Dose effects of LPS on neutrophils in a whole blood flow cytometric assay of phagocytosis and oxidative burst.

Whole blood phagocytosis (P) and oxidative burst (OB), a rapid and sensitive flow cytometric method for quantifying neutrophil activation, was modified for single laser systems by using propidium iodide labeled Staphylococcus aureus and 2',7' dichlorofluorescein diacetate. The purpose of the present study was to characterize this assay with respect to the stimulatory activity of bacterial lipopolysaccharide (LPS) on phagocytosis. Blood from healthy donors was preincubated with log doses of bacterial LPS B (0.1-1,000 ng/ml) or sterile pyrogen-free saline at 37 degrees C from 0-120 minutes. LPS increased both P and OB in a dose-dependent manner (up to 62 and 121%, respectively) at all time points tested, and this effect on P and OB could be detected even with no preincubation. This LPS-induced phagocytic activity could be blocked by the addition of polymyxin B (10 micrograms/ml) during preincubation. The priming effect of LPS was maximal at 45 min. P and OB were inhibited by preincubation with EDTA at doses greater than 2 mM (60 and 80% inhibition, respectively). These observations are consistent with the exquisite sensitivity of the neutrophil to endotoxin. This method can evaluate neutrophil response to immunomodulatory and chemotherapeutic agents in a physiological milieu. These findings re-emphasize the necessity of using pyrogen-free reagents in any study of neutrophil function.     

Flow cytometric kinetic assay of calcium mobilization in whole blood platelets using Fluo-3 and CD41

BACKGROUND: Platelet activation plays a major role in the physiology and pathology of hemostasis. Flow cytometry is a promising approach for the structural and functional analysis of platelets. However, the choice of adequate biological parameters and most technical issues are still under discussion. A rise in cytosolic free Ca2+ is a key early event that follows platelet stimulation and precedes several activation responses, including shape change, aggregation, secretion, and expression of procoagulant activity. Our objective was to set up a fast and sensitive flow cytometric method to determine the kinetics of intracellular Ca2+ mobilization in platelets, which could be performed with the least artifactual perturbation of platelet function. METHODS: Anticoagulated blood was diluted in Tyrode's buffer and incubated with Fluo-3-acetoxymethyl ester prior to staining with phycoerytrin-conjugated antiplatelet GPIIb/IIIa complex monoclonal antibody. Platelets were identified by a gate including only CD41+ events. After the determination of baseline Fluo-3 green fluorescence on a flow cytometer (EPICS XL-MCL, Coulter Electronics, Hialeah, FL), adequate agonists were added and time-dependent changes in Fluo-3 fluorescence were recorded on-line for up to 3 min. RESULTS: In these conditions, a very fast and transient increase of cytosolic-free Ca2+ was observed following the addition of thrombin, a strong platelet agonist. Stimulation with adenosine diphosphate (ADP), a weak agonist, also resulted in evident increase of Ca2+ levels. CONCLUSIONS: Our results show that this flow cytometric kinetic method provides a simple and sensitive tool to assess in vitro the time course and intensity of signal transduction responses to different platelet agonists under near physiological conditions. In this way, it may be useful to evaluate the degree of platelet reactivity and thus to monitor antiplatelet therapy.     

A flow cytometric assay for intracellular nonprotein thiols using mercury orange

The level of nonprotein thiols was assayed in individual mammalian cells using flow cytometry. Previous determinations of glutathione (GSH, the most abundant nonprotein thiol in most cells) by flow cytometry were based on UV laser excitation of fluorochromes. Because of several shortcomings of UV excitation, an assay for GSH using visible light is of interest. Selective staining of nonprotein thiols with mercury orange (a mercurial compound that binds stoichiometrically to sulfhydryl groups) was obtained by restricting the staining time. By using various drugs that affect GSH levels and overall thiol levels in cells, it was shown that GSH is the primary thiol group being stained. Thus a quick, specific technique using mercury orange has been developed for the flow cytometric determination of nonprotein thiols and preferentially for GSH in individual mammalian cells.     

