Single cells as biosensors for chemical separations.

A biosensor system based on the response of living cells was demonstrated that can detect specific components of a complex mixture fractionated by a microcolumn separation technique. This system uses ligand-receptor binding and signal-transduction pathways to biochemically amplify the presence of an analyte after electrophoretic separation. The transduced signal was measured by means of two approaches: (i) fluorescence determination of intracellular calcium concentrations in one or more rat PC-12 cells and (ii) measurement of transmembrane current in a Xenopus laevis oocyte microinjected with messenger RNA that encodes a specific receptor. This analysis system has the potential to identify biologically active ligands present in a complex mixture with exceptional sensitivity and selectivity.

Patch-clamp detection of neurotransmitters in capillary electrophoresis.

Gamma-aminobutyrate acid, L-glutamate, and N-methyl-D-aspartate were separated by capillary electrophoresis and detected by the use of whole-cell and outside-out patch-clamp techniques on freshly dissociated rat olfactory interneurons. These neuroactive compounds could be identified from their electrophoretic migration times, unitary channel conductances, and power spectra that yielded corner frequencies and mean single-channel conductances characteristic for each of the different agonist-receptor interactions. This technique has the sensitivity to observe the opening of a single ion channel for agonists separated by capillary electrophoresis.

Microcolumn sample injection by spontaneous fluid displacement.

The withdrawal of a capillary structure from a sample solution causes a droplet to be formed at the end of the capillary. Because of the interfacial pressure difference across the curved surface of the droplet, the droplet is driven into the entrance of the capillary, thereby causing injection of the sample. Assuming negligible sample penetration by diffusive or convective mixing, this injection is intrinsically the smallest possible for a capillary. Moreover, the injection volume can be varied by changing the shape of the capillary structure, specifically the outer diameter of the capillary. This injection method eliminates the need for external pressure differences, applied fields across the capillary, or precise timing, thus offering several advantages over conventional procedures. Studies using capillary electrophoresis as the separation procedure show that approximately 3.5 nl (66 microns I.D. capillary) sample volumes can be injected by hand with a reproducibility of 5.8 +/- 0.7% R.S.D. Parameters that affect the variability of the injection are discussed.

Biosensors in chemical separations.

Identification of biomolecules in complex biological mixtures represents a major challenge in biomedical, environmental, and chemical research today. Chemical separations with traditional detection schemes such as absorption, fluorescence, refractive index, conductivity, and electrochemistry have been the standards for definitive identifications of many compounds. In many instances, however, the complexity of the biomixture exceeds the resolution capability of chemical separations. Biosensors based on molecular recognition can dramatically improve the selectivity of and provide biologically relevant information about the components. This review describes how coupling chemical separations with online biosensors solves challenging problems in sample analysis by identifying components that would not normally be detectable by either technique alone. This review also presents examples and principles of combining chemical separations with biosensor detection that uses living systems, whole cells, membrane receptors, enzymes, and immunosensors.

Optimizing fluorescence detection in chemical separations for analyte bands traveling at different velocities.

In many separation techniques, such as field flow fractionation, liquid chromatography, and electrophoresis, chemical species form bands that migrate at distinct velocities. If these bands are to be quantified on-line using a shot-noise-limited detection system, then attention must be given to the data-digitization rate and to the removal rate of molecules from the analyte pool as a result of the detection process. A theory is developed for calculating the signal-to-noise ratio under such conditions, and it is specialized to the case of fluorescence detection in capillary electrophoresis. Using standard detection procedures in which the data-digitization rate and excitation intensity remain constant for the duration of a separation, detection sensitivity can vary by more than a factor of five for bands that arrive at the detection zone between migration times tau fast and 10 tau fast, where tau fast is the time after the start of the separation that the fastest migrating band arrives at the detection zone. To compensate for different band velocities, both the data-digitization rate and the excitation intensity must be decreased as separation time (tau) increases by the factor tau fast/tau. Only when these corrections are made can uniform sensitivity with the highest possible signal-to-noise ratio be achieved for each peak. These predictions are experimentally tested and compare favorably to observations.

Identification of receptor ligands and receptor subtypes using antagonists in a capillary electrophoresis single-cell biosensor separation system.

