Method for determining oxygen consumption rates of static cultures from microplate measurements of pericellular dissolved oxygen concentration.

We describe a simple protocol for determining the oxygen consumption of cells in static culture. The protocol is based on a noninvasive oxygen-sensing microplate and a simple mathematical model derived from Fick's Law. The applicability of the model is confirmed by showing the correlation of computed oxygen consumption rate (OCR) values to actual cell densities ascertained by direct cell counting and/or MTT for HL60 and U937 cells cultured in suspension. Correlation between computed OCR and these other indications of cell number was quite good, as long as the cultures were not diffusion-limited for oxygen. The impact of the geometric factors of media depth and well size were confirmed to be consistent with the model. Based on this demonstrated correlation, we also developed a simple, completely noninvasive algorithm for ascertaining the per-cell oxygen utilization rate (OUR), which is the ratio of OCR to cell number, and a fundamental cell characteristic. This is accomplished by correlating the known seed densities to extrapolated determinations of OCR at time zero. Such determinations were performed for numerous cell types, in varying well sizes. Resulting OUR values are consistent with literature values acquired by far more painstaking methods, and ranged from <0.01 fmol.min(-1).cell(-1) for bacteria to 0.1-10 fmol.min(-1).cell(-1) for immortalized mammalian and insect cell lines to >10 fmol.min(-1).cell(-1) for primary hepatocytes. This protocol for determining OCR and OUR is extremely simple and broadly applicable and can afford rapid, informative, and noninvasive insight into the state of the culture.

Kava does not display metabolic toxicity in a homogeneous cellular assay.

To determine whether kava (Kava kava, 'Awa, Yaqona, Piper methysticum Forst.), the popular herbal product associated recently with possible human hepatotoxicity, is bioactivated by cytochrome P450 enzymes to cytotoxic metabolites, three kava lactones (methysticin, yangonin, and desmethoxyyangonin) and an ethanolic extract of dried kava root were incubated over time in culture with MCL-5 cells, a human lymphoblastoid cell line that has been stably transfected with five human P450's (CYP 1A1, 1A2, 2A6, 2E1, and 3A4) and human epoxide hydrolase. Incubations were performed concurrently with a control cell line (cH2) that is derived from the same parental line as MCL-5, but transfected with two empty vectors. The kava compounds displayed varying degrees of toxicity (IC (50) values ranged from 50 to > 100 microM) to the MCL-5 and cH2 cell lines; however, both cell lines were equally sensitive to the test compounds. These results suggest that the parent compound for each of the four test compounds was primarily responsible for the observed cell toxicity and that CYP 1A1, 1A2, 2A6, 2E1, and 3A4 or epoxide hydroxylase did not appear to be involved. Thus, in vitro kava does not appear to be activated to toxic metabolites by enzymes known to be important in metabolic toxicity.