The flow cytometric analysis of cytokines using multi-analyte fluorescence microarray technology

Cytokines, which are small peptides that act as hormones of the immune system, affect cells throughout the body in a variety of different ways. These cellular signaling molecules often have synergistic or opposing effects on various cell types and often different cytokines have overlapping activities. There is great advantage, therefore, to be able to assess a pattern of cytokine responses in certain inflammatory, autoimmune, transplant or immunodeficiency states. This is one of the major advantages of the new particle-based flow cytometric assays, which have become available. We have employed such assays to analyze up to 10 different cytokines in cultured supernatants of stimulated mononuclear cells and in as little as 75 microL of serum from patients with a variety of different disorders. In developing these assays and validating them for use in our esoteric reference laboratory (ARUP Laboratories), we have found that a variety of heterophile antibodies can lead to both false positive and false negative results. This review will describe the development of our multi-analyte cytokine assays and document the interference derived from heterophile antibodies. Lastly, we will point out various procedures that we have utilized to include internal controls directly in the assays, which allow one to routinely detect these interfering antibodies, as well as methods we have developed to circumvent the interference posed by these antibodies.     

Evaluation of rapid immunochromatographic assay kit for HBsAg-screening using whole blood

A rapid immunochromatographic assay kit using whole blood to screen hepatitis B surface antigen was developed and evaluated by using sera from 240 patients. The reference diagnosis was based on the results obtained with GENEDIA Anti-HBs Rapid kit which is very similar to the above kit except for the use of serum. The test demonstrated a good correlation with the reference immunochromatographic assay kit, that is, the sensitivity and the specificity of the kit was 100%, respectively. The rapid test kit using whole blood should be more convenient and useful for the diagnosis of hepatitis B virus because the kit does not need machines and time to prepare serum. In addition, this kit is safe from inadvertent infection during sample treatment because the blood is sterilized with hydrogen peroxide, eliminates the procedure required to prepare serum and reduces the possibility of exposure to infectious agents.     

A modular detector for flow cytometric multicolor fluorescence measurements

A modular detector for measuring multicolor fluorescence from cells illuminated by single or multiple lasers has been developed for flow cytometers. Motion picture projector, camera, and CCTV/video lenses were evaluated for use in the detector by comparing their physical characteristics, image quality, and light collection efficiencies. A 25-mm focal length F/0.95 CCTV lens was selected, based on our criteria and test results. The detector was constructed out of square aluminum extrusion channels. A CCTV lens mounted on the outside of the first channel collected light emitted from cells and collimated it towards filters and secondary CCTV lenses located in each channel. The secondary lenses functioned as relay optics for directing and focusing light onto pinhole spatial filters for measurement by photomultipliers. The detector design allowed any number of channels to be connected together and the versatility for making simultaneous or sequential measurements. Measurements on lymphocytes labeled with four monoclonal antibodies conjugated to fluorescent dyes and measurements on viable tumor cells stained for DNA content and with three fluorescent-labeled antibodies were used to demonstrate the detector's capabilities.     

Rapid in vitro biocompatibility assay of endovascular stents by flow cytometry using platelet activation and platelet-leukocyte aggregation

Clinical studies suggest that stent design and surface texture are responsible for differences in biocompatibility of metallic endovascular stents. A simple in vitro experimental setup was established to test stent-induced degree of platelet and leukocyte activation and platelet-leukocyte aggregation by flow cytometry. Heparin-coated tantalum stents and gold-coated and uncoated stainless steel stents were tested. Stents were implanted into silicone tubes and exposed to blood from healthy volunteers. Platelet and leukocyte activation and percentage of leukocyte-platelet aggregates were determined in a whole-blood assay by subsequent staining for activation-associated antigens (CD41a, CD42b, CD62p, and fibrinogen binding) and leukocyte antigens (CD14 and CD45) and flow cytometric analysis. Blood taken directly after venous puncture or exposed to the silicone tube alone was used as negative controls. Positive control was in vitro stimulation with thrombin receptor activating peptide (TRAP-6). Low degree of platelet activation and significant increase in monocyte- and neutrophil-platelet aggregation were observed in blood exposed to stents (P < 0.05). In addition, leukocyte activation was induced as measured by increased CD45 and CD14 expression. Heparin coated stents continuously induced less platelet activation and leukocyte-platelet aggregation than uncoated stainless steel stents of the same length and shorter stents of the same structure. Stent surface coating and texture plays a role in platelet and leukocyte activation and leukocyte-platelet aggregation. Using this simple in vitro assay and whole blood and flow cytometry, it seems possible to differentiate stents by their potency to activate platelets and/or leukocytes. This assay could be applied for improving the biocompatibility of coronary stents.     

