A mercury arc lamp-based multi-color confocal real time imaging system for cellular structure and function

Multi-point scanning confocal microscopy using a Nipkow disk enables the acquisition of fluorescent images with high spatial and temporal resolutions. Like other single-point scanning confocal systems that use Galvano meter mirrors, a commercially available Nipkow spinning disk confocal unit, Yokogawa CSU10, requires lasers as the excitation light source. The choice of fluorescent dyes is strongly restricted, however, because only a limited number of laser lines can be introduced into a single confocal system. To overcome this problem, we developed an illumination system in which light from a mercury arc lamp is scrambled to make homogeneous light by passing it through a multi-mode optical fiber. This illumination system provides incoherent light with continuous wavelengths, enabling the observation of a wide range of fluorophores. Using this optical system, we demonstrate both the high-speed imaging (up to 100 Hz) of intracellular Ca(2+) propagation, and the multi-color imaging of Ca(2+) and PKC-gamma dynamics in living cells.     

A comparison of mercury arc lamp and laser illumination for flow cytometers.

Optical differences between a mercury arc lamp and a laser-illuminated flow cytometer are compared. The distributions of spectral intensities of the two light sources are shown in relation to the excitation characteristics of the fluorescent dyes acriflavine, chromomycin A3, mithramycin, ethidium bromide, Hoechst 33258, and 4,6-diamidino-2-phenylindole (DAPI). Fluorescence intensities of microspheres and Hoechst 33258-stained mouse sperm are compared in the two cytometers. The optical efficiencies are similar and depend on the match of the excitation characteristics of the stain with the emission spectra of the light source.     

High resolution dual laser flow cytometry.

Flow cytometers based on optical sensing utilize external light sources and fluorescent dyes to measure one or more specific components or properties of individual cells or subcellular particles in liquid suspension. To provide for independent excitation of two dyes used in double staining experiments we have constructed a high resolution flow cytometer that uses two laser beams to provide two wavelengths of excitation. These beams are separated spatially so that cells flow through them sequentially, with a time separation of about 20 musec. Since the dyes are excited sequentially their emission occurs at different times and their emission spectra may overlap without causing any difficulty in analysis. We have developed new light collection optics that permit up to four measurements to be made on each cell. This approach greatly increases the number of dye combinations that can be used in flow cytometry, thus removing a significant limitation of single illumination instruments.     

Fluorescent rhodol derivatives: versatile, photostable labels and tracers.

A series of chemically reactive, fluorescent rhodol derivatives was prepared and evaluated. Reactive functional groups included activated esters, amines, haloacetamides, fixable hydrazide derivatives, acrylamides, and photoaffinity reagents. Depending on the choice of substituents, absorption maxima of the dyes varied from 490 to 550 nm with extinction coefficients that were generally greater than 50,000 M-1 cm-1 in aqueous solution and emission maxima from 520 to 580 nm. Most of the compounds investigated exhibited fluorescence lifetimes between 3 and 4 ns. Individual derivatives were suitable for excitation with the 488 and 514-nm lines of the argon ion laser and the 546-nm line of the mercury arc lamp and were compatible for use with standard fluorescein and rhodamine filter sets. The rhodol dyes were more photostable and less sensitive to pH changes in the physiological range than fluorescein derivatives. Some examples show absorption maxima at or near 514 nm, an excitation wavelength that is useful for multicolor fluorescence microscopy, flow cytometry, and DNA sequencing. Derivatives were also prepared that exhibit absorption and emission maxima similar to those of tetramethylrhodamine (TMR) analogs but with higher quantum yields in aqueous solution. A number of the dyes had higher solubilities in aqueous systems and were less quenched on conjugation to proteins than TMR derivatives. Appropriate substitution results in a wider range of solubilities in hydrophilic or lipophilic solvents than is easily accomplished with fluorescein or TMR derivatives. Conjugates of a number of the rhodol fluorophores were generally more photostable and less pH sensitive than fluorescein conjugates and more fluorescent than TMR conjugates.     

