UV lasers for flow cytometric analysis: HeCd versus argon laser excitation.

Applying flow cytometric single cell analysis, we compared the performance of UV excitation from argon ion and HeCd lasers using various UV-excitable fluorochromes of cell kinetic and cell physiological relevance. The AT-specific DNA fluorochromes DAPI, Hoechst 33258, and Hoechst 33342 showed no significant differences of G1-phase resolution and cell cycle distribution. With the HeCd laser, high-resolution cell kinetic analysis applying the novel BrdU/Hoechst-PI quenching technique showed superior resolution and an almost normalized G2M/G1 channel ratio of the first cell cycle. Indo-1 analysis for detection of intracellular free calcium gave similar results for both excitation sources, although the indo-1 ratio of activated cells was lower for HeCd excitation. Monochlorobimane as an indicator fluorochrome of glutathione content could not be excited sufficiently with the 325-nm line of the HeCd laser and exhibited poor resolution between positive and negative cells. However, the second glutathione-specific fluorochrome o-phtalaldehyde gave even better results with the HeCd laser. Our data indicate that air-cooled HeCd lasers are cheap and reliable UV-excitation sources for most UV-excitable fluorochromes, and might be an alternative to the expensive water-cooled argon and krypton laser.     

A comparison of low-power helium-cadmium and argon ultraviolet lasers in commercial flow cytometers

The feasibility of installing a low power ultraviolet (UV) laser in a commercial flow cytometer was evaluated by testing an Ortho Cytofluorograf 50HH and a Coulter Epics V. Both instruments were equipped with two argon ion lasers, one emitting at 488 nm and the other in the UV region and were tested by measuring the DNA content of cells stained with Hoechst 33342 or DAPI. The coefficient of variation (CV) of the G0/G1 peak of the DNA histograms produced by each instrument did not deteriorate markedly when results obtained at 100-125 mW were compared to those obtained at 10 mW. These tests indicated that a helium-cadmium laser (He-Cd) which can produce 10 mW at 325 nm should work well as a UV laser in these instruments. An Ortho Cytofluorograf IIs was purchased with a 10 mW He-Cd laser installed in the forward position. Studies of DNA content have confirmed that this low power UV laser can produce CVs of 2.2% with DAPI stained fixed cells and 3.6% with Hoechst 33342 stained viable lymphocytes. Thus, the He-Cd laser should provide a reasonable alternative as a UV source for flow cytometers.     

Extended application of flow microfluorometry by means of dual laser excitation

Summary A dual laser beam excitation device for flow analysis of biological particles has been developed. The aid of this arrangement is to increase the range of fluorescent agents employed so far in quantitative and qualitative cytochemistry. Combining an argon ion and a helium-cadmium laser two color fluorescence measurements were performed employing propidium iodide as a DNA stain and fluorescamine which stains total protein in fixed cells. Energy transfer processes between the antibiotic and DNA specific dye mithramycin and propidium iodide both being bound to nuclear chromatin were analyzed. Utilization of energy transfer processes is generally discussed as a mean to extract information about the structure and conformation of nuclear chromatin in situ. The application of a crypton ion laser with three lines near 400 nm and a single line at 350 nm having a light output in each range of nearly one Watt gives the opportunity of utilizing DNA fluorochromes which have an excitation maximum in the deep blue region. DNA spectra are shown employing mithramycin, the benzimidazol derivative 33258 (Hoechst) and the indol compound DAPI which has a high DNA specifity combined with a great stability under UV illumination. By separating two focussed laser beams at their intereecting points with the liquid sample stream the trajectory of each flowing cell crosses the beams sequentially, which causes a solitary dual excitation of each cell. The advantages of a solitary excitation device compared with a simultaneous one is discussed.This work has been supported by the ministry of research and technology (FRG), contract No. 01VH015-B13MT 225a     

Combination of Budr-Quenched Hoechst Fluorescence With Dna-Specific Ethidium Bromide Fluorescence For Cell Cycle Analysis With A Two-Parametrical Flow Cytometer