Quantitative measurement of mast cell degranulation using a novel flow cytometric annexin-V binding assay.

BACKGROUND: Mast cells are primary mediators of allergic inflammation. Antigen-mediated crosslinking of their cell surface immunoglobulin E (IgE) receptors results in degranulation and the release of proinflammatory mediators including histamine, tumor necrosis factor-alpha, and leukotrienes. METHODS: Mast cells were stimulated to degranulate by using either IgE crosslinking or ionophore treatment. Exogenously added annexin-V was used to stain exocytosing granules, and the extent of binding was measured flow cytometrically. Release of the enzyme beta-hexosaminidase was used for population-based measurements of degranulation. Two known inhibitors of degranulation, the phosphatidylinositol 3 kinase inhibitor wortmannin and overexpression of a mutant rab3d protein, were used as controls to validate the annexin-V binding assay. RESULTS: Annexin-V specifically bound to mast cell granules exposed after stimulation in proportion to the extent of degranulation. Annexin-V binding was calcium dependent and was blocked by phosphatidylserine containing liposomes, consistent with specific binding to this membrane lipid. Visualization of annexin-V staining showed granular cell surface patches that colocalized with the exocytic granule marker VAMP-green fluorescent protein (GFP). Wortmannin inhibited both annexin-V binding and beta-hexosaminidase release in RBL-2H3 cells, as did the expression of a dominant negative rab3d mutant protein. CONCLUSIONS: The annexin-V binding assay represents a powerful new flow cytometric method to monitor mast cell degranulation for functional analysis.     

A method for calibration of flow cytometric wavelength shift fluorescence measurements

Recently, new fluorescent dyes have been introduced into flow cytometry which alter their spectral characteristics when changes occur in certain cell features, e.g., intracellular pH or calcium ion concentration. Such changes may be determined by measuring the fluorescence intensity ratio in two different wavelength ranges (5). Here a new method is described, which simplifies the use of steadily flowing fluids for calibration. The pulse electronics of a flow cytometer cannot process the static fluorescence signals of a streaming fluid. If, however, the exciting or emitted fluorescence light of a calibration fluid is made pulsating, the flow cytometer electronics can evaluate those pulses. The new calibration procedure uses measurement of two wavelength windows shown in a two-parameter display to generate an absolute calibration scale. Measurement of the spectral shift in calibration fluids under identical instrumental settings provides absolute values that measurements of intracellular concentrations can be referred to.     

Flow cytometric evaluation of leukocyte function in rat whole blood

The aim of this study was to establish a standard flow cytometric method to measure the phagocytic function of and intracellular hydrogen peroxide (H2O2) production by rat leukocytes. Thirty-six adult, male Sprague-Dawley rats were included in this study. Whole-blood specimens from the inferior vena cava were collected in a heparinized tube and ethylenediaminetetraacetic acid (EDTA) anticoagulated tube. The phagocytic function of and intracellular H2O2 generation by leukocytes were measured with FACS Vantage trade mark flow cytometer (Becton Dickinson, San Jose, CA), using fluorescent microspheres and dihydrorhodamine-123 as probes, respectively. Several conditions were optimized in this study, including anticoagulants (heparin and EDTA), fluorescent probes (0.75- and 1.72-microm-diameter microspheres), incubation time, and concentration of the chemicals used in the experiment. Neutrophils, monocytes, and lymphocytes could be clearly defined and separated in whole blood by flow cytometry and tested for phagocytosis and intracellular H2O2 generation without the need for further purification and handling of the cells. Intracellular H2O2 production by and phagocytic function of neutrophils and monocytes were inhibited in EDTA-anticoagulated blood compared with heparin- anticoagulated blood (P < 0.01). Neutrophils showed similar phagocytic function to 0.75- and 1.72-microm microspheres, but monocytes showed weak phagocytic activity to 1.72-microm beads compared with 0.75-microm beads (P < 0.01). In conclusion, a flow cytometric method to measure the phagocytic function of and intracellular H2O2 production by rat leukocytes has been developed. Quantitative flow cytometric analysis of rat leukocyte function is convenient and feasible and provides a reliable and rapid assay to assess phagocytosis and intracellular H2O2 production by rat neutrophils and monocytes.     