A new multiparameter flow cytometer: optical and electrical cell analysis in combination with video microscopy in flow

BACKGROUND: Flow cytometers, which are commercially available, do not necessarily meet all demands of actual biomedical research. This is the case for the investigation of mechanisms involved in cell volume regulation, which requires electrical volume measurement and ratiometric multichannel fluorescence analysis for the simultaneous assessment of different physiologic parameters (intracellular pH and the intracellular concentration of calcium ions, etc). METHODS AND RESULTS: We describe the construction of a new nonsorting flow cytometer designed for the simultaneous acquisition of seven parameters including fluorescence signals, forward and perpendicular light scatter, cell volume according to the electrical Coulter principle, and flow cytometric imaging. The instrument is equipped with three different light sources. A tunable argon-ion laser generates efficient excitation of the most standard fluorescent probes in the visible spectral range, and an arc lamp provides the means for ultraviolet excitation at low cost. Because of the spatial filtering by the excitation and detection optics, two independent sets of dual fluorescence measurements can be performed, a prerequisite for flexible ratiometric fluorescence analysis. A flow video microscope integrated into the optical system optionally generates either brightfield or phase images of selected flowing particles. Only particles whose individual datasets meet predefined gating conditions are imaged in real time. To avoid smear effects, the motion of the object to be imaged (speed approximately 8 m/s) is frozen on the target of a CCD camera by flash illumination. For this purpose, a high radiance gas discharge lamp with 25-mJ electric pulse energy provides an illumination time of 18 ns (full width half maximum). Test results obtained from latex spheres and cells are shown. CONCLUSIONS: Test results indicate that our instrument can perform Coulter measurements in combination with flexible optical analysis. Moreover, integration of an adapted video microscope into a flow cytometer is an approach to overcome the gap between flow and image cytometry.     

Alexa dyes, a series of new fluorescent dyes that yield exceptionally bright, photostable conjugates.

Alexa 350, Alexa 430, Alexa 488, Alexa 532, Alexa 546, Alexa 568, and Alexa 594 dyes are a new series of fluorescent dyes with emission/excitation spectra similar to those of AMCA, Lucifer Yellow, fluorescein, rhodamine 6G, tetramethylrhodamine or Cy3, lissamine rhodamine B, and Texas Red, respectively (the numbers in the Alexa names indicate the approximate excitation wavelength maximum in nm). All Alexa dyes and their conjugates are more fluorescent and more photostable than their commonly used spectral analogues listed above. In addition, Alexa dyes are insensitive to pH in the 4-10 range. We evaluated Alexa dyes compared with conventional dyes in applications using various conjugates, including those of goat anti-mouse IgG (GAM), streptavidin, wheat germ agglutinin (WGA), and concanavalin A (ConA). Conjugates of Alexa 546 are at least twofold more fluorescent than Cy3 conjugates. Proteins labeled with the Alexa 568 or Alexa 594 dyes are several-fold brighter than the same proteins labeled with lissamine rhodamine B or Texas Red dyes, respectively. Alexa dye derivatives of phalloidin stain F-actin with high specificity. Hydrazide forms of the Alexa dyes are very bright, formaldehyde-fixable polar tracers. Conjugates of the Alexa 430 (ex 430 nm/em 520 nm) and Alexa 532 (ex 530 nm/em 548 nm) fluorochromes are spectrally unique fluorescent probes, with relatively high quantum yields in their excitation and emission wavelength ranges.     

Performance validation of an improved Xenon-arc lamp-based CCD camera system for multispectral imaging in proteomics

Advances in gel-based nonradioactive protein expression and PTM detection using fluorophores has served as the impetus for developing analytical instrumentation with improved imaging capabilities. We describe a CCD camera-based imaging instrument, equipped with both a high-pressure Xenon arc lamp and a UV transilluminator, which provides broad-band wavelength coverage (380-700 nm and UV). With six-position filter wheels, both excitation and emission wavelengths may be selected, providing optimal measurement and quantitation of virtually any dye and allowing excellent spectral resolution among different fluorophores. While spatial resolution of conventional fixed CCD camera imaging systems is typically inferior to laser scanners, this problem is circumvented with the new instrument by mechanically scanning the CCD camera over the sample and collecting multiple images that are subsequently automatically reconstructed into a complete high-resolution image. By acquiring images in succession, as many as four different fluorophores may be evaluated from a gel. The imaging platform is suitable for analysis of the wide range of dyes and tags commonly encountered in proteomics investigations. The instrument is unique in its capabilities of scanning large areas at high resolution and providing accurate selectable illumination over the UV/visible spectral range, thus maximizing the efficiency of dye multiplexing protocols.     