Stimulated or asynchronous L-cells were grown in a BUdR-medium, harvested and stained with a combination of 33258 Hoechst and ethidium bromide for analysis in a FACS II cell sorter. the u.v. laser line served as a light source for exciting the Hoechst fluorescence, the ethidium bromide fluorescence being excited mainly by energy transfer from the Hoechst dye. the quenched Hoechst fluorescence was analysed between 410 nm and 480 nm, the DNA specific EB fluorescence at beyond 630 nm. Thus, not only the actual location of each cell in the cycle could be determined, but also its initial location at time 0 of the experiment, together with its moment of division (BUdR-quenched Hoechst fluorescence). This method could become a powerful tool in many investigations dealing with cell cycle perturbations in culture.     

Combination of BUdR-quenched Hoechst fluorescence with DNA-specific ethidium bromide fluorescence for cell cycle analysis with a two-parameter flow cytometer

Stimulated or asynchronous L-cells were grown in a BUdR-medium, harvested and stained with a combination of 33258 Hoechst and ethidium bromide for analysis in a FACS II cell sorter. The u.v. laser line served as a light source for exciting the Hoechst fluorescence, the ethidium bromide fluorescence being excited mainly by energy transfer from the Hoechst dye. The quenched Hoechst fluorescence was analysed between 410 nm and 480 nm, the DNA specific EB fluorescence at beyond 630 nm. Thus, not only the actual location of each cell in the cycle could be determined, but also its initial location at time 0 of the experiment, together with its moment of division (BUdR-quenched Hoechst fluorescence). This method could become a powerful tool in many investigations dealing with cell cycle perturbations in culture.     

Simultaneous analysis of DNA content and surface antigens in human bone marrow

In order to identify when cellular expansion occurs during hematopoietic maturation, a method was developed for the simultaneous analysis of one or two cell-surface antigens and DNA content on bone marrow cells while preserving their light-scatter properties. Proliferation in a population defined by light-scatter and surface-antigenic characteristics was assessed by measuring the percentage of cells in this population having more than 2C amount of DNA ("proliferation index"). Viable, low-density (1.077 g/cm3), bone marrow cells, stained with monoclonal antibodies conjugated with fluorescein or phycoerythrin, were fixed with paraformaldehyde and subsequently treated with the detergent, Tween 20. The UV-excitable DNA stain Hoechst 33342 was used to quantify DNA content in the cells without interference with immunofluorescence. A FACS IV flow cytometer was used, equipped with the first laser at 488 nm emitting for light scattering and immunofluorescence measurements and the second laser emitting at 360 nm for the Hoechst excitation. The Hoechst uptake was the same for all bone marrow populations, yielding a tight coefficient of variation (CV) (average 5.0%) for the G0/G1 DNA peak. This permitted high sensitivity of cell detection in S, G2, and M phases of the cell cycle, while preserving light-scattering properties of the cells and maintaining cell surface immunofluorescence. The lowest "proliferation index" detected using this technique was 0.08% in a sample obtained from a patient with chronic lymphocytic leukemia. Normal helper T lymphocytes in marrow had approximately 0.5% of the cells in S, G2, or M phase. We show that the erythroid lineage, in the adult normal bone marrow, is the most active in proliferation among all hematopoietic lineages.     

Fluorescence enhancement of DNA-bound TO-PRO-3 by incorporation of bromodeoxyuridine to monitor cell cycle kinetics.