Viscoelastic properties of whole blood. Influence of fast sedimenting red blood cell aggregates

Red blood cell (RBC) aggregation is known to be of deciding influence on erythrocyte sedimentation-rate (ESR) and on whole blood viscoelastic properties. The rheological behaviour of blood collected from a control-group with normal ESR is compared to the viscoelastic behaviour of blood collected from two groups with high to very high ESR, whose individuals are suffering from chronical polyarthritis and Morbus Bechterew, respectively. The rheological properties are evaluated by means of an oscillating-flow capillary-rheometer where the viscous (eta') and elastic (eta") component of the complex viscosity (eta) is measured at a constant frequency of 2 Hz. Correcting for the varying hematocrit of the different blood samples according to an exponential equation, the viscoelastic data are found to be elevated in the groups with high ESR. For the viscous properties this is only due to the increase of the plasma viscosity. A correction for the plasma viscosity, however, shows that the viscous properties at low shear- rates (2s-1) are significantly reduced, whereas elastic properties in a range of medium shear-rates (10s-1 to 50s-1) are significantly increased (P less than 0.001, t-test of Student). This result is discussed to be due to the high packing density of the RBC in fast sedimenting aggregates. High packing density reduces the effective volume of the RBC but increases the stiffness of the aggregates.     

Detection of granulocyte reactive oxygen species formation in whole blood using flow cytometry.

We have developed a technique for analysis of granulocyte reactive oxygen species formation in whole blood using flow cytometry and two color immunofluorescence. This technique relies upon the use of specific fluorescent dye (LDS-751) to stain nucleated cells, eliminating erythrocytes from analysis. Using LDS-751, forward angle light scatter, and 90 degrees side scatter, a granulocyte gate, monocyte gate, and lymphocyte gate were identified. Analysis with multiple FITC conjugated monoclonal antibodies demonstrated greater than 95% purity of a flow cytometrically identified granulocyte population in whole blood without physical manipulation of the blood. Utilizing 2'7' dichlorofluorescein diacetate (DCFH-DA), we were able to measure granulocyte intracellular reactive oxygen species production. Dose response curves were obtained for the effect of granulocyte agonists phorbol myristate acetate, FMLP, and heat fixed Staphylococcus aureus on reactive oxygen species production. The techniques described in this paper should be useful for measuring granulocyte activation in vivo with flow cytometry.     

A flow cytometric assay for screening improved heterologous protein secretion in yeast

Selection of highly productive hosts for protein expression is a significant component of bioprocess design. As an alternative to traditional plate, halo, and suppression-based screens, we describe a high-throughput, flow cytometric assay, the Cell Surface Secretion Assay (CeSSA), that can be used to select for improved heterologous protein secretion from a population of S. cerevisiae mutants. A ligand is covalently attached to the cell surface via a PEG linker, and as cells secrete a protein that binds the tethered ligand, the protein is captured on the surface where it can be labeled and the cells sorted using flow cytometry. This report describes three different protein/ligand interactions that have been demonstrated with this system. Single-pass sorting enrichments from 23- to 54-fold have been validated in the separation of a 3-fold higher secretor from a background population of wild-type secretors making this system applicable to large library screening (10(8) clones). A mathematical model was developed to improve the parameters of the assay further. The model was validated with time course data and predicts an optimal screening window. The model also predicts a 60-fold enrichment rate for the validation experiment described above. With the development of this selection system, limitations presented by traditional, particularly plate-based, secretion assays can be overcome so that a larger search space can be examined under conditions closer to the growth physiology experienced by cells in fermentors.     

A time-resolved immunofluorometric assay for porcine C-reactive protein quantification in whole blood.

A time-resolved immunofluorometric assay (TR-IFMA) for C-reactive protein (CRP) determination in whole blood of pigs was developed and validated. CRP was isolated from porcine acute-phase serum by affinity chromatography on agarose, coupled with phosphorylethanolamine and polyclonal antibodies to porcine CRP were purified from antiserum raised in sheep immunized with porcine CRP. Intra- and inter-assay coefficients of variation (CVs) were in the range 3.13-7.19% and 7.06-15.66%, respectively, showing good precision. The assay measured the CRP values in a proportional and linear manner (r=0.99); additionally, CRP concentrations measured in whole blood by the present TR-IFMA and in serum by an established immunoturbidimetric assay were highly correlated (R(2)=0.97). The limit of detection of the method was 0.0028 mg/L. Significantly lower CRP concentrations were observed after 7 days of sample storage at 4 degrees C. The injection of turpentine oil caused a significant increase in CRP concentrations and significantly higher CRP concentrations were observed in pigs with pathological processes compared to healthy animals.     

