The method of cellular immobilization and perfusion was applied to adipocytes. The lipolytic effect of isoprénaline, whose action is produced as a result of receptor-drug interaction, was followed. An agarose solution kept at at 37 °C was mixed 1:1 with the cell suspension. Thereafter, adipocytes were immobilized in the agarose threads. The lipolytic effect of 0.1 ml of isoprénaline (1x10~4 mol/1), that was rapidly introduced to the cell perfusion inlet in a non-recirculating system, was monitored by assessing glycerol production. The immobilized and perfused adipocytes exhibited significant lipolytic activity. After reaching the maximum effect, 0.1 ml of propranol (lxl 0-3 mol/1) that was applied to the bioreactor inlet, abolished the isoprénaline effect. The present data demonstrate the potential applicability of immobilized perfused adipocytes for various kinds of studies.
This study deals with the application of the previously developed immobilized and perfused isolated hepatocytes as a cellular system for the study of representative phase 1 and phase II of biotransformation reactions. To illustrate phase I reactions, aminopyrine (0.17-4.25 mmol/1) and hexobarbital (0.2 mmol/1) were selected. For phase II reactions, glutathione transferase activity was evaluated by using l-chloro-2,4-dinitrobenzene (CDNB) as a substrate (0.125-2.0 mmol/1). Formaldehyde, that was formed from aminopyrine, increased steadily in the perfusion medium with time. The perfused hepatocytes eliminated hexobarbital at a much higher rate than the hepatocytes in suspension. At several time points the amount of CDNB-glutathione conjugate formed per one million hepatocytes in the bioreactor was almost twice the amount formed by the hepatocytes in suspension. The present data illustrate the successful application of the hepatocyte bioreactor in phase I and phase II of xenobiotic metabolism and indicate that the cells were metabolically more active than the cells in suspension.
Though two isoforms of nitric oxide synthase, iNOS and eNOS, were reported in adipocytes, the role of NO in adipose tissue is still ambiguous. The aims of the present study were 1) to follow the effect of bacterial lipopolysaccharide (LPS), on 24 h-lipolysis in rat epididymal adipocyte culture in relation to iNOS stimulation; 2) to compare LPS-induced NO effects with exogenously NO, delivered as S-nitroso-N-acetylpenicillamine (SNAP), and 3) to examine the possible role of NO signaling agonist in lipolysis mediated by the -adrenoreceptor agonist. Lipolysis was measured by glycerol and free fatty acid (FFA) production. The medium nitrite levels were used for the indirect estimation of NOS expression. Adipocyte mitochondrial function was assessed by the MTT test. LPS produced a concentration-dependent increase of NO with a decrease of viability at the highest dose. However, LPS did not affect lipolysis. SNAP did not exhibit significant changes in glycerol, FFA or MTT. BRL-37344 and db-cAMP significantly increased nitrite, glycerol and FFA levels. There was a positive correlation between glycerol release and nitrite production. Moreover,
BRL-37344 significantly reduced mitochondrial functions. The pretreatment with bupranolol, -antagonist, restored all parameters affected by BRL-37344. These results support a concept that NO fulfils multifaceted role of stimulating lipolysis under physiological conditions (-agonistic effect) and modulating the same processes during inflammatory (LPS) processes.
In the present study, a method has been employed for hepatocyte immobilization in agarose threads which allows for cell perfusion. The rat hepatocytes are isolated from the liver. A 1.8 % low-gelling agarose solution is prepared in warm Krebs-Henseleit solution. The agarose solution is mixed 1:1 with the hepatocytes and the cells are immobilized in agarose threads by extruding the agarose-cell mixture through cooled Chemfluor teflon (TFE) tubing. Light and electron microscopy studies indicated the integrity of the hepatocytes in the gel matrix. This system allows for liver cell perfusion and viability studies to be carried out non-invasively on the cells and provides data that are comparable to those obtained with a perfused isolated liver. Immobilized hepatocytes are an in vitro system worthy of further evaluation which may be useful in the studies of liver cell metabolism and the response of the liver to foreign chemicals.