New near-infrared optical probes of cardiac electrical activity

Styryl voltage-sensitive dyes (e.g., di-4-ANEPPS) have been widely and successfully used as probes for mapping membrane potential changes in cardiac cells and tissues. However, their utility has been somewhat limited because their excitation wavelengths have been restricted to the 450- to 550-nm range. Longer excitation/emission wavelength probes can minimize interference from endogenous chromophores and, because of decreased light scattering and lower absorption by endogenous chromophores, improve recording from deeper tissue layers. In this article, we report efforts to develop new potentiometric styryl dyes that have excitation wavelengths ranging above 700 nm and emission spectra extending to 900 nm. Three dyes for cardiac optical mapping were investigated in depth from several hundred dyes containing 47 variants of the styryl chromophores. Absorbance and emission spectra in ethanol and multilamellar vesicles, as well as voltage-dependent spectral changes in a model lipid bilayer, have been recorded for these dyes. Optical action potentials were recorded in typical cardiac tissues (rat, guinea pig, pig) and compared with those of di-4-ANEPPS. The voltage sensitivities of the fluorescence of these new potentiometric indicators are as good as those of the widely used ANEP series of probes. In addition, because of molecular engineering of the chromophore, the new dyes provide a wide range of dye loading and washout time constants. These dyes will enable a series of new experiments requiring the optical probing of thick and/or blood-perfused cardiac tissues.     

Light scattering measurement in an arc lamp-based flow cytometer

The epi-illumination optics employed in most arc lamp-based flow cytometers may be modified so as to produce a dark-field configuration which facilitates highly sensitive detection of both forward and large angle light scattering in an instrument with a "jet on open surface" flow chamber. Forward scattering is detected at angles upwards from about 2 degrees, while large angle scattering includes angles above 18 degrees. Theoretical considerations suggest that large angle scattering measured around 20 degrees may be as efficient as that measured at 90 degrees for the purpose of distinguishing cells on the basis of intracellular structure. This was supported by the finding that dual parameter light scattering histograms of leukocyte suspensions obtained with the arc lamp-based instrument were closely similar to such histograms recorded with a laser-based instrument with the large angle detector at 90 degrees. Different species of bacteria could be distinguished by means of the dual parameter light scattering device, as could different species of sea algae. The sensitivity of the device is sufficient to measure 0.2 microns polystyrene particles in both forward and large angle scattering.     

A single molecule investigation of the photostability of quantum dots

Quantum dots (QDs) are very attractive probes for multi-color fluorescence imaging in biological applications because of their immense brightness and reported extended photostability. We report here however that single QDs, suitable for biological applications, that are subject to continuous blue excitation from a conventional 100 W mercury arc lamp will undergo a continuous blue-switching of the emission wavelength eventually reaching a permanent dark, photobleached state. We further show that β-mercaptoethanol has a dual stabilizing effect on the fluorescence emission of QDs: 1) by increasing the frequency of time that a QD is in its fluorescent state, and 2) by decreasing the photobleaching rate. The observed QD color spectral switching is especially detrimental for multi-color single molecule applications, as we regularly observe spectral blue-shifts of 50 nm, or more even after only ten seconds of illumination. However, of significant importance for biological applications, we find that even small, biologically compatible, concentrations (25 μM) of β-mercaptoethanol has a significant stabilizing effect on the emission color of QDs, but that greater amounts are required to completely abolish the spectral blue shifting or to minimize the emission intermittency of QDs.     