BACKGROUND:The detection of DNA-incorporated bromodeoxyuridine (BrdUrd) in mammalian cells is a well-known and important technique to study cell cycle. The use of TO-PRO-3 for detection of BrdUrd substitution of DNA by dual-laser flow cytometry has been investigated. METHODS:Fluorescence enhancement of TO-PRO-3 in BrdUrd-labeled cells is registered in combination with the fluorescence emission of the intercalating dye propidium iodide (PI) as a total DNA stain to give bivariate DNA/BrdUrd histograms. By the low concentration of only 0.3 mircoM TO-PRO-3, BrdUrd detection is optimized, and undisturbed total DNA content by PI can be detected as well. TO-PRO-3 is excited by a red HeNe laser and PI by an argon ion laser. RESULTS:In order to understand the binding of TO-PRO-3, energy transfer from PI to TO-PRO-3 has been measured as well as the influence of an external DNA binding dye such as Hoechst 33258 with Adenine-Thymine (AT) binding specificity. Cell cycle studies of human SCL-2 keratinocytes and mouse 3T3 cells prove the method to be as generally applicable as the classical BrdUrd/Hoechst quenching technique, but without need for expensive ultraviolet laser excitation. No BrdUrd sensitivity could be found for the similar dyes TO-PRO-1 and YO-PRO-3, whereas TO-PRO-5 and YOYO-3 showed only very little sensitivity to BrdUrd labeling as compared with TO-PRO-3. CONCLUSIONS:Cell cycle studies of mammalian cells can be done by dual-laser flow cytometry without the need for ultraviolet lasers by using the BrdUrd-dependent fluorescence enhancement of TO-PRO-3. Total DNA content can be measured simultaneously using PI.     

Flow cytometric analysis of cell cycle-dependent changes in cell thiol level by combining a new laser dye with Hoechst 33342.

By halogenation of methylfluorescein-diacetate (MFDA) or eosin-diacetate, two new dyes for cellular thiol compatible with visible laser excitation have become available. These probes circumvent the use of an ultraviolet (UV)-excitation system as required by bimane-based dyes and allow combination with probes for other cellular parameters. The thiol dyes attain maximal staining after 10 min at 37 degrees C, and fluorescence is sensitive to pretreatment with diethylmaleate but not to buthionine sulfoximine. In a dual-laser system, analysis of the cellular thiol level as a function of cell cycle distribution can be achieved in viable cells by simultaneous staining with the bisbenzimidazole dye Hoechst 33342 and one of the halogenated dyes. Using this approach, we were able to show that cells in the G2 phase of the cell cycle were more sensitive to thiol depletion with diethylmaleate than were cells in the G1 compartment. The new thiol dyes allow a more flexible selection of wavelengths of excitation and emission for assessing changes in cellular thiol (glutathione and other thiol compounds) and allow this parameter to be examined as a function of cell cycle position.     

Measurement of efflux from G1-phase in a growth factor dependent cell line

In order to test a mathematical model of G1/S-phase transition, the proliferative response of the murine myeloid interleukin 3 (IL-3) dependent cell line NFS-78 to graded reduction of IL-3 levels was measured. Exponentially growing cells were exposed to bromodeoxyuridine (BUdR), which replaces thymidine (TdR) in the DNA double strands during DNA synthesis. After incubation periods ranging from 3 to 36 h the cells were fixed and stained with a fluorescence dye mixture of Hoechst 33258 and ethidium bromide (EB) and subsequently analyzed in a two-parametrical flow cytometer. The BUdR-quenched TdR-specific Hoechst 33258 fluorescence of each cell provides information on the cell cycle location at the start of incubation and on whether or not a cell has divided. The DNA-specific EB fluorescence provides information on the actual cell cycle location at the end of the incubation period. From the 2-dimensional fluorescence distributions the efflux from G1-phase was calculated. Upon IL-3 reduction the cells showed accumulation in the Gl-phase along with a reduction in the progression rate through the other phases of the cell cycle. By staining with the vital dye Hoechst 33342 as well as with propidium iodide (PI) it was further possible to show that cell death after IL-3 withdrawal occurred in all phases of the cell cycle.     

