat plastic surfaces. To enable 3-D growth of HepG2 cells in vitro, we cultured cells on 3-D porous polystyrene scaffolds previously developed in our laboratories. HepG2 cells grown in 3-D displayed excellent morphological characteristics and formed numerous bile canaliculi that were seldom seen in cultures grown on 2-D surfaces. The function of liver cells grown on 3-D supports was significantly enhanced compared to activity of cells grown on 2-D standard plasticware. Unlike their 2-D counterparts, 3-D cultures were less susceptible to lower concentrations of methotrexate. Cells grown in 3-D maintained their structural integrity, possessed greater viability, were less susceptible to cell death at higher levels of the cytotoxin compared to 2-D cultures, and appeared to respond to the drug in a manner more comparable to its known activity in vivo. Our results suggest that hepatotoxicity testing using 3-D cultures might be more likely to reflect true physiological responses to cytotoxic compounds than existing models that rely on 2-D culture systems. This technology has potential applications for toxicity testing and drug screening.

Novel cell culture device enabling three-dimensional cell growth and improved cell function.

A better understanding of cell biology and cell-cell interactions requires three-dimensional (3-D) culture systems that more closely represent the natural structure and function of tissues in vivo. Here, we present a novel device that provides an environment for routine 3-D cell growth in vitro. We have developed a thin membrane of polystyrene scaffold with a well defined and uniform porous architecture and have adapted this material for cell culture applications. We have exemplified the application of this technology by growing HepG2 liver cells on 2- and 3-D substrates. The performance of HepG2 cells grown on scaffolds was significantly enhanced compared to functional activity of cells grown on 2-D plastic. The incorporation of thin membranes of porous polystyrene to create a novel device has been successfully demonstrated as a new 3-D cell growth technology for routine use in cell culture.

Tailoring the morphology of emulsion-templated porous polymers.

Methods with which to tailor the morphology of polystyrene-based emulsion-templated (PolyHIPE) materials are presented. Increasing the temperature of the aqueous phase used to prepare the parent emulsion leads to an increase in average void and interconnect size in the resulting porous material. Additionally, the presence in the aqueous phase of small quantities of organic additives that are capable of partitioning between the two emulsion phases also affects the morphology of the porous material obtained. The additives examined were tetrahydrofuran (THF), methanol and poly(ethylene glycol) (PEG), all of which were found to increase the average void and interconnect diameters. It is suggested that THF and, to a lesser extent, PEG enhance Ostwald ripening, resulting in emulsion coarsening over time. Evidence for this was gleaned from NMR experiments to determine the rates of water diffusion in each emulsion. However, methanol was shown not to affect the rate of water diffusion. An alternative mechanism by which methanol could affect the emulsion stability is by depleting surfactant from the interface. However, higher levels of surfactant in emulsions containing methanol did not have a significant effect on morphology. To explain this, we suggest that methanol may result in depletion of surfactant from the emulsion interface, however additional surfactant serves not only to replace this depleted surfactant but also to increase the number of w/o micelles in the continuous phase. These facilitate transport of water between droplets, thus negating the effect of replacing the surfactant lost from the interface.