Multidimensional flow cytometric blood cell differentiation without erythrocyte lysis.

Forward light scattering, orthogonal light scattering, and the fluorescence intensities of unlysed peripheral blood cells, labeled with CD45-phycoerythrin and the nucleic acid dyes LDS-751 and thiazole orange, were measured simultaneously, utilizing a flow cytometer. Erythrocytes, reticulocytes, platelets, neutrophils, eosinophils, basophils, monocytes, lymphocytes, nucleated erythrocytes, and immature nucleated cells occupied unique positions in the five-dimensional space created by the listmode storage of the five independent parameters. A software program was developed which identified and enumerated each of these cell populations. Platelets in this study were identified by LDS-751 staining, in addition to their forward and orthogonal light-scattering characteristics. Validation of this approach was obtained by demonstrating that all CD41- or CD42-expressing platelets also stained with LDS-751. Furthermore, the staining by LDS-751 did not change following platelet activation with ADP. The quantification of erythrocytes, platelets, neutrophils, eosinophils, monocytes, and lymphocytes correlated well with data obtained with a commercial hematology whole blood analyzer (H-1). Reproducibility of the identification of these populations was shown by repeated measurement of the same sample and by staining and analysis of multiple aliquots of identical blood samples. Stability studies demonstrated that 8 hours after blood collection, the number of damaged cells increased. This could be measured by a greater thiazole orange uptake by the damaged cells. This investigation demonstrates the feasibility of multidimensional flow cytometric blood cell differentiation for an automated whole blood cell analysis without the necessity of erythrocyte lysis. The ability to simultaneously identify reticulocytes, nucleated erythrocytes, and immature nucleated cells in one measurement is unique and promises to be a powerful tool for the assessment of abnormal blood samples.     

Rapid titer assay of adenovirus containing green fluorescent protein gene using flow cytometric analysis

The plaque assay has been widely used for titration of adenovirus (AdV). However, it takes usually 2-3 weeks, so this slow assay often impedes bioprocess development of large-scale AdV production. In this study, we developed a rapid AdV titration assay that can be done within a day. Further, unlike the plaque assay, this assay does not require a laborious serial dilution of samples. This rapid assay can be achieved by using green fluorescent protein (GFP) as a marker gene and flow cytometric analysis. It yields a good correlation between infectious titer of AdV harboring GFP and flow cytometric parameters such as average green fluorescence intensity or % of infected cells. Taken together, this rapid assay will facilitate bioprocess development for efficient large-scale AdV production.     

A novel multiparameter flow cytometric assay for inosine triphosphatase expression analysis in leukocytes

The aim of this study was to assess inosine triphosphate (ITPase) expression in the different leukocyte populations present in peripheral blood samples of a nonimmune compromised control group. For this purpose, a multiparameter flow cytometric assay was developed and performed to study ITPase expression in peripheral leukocyte subpopulations of healthy volunteers (n = 20). Qualitative ITPase expression was assessed by determining the percentage of ITPase-positive cells. Quantitative data were obtained by measuring the median fluorescent intensity (MFI). Subcellular localization of ITPase was analyzed using immunocytochemistry. Immunocytochemistry showed that ITPase is present in all leukocytes and localized intracellular. Based on this finding, a multiparameter flow cytometric assay was developed using a Fix & Perm strategy. Qualitative and quantitative ITPase expression remained stable (variation, <10%) for at least 48 h after blood sampling. MFI values showed that activated monocytes contained significantly more ITPase when compared to the total monocyte fraction (P < 0.0001), which subsequently had a higher amount of expression than granulocytes (P < 0.0001). In addition, the phagocyte subpopulations ([activated] monocytes and granulocytes) contained significantly higher levels of ITPase when compared to lymphocytes (P < 0.0001). Within the lymphocyte fraction, it appeared that T-helper cells contained significantly higher ITPase levels when compared to cytotoxic T cells, B lymphocytes, and natural killer cells (P < 0.0001). Our study is the first which describes a flow cytometry assay to analyze ITPase expression in leukocytes qualitatively as well as quantitatively and visualizes the intracellular localization of ITPase in leukocytes. ? 2012 International Society for Advancement of Cytometry.     