Dual excitation multi- fluorescence flow cytometry for detailed analyses of viability and apoptotic cell transition

The discrimination of live/dead cells as well as the detection of apoptosis is a frequent need in many areas of experimental biology. Cell proliferation is linked to apoptosis and controlled by several genes. During the cell life, specific events can stimulate proliferation while others may trigger the apoptotic pathway. Very few methods (i.e. TUNEL) are now available for studies aimed at correlation between apoptosis and proliferation. Therefore, there is interest in developing new methodological approaches that are able to correlate apoptosis to the cell cycle phases. Recently new approaches have been proposed to detect and enumerate apoptotic cells by flow cytometry. Among these, the most established and applied are those based on the cell membrane modifications induced in the early phases of the apoptotic process. The dye pair Hoechst 33342 (HO) and Propidium Iodide (PI), thanks to their peculiar characteristics to be respectively permeable and impermeable to the intact cell membrane, seems to be very useful. Unfortunately the spectral interaction of these dyes generates a consistent "energy transfer" from HO to PI. The co-presence of the dyes in a nucleus results in a modification in the intensity of both the emitted fluorescences. In order to designate the damaged cells (red fluorescence) to the specific cell cycle phases (blue fluorescence), we have tested different staining protocols aimed to minimize the interference of these dyes as much as possible. In cell culture models, we are able to detect serum-starved apoptotic cells as well as to designate their exact location in the cell cycle phases using a very low PI concentration. Using a Partec PAS flow cytometer equipped with HBO lamp and argon ion laser, a double UV/blue excitation has been performed. This analytical approach is able to discriminate live blue cells from the damaged (blue-red) ones even at 0.05 micro g/mL PI. The same instrumental setting allows performing other multi-colour analyses including AnnexinV-FITC as well as the possibility to make a correlated analysis to phenotype markers.     

Analysis of UV-excited fluorochromes by flow cytometry using near-ultraviolet laser diodes.

INTRODUCTION: Violet laser diodes have become common and reliable laser sources for benchtop flow cytometers. While these lasers are very useful for a variety of violet and some ultraviolet-excited fluorochromes (e.g., DAPI), they do not efficiently excite most UV-stimulated probes. In this study, the next generation of InGaN near-UV laser diodes (NUVLDs) emitting in the 370-375-nm range have been evaluated as laser sources for cuvette-based flow cytometers. METHODS: Several NUVLDs, ranging in wavelength from 370 to 374 nm and in power level from 1.5 to 10 mW, were mounted on a BD Biosciences LSR II and evaluated for their ability to excite cells labeled with the UV DNA binding dye DAPI, several UV phenotyping fluorochromes (including Alexa Fluor 350, Marina Blue, and quantum dots), and the fluorescent calcium chelator indo-1. RESULTS: NUVLDs at the 8-10-mW power range gave detection sensitivity levels comparable to more powerful solid-state and ion laser sources, using low-fluorescence microsphere beads as measurement standards. NUVLDs at all tested power levels allowed extremely high-resolution DAPI cell cycle analysis, and sources in the 8-10-mW power range excited Alexa Fluor 350, Marina Blue, and a variety of quantum dots at virtually the same signal-to-noise ratios as more powerful UV sources. CONCLUSIONS: These evaluations indicate that near-UV laser diodes installed on a cuvette-based flow cytometer performed nearly as well as more powerful solid-state UV lasers on the same instrumentation, and comparably to more powerful ion lasers on a jet-in-air system, and. Despite their limited power, integration of these small and inexpensive lasers into benchtop flow cytometers should allow the use of flow cytometric applications requiring UV excitation on a wide variety of instruments.     

Isolation of side population cells from endometrial cancer cells using a violet laser diode

Cancer stem cells (CSCs) possess the ability for self-renewal, differentiation, and tumorigenesis and play a role in cancer recurrence and metastasis. CSCs are usually sorted in analysis into side population (SP) cells using ultraviolet (UV) laser (350 nm) excitation; they cannot be stained with Hoechst 33342 because of their efflux ability. However, it is difficult to avoid cell damage using a UV laser. Therefore, we attempted to isolate CSCs using a violet laser (407 nm) excitation to avoid cellular DNA damage. We sorted SP cells and main population (MP) cells from a human endometrial cancer cell line using the FACSAria system equipped with a violet laser and analyzed the biological properties of these cells. SP cells exhibited drug efflux, self-renewal, differentiation abilities, and tumorigenicity. It was found that v-Ki-ras2 Kirsten rat sarcoma viral oncogene homolog (KRAS) expression was significantly higher in SP cells than in MP cells. Our results suggest that CSCs exist in the SP fraction sorted using the FACSAria system equipped with a violet laser, which presents a useful tool to isolate small populations of viable putative CSCs from solid tumors and can be used to identify and characterize CSCs.     