A fluorescence detection platform using spatial electroluminescent excitation for measuring botulinum neurotoxin A activity

Current biodetection illumination technologies (laser, LED, tungsten lamp, etc.) are based on spot illumination with additional optics required when spatial excitation is required. Herein we describe a new approach of spatial illumination based on electroluminescence (EL) semiconductor strips available in several wavelengths, greatly simplifying the biosensor design by eliminating the need for additional optics. This work combines EL excitation with charge-coupled device (CCD) based detection (EL-CCD detector) of fluorescence for developing a simple portable detector for botulinum neurotoxin A (BoTN-A) activity analysis. A F?rster Resonance Energy Transfer (FRET) activity assay for BoTN-A was used to both characterize and optimize the EL-CCD detector. The system consists of two modules: (1) the detection module which houses the CCD camera and emission filters, and (2) the excitation and sample module, containing the EL strip, the excitation filter and the 9-well sample chip. The FRET activity assay used in this study utilized a FITC/DABCYL-SNAP-25 peptide substrate in which cleavage of the substrate by BoTN-A, or its light chain derivative (LcA), produced an increase in fluorescence emission. EL-CCD detector measured limits of detection (LODs) were similar to those measured using a standard fluorescent plate reader with valves between 0.625 and 1.25 nM (31-62 ng/ml) for LcA and 0.313 nM (45 ng/ml) for the full toxin, BoTN-A. As far as the authors are aware this is the first demonstration of phosphor-based EL strips being used for the spatial illumination/excitation of a surface, coupled with CCD for point of care detection.     

Luminescent quantum dots for multiplexed biological detection and imaging

Recent advances in nanomaterials have produced a new class of fluorescent labels by conjugating semiconductor quantum dots with biorecognition molecules. These nanometer-sized conjugates are water-soluble and biocompatible, and provide important advantages over organic dyes and lanthanide probes. In particular, the emission wavelength of quantum-dot nanocrystals can be continuously tuned by changing the particle size, and a single light source can be used for simultaneous excitation of all different-sized dots. High-quality dots are also highly stable against photobleaching and have narrow, symmetric emission spectra. These novel optical properties render quantum dots ideal fluorophores for ultrasensitive, multicolor, and multiplexing applications in molecular biotechnology and bioengineering.     

A microscope-based flow cytophotometer

By means of a new flow chamber, a standard fluorescence microscope with Epi illumination and 100 W mercury arc excitation has been turned into a flow cytophotometer combining high resolution and sensitivity with simplicity of operation. In the flow chamber, cells are passed in a narrow stream through the microscope focus carried by a laminar flow of water running on the open surface of a cover glass which is coupled to the oil immersion microscope objective. Two spectral components of the fluorescence, for example, resulting from specific staining of two different cellular constituents with different dyes, can be measured simultaneously in separate channels so as to produce three-dimensional histograms. The scattered light of the cells is detected in dark field by a second microscope situated opposite the primary objective. Scattered light detection is integrating with regard to scattering angle from 0 degree to 90 degrees. Hence, diffraction pattern effects are eliminated and the light scatter signal is approximately proportional to cell dry weight. The Epi illumination, which implies that excitation and fluorescence collection are parfocal, greatly simplifies instrument adjustment, which is further facilitated by the fact that the cell stream can be viewed at high magnification. Cell measuring time is about 3 microseconds which implies a measuring rate of 3 x 10(3) cells/s at 1% coincidence rate. Sensitivity is sufficient for measuring the DNA content of bacteria (that is, approximately 5 x 10(-15) g/cell) with a coefficient of variance (CV) of about 6%. CV less than 1% is achieved for DNA histograms of mammalian cells. A 5 W argon laser as excitation source facilitates slit scan analysis and increases the sensitivity and measuring rate by one to two orders of magnitude.     

Dual-laser flow cytometry of single mammalian cells.

An improved dual-laser flow cytometric system for quantitative analysis and sorting of mammalian cells has been developed using a low-power argon and high-power krypton laser as illumination sources, thus permitting the excitation of fluorescent dyes having absorption regions ranging from the ultraviolet to infrared. Cells stained in liquid suspension with fluorescent dyes enter a flow chamber where they intersect two spatially separated laser beams. Separate pairs of quartz beam-shaping optics focus each beam onto the cell stream. Electro-optical sensors measure fluorescence and light scatter signals from cells that are processed electronically and displayed as frequency distribution histograms. Cells also can be electronically separated and microscopically identified. The ease and versatility of operation designed into this system represent a marked technological improvement for dual-laser excited flow systems. Details of this instrument are described along with illustrative examples of cells stained with mithramycin and rhodamine and analyzed for DNA content, total protein, and nuclear and cytoplasmic diameter.     