A new four-color flow cytometric assay to detect apoptosis in lymphocyte subsets of cultured peripheral blood cells

BACKGROUND: Human peripheral blood lymphocytes kept in culture after isolation die by an apoptotic process. Detection of apoptosis with labeled Annexin V to demonstrate loss of plasma membrane asymmetry is sensitive, specific, and easy using flow cytometry. This is true in lymphoblastic cell lines when combining Annexin V-fluorescein isothiocyanate (FITC) and propidium iodide (PI). However, measurement of apoptosis by flow cytometry in isolated human lymphocytes using Annexin V-FITC/PI is disturbed by the presence of a variable percentage of erythrocytes in the isolated lymphocyte population. To overcome this problem, we have developed and tested a new four-color flow cytometric assay to detect apoptosis in lymphocyte subsets of cultured peripheral blood cells. METHODS: Peripheral blood lymphocytes are isolated by density gradient centrifugation. Nucleus-containing cells are selected using CD45-phycoerythrin (PE). The lymphocyte subset of interest is selected using CD4, CD8, or CD19 energy-coupled dye (ECD) labeling. Apoptosis is detected using Annexin V-FITC with 7-amino-Actinomycin-D (7-AAD) to distinguish early apoptotic from late apoptotic lymphocytes. RESULTS: We have developed a new technique to detect apoptosis in isolated human peripheral blood lymphocyte subsets with good reproducibility, coefficient of variation < 17%. CONCLUSIONS: We now have a validated tool to study apoptosis in subsets of isolated human lymphocytes to increase our knowledge of pathogenesis and therapies in lymphoreticular malignancies.     

Novel calibration method for flow cytometric fluorescence resonance energy transfer measurements between visible fluorescent proteins.

BACKGROUND: The combination of fluorescence resonance energy transfer (FRET) and flow cytometry offers a statistically firm approach to study protein associations. Fusing green fluorescent protein (GFP) to a studied protein usually does not disturb the normal function of a protein, but quantitation of FRET efficiency calculated between GFP derivatives poses a problem in flow cytometry. METHODS: We generated chimeras in which cyan fluorescent protein (CFP) was separated by amino acid linkers of different sizes from yellow fluorescent protein (YFP) and used them to calibrate the cell-by-cell flow cytometric FRET measurements carried out on two different dual-laser flow cytometers. Then, CFP-Kip1 was coexpressed in yeast cells with YFP and cyclin-dependent kinase-2 (Cdk2) and served as a positive control for FRET measurements, and CFP-Kip1 coexpressed with a random peptide fused to YFP was the negative control. RESULTS: We measured donor, direct, and sensitized acceptor fluorescence intensities and developed a novel way to calculate a factor (alpha) that characterized the fluorescence intensity of acceptor molecules relative to the same number of excited donor molecules, which is essential for quantifying FRET efficiency. This was achieved by calculating FRET efficiency in two different ways and minimizing the squared difference between the two results by changing alpha. Our method reliably detected the association of Cdk2 with its inhibitor, Kip1, whereas the nonspecific FRET efficiency between Cdk2 and a random peptide was negligible. We identified and sorted subpopulations of yeast cells showing interaction between the studied proteins. CONCLUSIONS: We have described a straightforward novel calibration method to accurately quantitate FRET efficiency between GFP derivatives in flow cytometry.     

Calibration of a flow cytometric assay of glucose-6-phosphate dehydrogenase activity.

The reduction of tetrazolium salts to colored formazans is a reaction which has been exploited both in histo- and cytochemistry. Tetrazolium salts forming fluorescent formazans prove suitable for measuring defined cellular dehydrogenase activities in automated processes. This study considers an important aspect of formazan measurement in flow cytometry, namely, calibration. Calibration is performed by correlating the number (and fluorescence intensity) of formazan-bearing cells measured by flow cytometry with simultaneously performed biochemical analyses of the same material. The method is demonstrated by an example of glucose-6-phosphate dehydrogenase. Using the data of a typical experiment, the enzyme activity is expressed in femtomol of hydrogen transferred per cell during incubation time. Furthermore, through spatially resolved double excitation of formazan and nuclear DAPI fluorescence, an independent analysis of cell cycle and cellular enzymatic activity is established.