A capillary electrophoresis system with single-cell biosensors as a detector has been used to separate and identify ligands in complex biological samples. The power of this procedure was significantly increased by introducing antagonists that inhibited the cellular response from selected ligand-receptor interactions. The single-cell biosensor was based on the ligand-receptor binding and G-protein-mediated signal transduction pathways in PC12 and NG108-15 cell lines. Receptor activation was measured as increases in cytosolic free calcium ion concentration by using fluorescence microscopy with the intracellular calcium ion indicator fluo-3-acetoxymethyl ester. Specifically, a mixture of bradykinin (BK) and acetylcholine (ACh) was fractionated and the components were identified by inhibiting the cellular response with icatibant (HOE 140), a selective antagonist to the BK B2 receptor subtype (B2BK), and atropine, an antagonist to muscarinic ACh receptor subtypes. Structurally related forms of BK were also identified based on inhibiting B2BK receptors. Applications of this technique include identification of endogenous BK in a lysate of human hepatocellular carcinoma cells (Hep G2) and screening for bioactivity of BK degradation products in human blood plasma. The data demonstrate that the use of antagonists with a single-cell biosensor separation system aids identification of separated components and receptor subtypes.

Use of 2,3-naphthalenedicarboxaldehyde derivatization for single-cell analysis of glutathione by capillary electrophoresis and histochemical localization by fluorescence microscopy.

We report that 2,3-naphthalenedicarboxaldehyde reacts rapidly with glutathione and its precursor, gamma-glutamylcysteine, to form highly fluorescent derivatives under physiological conditions. In contrast to previous accounts of 2,3-naphthalenedicarboxaldehyde labeling of primary amines, no additional CN- ion or any other additional nucleophile is required. The fluorescence spectral properties of the chromophores (lambda exc max = 472 nm, lambda em max = 528 nm) make these derivatives amenable to excitation and detection by optical instrumentation that is optimized for fluorescein wavelengths. This selective labeling chemistry enabled quantitative determination and histochemical localization of glutathione in neurobiological samples. Intracellular glutathione was labeled by incubating cultured cells or cell suspensions in a 2,3-naphthalenedicarboxaldehyde-supplemented, DMSO-containing physiological buffer (pH = 7.4) for 2-10 min. Applications include imaging of cultured NG 108-15 cells (mouse neuroblastoma x rat glioma) and primary glial and neuronal cell cocultures (rat hippocampus) using epiluminescent and confocal fluorescence microscopy. Quantitative determination of glutathione in single NG 108-15 cells was accomplished using laser-induced fluorescence detection and capillary electrophoresis.

Fluorescence detection in capillary zone electrophoresis using a charge-coupled device with time-delayed integration.

A fluorescence detection system for capillary zone electrophoresis is described in which a charged-coupled device (CCD) views a 2-cm section of an axially illuminated capillary column. The CCD is operated in two readout modes: a snapshot mode that acquires a series of images in wavelength and capillary position, and a time-delayed integration mode that allows long exposure times of the moving analyte zones. By use of the latter mode, the ability to differentiate a species based on both its fluorescence emission and migration rate is demonstrated for fluorescein and sulforhodamine 101. The detection limit for fluorescein isothiocyanate (FITC) is 1.2 X 10(-20) mol; detection limits for FITC-amino acids are in the (2-8) X 10(-20) mol range.

Spontaneous injection in microcolumn separations.

The phenomenon of spontaneous (ubiquitous) injection in microcolumn separations has been characterized to improve quantitative precision for ultramicrosampling and to enhance separation efficiency. By combining fluorescence imaging, video microscopy, and measurements from capillary electrophoresis, we demonstrate that spontaneous injection is caused primarily by an interfacial pressure difference formed at the inlet of the capillary. This complex injection mechanism has been modeled with some simple assumptions based on fluid dynamics. In particular, studies showed that extraneous injection is reduced up to 12-fold by etching the capillary inlet or by using a thin-walled capillary. Variations by a factor of 2 in the injection length can result from delays between sample introduction and reinsertion into the inlet vial if the timing is not controlled precisely. Evidence is presented that evaporation of buffer from the inlet can reduce the injection length by more than 1 order of magnitude.

Cell-to-cell scanning in capillary electrophoresis.

A widespread limitation in using cell-based biosensors for repetitive chemical analysis is loss of agonist-induced response caused by receptor desensitization. We overcome this problem by scanning an array of immobilized cells underneath a capillary electrophoresis column outlet. In this way, electrophoretically fractionated components that exit the separation capillary are always directed onto cells previously unexposed to receptor agonists. To demonstrate this concept of response recovery using a scanning format, we have chosen the bradykinin B2 receptor system in the NG108-15 cell line, which is known to undergo desensitization. Whereas four subsequent injections of 250 microM bradykinin separated by 120 s are found to reduce the NG108-15 cell response markedly, scanning to new cells can fully restore the response during the separation. Furthermore, by pretesting individual NG108-15 cells for an agonist response and then later scanning back to the same cell, we achieved a 100% success rate in detecting bradykinin in subsequent electrophoretic separations.