Multicolor immunofluorescence and flow cytometry utilizing cascade blue to purify murine hematopoietic stem cells from fetal liver and bone marrow.

BACKGROUND: Here we demonstrate the utility of cascade blue (CB), to purify hematopoietic stem cells by flow cytometry. Multicolor immunofluorescence and the sensitivity (signal-to-noise) of the fluorochromes are essential for the identification and isolation of rare stem cell populations. METHODS: We isolated hematopoietic stem cells utilizing a 407 nm laser line to excite CB and propidium iodide (PI) in combination with FITC, PE, and Red670 which were excited at 488 nm. RESULTS: CB is maximally excited using a 407 nm laser line, when compared to UV or 413 nm excitation. The increase in sensitivity of CB at 407 nm can be contributed to higher absorption of CB and a reduction of autofluorescence at this excitation wavelength (Ropp et al.: Cytometry 21: 309-317, 1995). CONCLUSIONS: Despite the fact that the CB antibody conjugate has a tendency to adhere specifically to a B cell subpopulation in bone marrow, we nevertheless could purify stem cells by using CB for the detection and elimination of lineage positive cells. Isolated stem cells from mouse fetal liver (Lin-CD34(+)Sca-1(+)c-Kit(high)) and adult bone marrow (Lin-CD34(-/low)Sca-1(+)c-Kit(+)) were transplanted into lethally irradiated mice, and the sorted stem cells had the ability to efficiently repopulate all mature hematopoietic lineages in recipient mice.     

Alteration of cell cycle kinetics by reducing agents in human peripheral blood lymphocytes from adult and senescent donors

For improving cell proliferation reducing agents are routinely used as medium supplements in murine cell cultures, however, they are rarely used for human peripheral blood lymphocytes (PBLs). Data on changes in cell kinetics induced by reducing agents are not available. Here cell kinetic alterations induced by reducing agents in human lymphocytes are revealed by applying flow cytometric BrdUrd/Hoechst cell cycle analysis and by using the exit kinetic model of Smith and Martin. Applying alpha-thioglycerol (a-TG) as a model compound it was shown that the major cell kinetic effect is a shortening of the mean duration of the G0/G1 phase. The minimum G0/G1 phase duration and the percentage of the non-cycling G0/G1 cell fraction decrease only slightly. Moreover, a lower number of PBL's are arrested in the G2/M phase of the 1st cell cycle. The durations of the S and G2/M phase in the 1st and G1 phase in the 2nd cycle are not affected. These cell kinetic effects are identical for lymphocytes from both adult and senescent donors. The supplementation of the cell cultures with recombinant IL-2 did not induce similar cell kinetic alterations compared with a-TG. This indicates that the variation of the cell cycle progression factor IL-2 is not solely responsible for improvement of the cell activation process in the G0/G1 phase.     

Incorporation of ethidium bromide in the Drosophila salivary gland approached by microspectrofluorometry: evidence for the presence of both free and bound dye in the nuclei of cells in viable conditions

