Detection of cell-affecting agents with a silicon biosensor.

Cellular metabolism is affected by many factors in a cell's environment. Given a sufficiently sensitive method for measuring cellular metabolic rates, it should be possible to detect a wide variety of chemical and physical stimuli. A biosensor has been constructed in which living cells are confined to a flow chamber in which a potentiometric sensor continually measures the rate of production of acidic metabolites. Exploratory studies demonstrate several applications of the device in basic science and technology.

Biosensors for directly measuring cell affecting agents.

Cellular perfusion chambers have been constructed from the Light Addressable Potentiometric Sensor (LAPS) previously described. The authors have used these chambers to measure the effects of a variety of agents on the metabolic rates of cells. The chambers are used in a stopped flow mode. When flow is on, samples may be introduced to the chamber. When flow is stopped, acidification of the very small volume of medium in the chamber is used to determined the metabolic rate of the cells. Using a variety of types of mammalian cells the authors have demonstrated the following. The triggering of cellular receptors can be determined in minutes. Metabolic inhibition of normal human cells by a test compound can be correlated with the compounds in vivo ocular irritancy. And the efficacy of chemotherapeutic agents on tumor cells exhibiting multidrug resistance can be determined in a few hours.

Continuous monitoring of receptor-mediated changes in the metabolic rates of living cells.

Activation of beta-adrenergic or muscarinic acetylcholine receptors expressed in transfected cells or epidermal growth factor receptors in human keratinocytes produces 15% to 200% changes in cellular metabolic rates. Changes in cell metabolism were monitored continuously with a previously described silicon-based microphysiometer that detects small changes in extracellular pH. The amplitude and kinetics of the metabolic changes depend upon several factors including pretreatment of the cells prior to receptor stimulation, the dose of hormone/neurotransmitter used, and the receptor complement of the cells. Responses are receptor specific; cells transfected with receptor genes respond only to the appropriate hormone/transmitter, whereas control (nontransfected) cells or cells transfected with different receptors exhibit no response. The specificity of the responses was further documented by using pharmacological antagonists. In Chinese hamster ovary (CHO) cells transfected with human beta 2-adrenergic receptors, isoproterenol produces a 20-60% increase in the rate of extracellular acidification with an EC50 of 4 nM, a response that is competitively antagonized by (-)-propranolol. The EC50 for the isoproterenol response is shifted from 4 nM to 100 nM in the presence of 3 nM (-)-propranolol. The kinetics of the metabolic response induced by beta-adrenergic receptor stimulation are markedly slower than those elicited by muscarinic receptor agonists. The maximal metabolic response in cells transfected with beta-adrenergic receptors peaks at approximately 12 min as compared with less than 30 sec in cells transfected with muscarinic receptors, perhaps reflecting activation of different second-messenger pathways. These findings illustrate an alternative means of studying cellular responses to hormones and neurotransmitters and suggest that metabolic changes will be generally useful for detecting the consequences of receptor-ligand interactions.