Three-dimensional culture systems are an ideal in vitro model being capable of sustaining cell functionalities in a manner that resembles the in vivo conditions. In the present study, we developed an ultrasound trap-based technique to rapidly produce HepG2 hepatocarcinoma cell aggregates within 30 min. Enhanced junctional F-actin was observed at the points of cell-cell contact throughout the aggregates. HepG2 aggregates prepared by the ultrasound trap can be maintained in culture on a P-HEMA-coated surface for up to 3 weeks. The cells in these aggregates proliferated during the initial 3 days and cell number was consistent during the following maintenance period. Albumin secretion from these HepG2 aggregates recovered after 3 days of aggregate formation and remained relatively stable for the following 12 days. Cytochrome P450-1A1 activity was significantly enhanced after 6 days with maximal enzyme activity observed between 9 and 18 days. In addition, comparison experiments demonstrated that HepG2 aggregates generated by the ultrasound trap had comparable functional characterizations with HepG2 spheroids formed by a traditional gyrotatory-mediated method. Our results suggest that HepG2 aggregate cultures prepared through the ultrasound trap-based technique may provide a novel approach to produce in vitro models for hepatocyte functional studies.
In the process of isolated single liver cells coming together to form three-dimensional spheroids, cells undergo dramatic environmental changes. How liver cells respond to these changes has not been well studied before. This study characterized the functional and biochemical changes during liver spheroid formation and maintenance. Spheroids were prepared in 6-well plates from freshly isolated liver cells from male Sprague rats by a gyrotatory-mediated method. Morphological formation, and functional and biochemical parameters of liver spheroids were evaluated over a period of 21 days in culture. Liver spheroid formation was divided into two stages, immature (1-5 days) and mature (>5 days), according to their size and shape, and changes in their functionality. Galactose and pyruvate consumption was maintained at a relatively stable level throughout the period of observation. However, glucose secretion and cellular GPT and GOT activities were higher in immature spheroids, decreased upto day 5 and remained stable thereafter. Cellular gamma-glutamyltransferase (gamma-GT) and lactate dehydrogenase (LDH) activities were initially undetectable or low and increased as spheroids matured. Albumin secretion decreased rapidly within the first 2 days and increased as spheroids matured. It is concluded that cells undergo functional and biochemical changes during spheroid formation following isolation of liver cells from intact tissue. Functionality and biochemical properties recovered and were maintained in mature spheroids. A relatively stable period (6-15 days) of functionality in mature spheroids was identified and is recommended for applications of the model.
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