The incorporation of 10^–6 M ethidium bromide (EB) was studied in viable Drosophila melanogaster salivary glands with a spatial resolution reaching a few µm³, using a confocal laser microspectrofluorometer designed for spectral analysis. Spectra were recorded with the 514 nm Argon laser line during excitation times of 1 second (20 µW on the preparation) at 5 min intervals for 30 or 60 min, either at points in determined cell sites or serially throughout the cells. The fluorescence intensity time-course indicated that the EB intake was not an all-or-none process, but rather a graded, sensitive indicator of the functional state of the cell. On the micrometer scale, the cytoplasm behaved as an homogeneous substrate with the fluorescence intensity depending on EB intake and intracellular diffusion. In the nucleus, however, localized enhancement of the emission intensity was observed. Spectral analysis allowed us to characterize the interactions. The mean values of λ _max in the cytoplasm (600 nm), in the nucleus (601 nm) and outside the glands (602 nm) were less than for free EB in aqueous solution (630 nm); values of full width at half maximum were between 92 and 96 nm, which is much lower than the 120 nm observed for free EB. The recorded spectra were analyzed using a linear combination of two spectral models, namely free and DNA intercalated EB. In the nucleus, the free EB model spectra was found to represent up to 10% of the recorded spectra whereas it was near zero in the cytoplasm. The present data suggest that the intranuclear concentration of free EB (allowing for its lower fluorescence quantum yield) might be at least equal to that of the bound EB.     

He—Ne激光照射对成纤维细胞内[Ca^2＋]i浓度影响的流式细胞计测定

目的：Ｈｅ－Ｎｅ激光照射治疗的机理不明,激光照射引起细胞内Ｃａ＾２＋水平变化,为治疗机理提供理论依据。方法：Ｈｅ－Ｎｅ激光照射引起鼠成纤维细胞Ｌ９２９内［Ｃａ＾２＋］ｉ的变化,用ＨＯ３４２对细胞ＤＮＡ活性染色,Ｆｌｕｏ－３ＡＭ对细胞内Ｃａ＾２＋染色,利用ＦＣＭ同时定量分析细胞ＤＮＡ和细胞内Ｃａ＾２＋的变化。结果：激光照射１５ｍｉｎ（光剂量１１．８１Ｊ／ｃｍ＾２后,ＦＣＭ分析可见ＤＮＡ分布直方图右移     

Characteristics of a novel deep red/infrared fluorescent cell-permeant DNA probe, DRAQ5, in intact human cells analyzed by flow cytometry, confocal and multiphoton microscopy

BACKGROUND: The multiparameter fluorometric analysis of intact and fixed cells often requires the use of a nuclear DNA discrimination signal with spectral separation from visible range fluorochromes. We have developed a novel deep red fluorescing bisalkylaminoanthraquinone, DRAQ5 (Ex(lambdamax) 646 nm; Em(lambdamax) 681 nm; Em(lambdarange) 665->800 nm), with high affinity for DNA and a high capacity to enter living cells. We describe here the spectral characteristics and applications of this synthetic compound, particularly in relation to cytometric analysis of the cell cycle. METHODS: Cultured human tumor cells were examined for the ability to nuclear locate DRAQ5 using single and multiphoton laser scanning microscopy (LSM) and multiparameter flow cytometry. RESULTS: Multiparameter flow cytometry shows that the dye can rapidly report the cellular DNA content of live and fixed cells at a resolution level adequate for cell cycle analysis and the cycle-specific expression of cellular proteins (e.g., cyclin B1). The preferential excitation of DRAQ5 by laser red lines (633/647 nm) was found to offer a means of fluorescence signal discrimination by selective excitation, with greatly reduced emission overlap with UV-excitable and visible range fluophors as compared with propidium iodide. LSM reveals nuclear architecture and clearly defines chromosomal elements in live cells. DRAQ5 was found to permit multiphoton imaging of nuclei using a 1,047-nm emitting mode-locked YLF laser. The unusual spectral properties of DRAQ5 also permit live cell DNA analysis using conventional 488 nm excitation and the single-photon imaging of nuclear fluorescence using laser excitation between 488 nm and low infrared (IR; 780 nm) wavelengths. Single and multiphoton microscopy studies revealed the ability of DRAQ5 to report three-dimensional nuclear structure and location in live cells expressing endoplasmic reticulum targeted-GFP, MitoTracker-stained mitochondria, or a vital cell probe for free zinc (Zinquin). CONCLUSION: The fluorescence excitation and emission characteristics of DRAQ5 in living and fixed cells permit the incorporation of the measurement of cellular DNA content into a variety of multiparameter cytometric analyses.     

High resolution analysis of cell cycle-correlated vimentin expression in asynchronously grown,TPA-treated MPC-11 cells by the novel flow cytometric multiparameter BrdU-hoechst/PI and immunolabeling technique

High resolution, multiparameter analysis using the flow cytometric BrdU/Hoechst quenching technique has been applied to study cell cycle kinetics and vimentin expression in individual cells of asynchronously grown MPC-11 mouse plasmacytoma cell cultures treated with 12-O-tetradecanoylphorbol-13-acetate (TPA) to induce in vitro differentiation. BrdU treatment up to 16 h in the absence or presence of TPA did not affect either cell cycle progression or the kinetics or quantity of vimentin expression. TPA-treated cells became arrested in G1 phase of the second cell cycle; however, this G1 phase arrest was transient only. In addition, G1 phase cells located prior to a putative transition point at the beginning of TPA treatment were completely blocked in cell cycle progression. There is also evidence that cells located in G1 or G2/M phase at the beginning of TPA treatment finally expressed low levels of vimentin. On the contrary, cells located in S phase at TPA exposure showed high vimentin levels after treatment. The results presented here show that, with the flow cytometric BrdU/Hoechst quenching technique, one can correlate time-dependent protein expression at the single cell level in asynchronously grown cultures not only with the actual cell cycle state, but also with the history of cell replication. © 1994 Wiley-Liss, Inc.     

Analysis of CD36 expression on human monocytic cells and atherosclerotic tissue sections with quantum dots: investigation by flow cytometry and spectral imaging microscopy

OBJECTIVE: To demonstrate CD36 expression with quantum dots (QDs) 525 and/or 605 on human monocytic U937 cells and atherosclerotic tissue sections by means of flow cytometry (FCM) and/or confocal laser scanning microscopy (CLSM). STUDY DESIGN: U937 cells and tissue sections were analyzed by means of FCM and/or CLSM. FCM was performed, using different ultraviolet (UV) and visible (488/532 nm) excitation modes. In the visible mode, fluorescence intensities of QDs, phycoerythrin (PE) and fluorescein isothiocyanate (FITC) were compared. Three-dimensional (3-D) sequences of images were obtained by spectral analysis in a CLSM and analyzed by the factor analysis of medical image sequences (FAMIS) algorithm, providing factor curves and images. Factor images are the result of the FAMIS image processing method, which differentiates emission spectra from 3D sequences of images. In CLSM analysis, preparations are screened in a UV excitation mode to optimize the possibilities of QDs and have the benefit of 4',6-diamino-2-phenylindole or Hoechst 33342 counterstaining of nuclei. RESULTS: FCM and CLSM revealed CD36 expression by means of QDs 525 and/or 605. Fluorescence intensity of PE and of FITC was higher than that of QDs 525 and of 605. As factor curves and images show the red emission of QDs 605 only, subsequent reliable identification and localization of CD36 was obtained. CONCLUSION: QDs 525 and 605 are useful to analyze antigenic expression. Following FCM, which is well adapted to detect fluorescence emission of QDs in the UV or visible excitation mode, CLSM and subsequent spectral analysis assess more specific characterization of QD fluorescent emissions.     

A rapid analytical technique for flow cytometric analysis of cell viability using calcofluor white M2R

Analysis of dead versus live cells is shown to be possible using Calcoflour White M2R (CFW), a fluorescent brightener. Comparison of CFW with both propidium iodide (PI) and fluorescein diacetate (FDA) was performed on a FACS 440 dual laser flow cytometer on several populations of cultured rat and mouse cell lines, peripheral leukocytes, splenocytes, diatoms, and plant protoplasts. As a measure of cell viability, staining results with CFW were strongly associated with PI (correlation coefficient of 0.9886) and FDA (inverse correlation coefficient of 0.9647). With plant and algal cells, controls are necessary as CFW does stain live cells to some extent. CFW (excitation: UV, emission max: 435 nm) can be used in conjunction with two-color immunofluorescence analysis using fluorochromes excited at 488 nm with no interference.