Sensitization enhancement of europium in ZnSe/ZnS core/shell quantum dots induced by efficient energy transfer

Eu‐doped ZnSe:/ZnS quantum dots (formed as ZnSe:Eu/ZnS QDs) were successfully synthesized by a two‐step wet chemical method: nucleation doping and epitaxial shell growing. The sensitization characteristics of Eu‐doped ZnSe and ZnSe/ZnS core/shell QD are studied in detail using photoluminescence (PL), PL excitation spectra (PLE) and time‐resolved PL spectroscopy. The emission intensity of Eu ions is enhanced and that of ZnSe QDs is decreased, implying that energy was transferred from the excited ZnSe host materials (the donor) to the doped Eu ions (the acceptor). PLE reveals that the ZnSe QDs act as an antenna for the sensitization of Eu ions through an energy transfer process. The dynamics of ZnSe:Eu/ZnS core/shell quantum dots with different shell thicknesses and doping concentrations are studied via PL spectra and fluorescence lifetime spectra. The maximum phosphorescence efficiency is obtained when the doping concentration of Eu is approximately 6% and the sample showed strong white light under ultraviolet lamp illumination. By surface modification with ZnS shell layer, the intensity of Eu‐related PL emission is increased approximately three times compared with that of pure ZnSe:Eu QDs. The emission intensity and wavelength of ZnSe:Eu/ZnS core/shell quantum dots can be modulated by different shell thickness and doping concentration. The results provide a valuable insight into the doping control for practical applications in laser, light‐emitting diodes and in the field of biotechnology. Copyright © 2014 John Wiley & Sons, Ltd.     

Flow cytometer based on triggered supercontinuum laser illumination

Multiple wavelength operation in a flow cytometer is an exciting way for cell analysis based on both fluorescence and optical scattering processing. For example, this multiparametric technique is currently used to differentiate blood cells subpopulations. The choice of excitation wavelengths matching fluorochrome spectra (it is currently the opposite) and the use of a broader range of fluorochromes can be made by taking advantage of a filtered supercontinuum white light source. In this study, we first wished to validate the use of a specific triggered supercontinuum laser in a flow cytometer based on white light scattering and electric sizing on human blood cells. Subsequently, to show the various advantages of this attractive system, using scattering effect, electrical detections, and fluorescence analysis, we realized cells sorting based on DNA/RNA stained by thiazole orange. Discrimination of white blood cells is efficiently demonstrated by using a triggered supercontinuum-based flow cytometer operating in a "one cell-one shot" configuration. The discriminated leukocyte populations are monocytes, lymphocytes, granulocytes, immature granulocytes, and cells having a high RNA content (monoblasts, lymphoblasts, and plasma cells). To the best of our knowledge, these results constitute the first practical demonstration of flow cytometry based on triggered supercontinuum illumination. This study is the starting point of a series of new experiments fully exploiting the spectral features of such a laser source. For example, the large flexibility in the choice of the excitation wavelength allows to use a larger number of fluorochromes and to excite them more efficiently. Moreover, this work opens up new research directions in the biophotonics field, such as the combination of coherent Raman spectroscopy and flow cytometry techniques.     

Effect of chromatic errors in microscopy on the visualization of multi-color fluorescence in situ hybridization

The relevant microscopical conditions for the optimal visualization of ratio-color FISH stained cells were investigated. Special attention was given to the influence of the type of illumination, (semi)-critical vs. K?hler type illumination, in combination with the use of multi-band excitation and emission filters, on the registration of the colors of ratio labelled probes. Due to chromatic errors, many collecting lenses were found to cause a wavelength dependent excitation pattern with critical illumination. This resulted in a change of the observed color of microscopic objects when stained with a mixture of two dyes and excited with a dual band pass filter. A quantitative study of this effect for semi-critical illumination of FISH ratio-labelled chromosomes revealed a difference of 20% between highest and lowest ratio values depending on the position of the object in the microscopic field vs. only 2.5% for K?hler type of illumination. The impact of these errors on the identification of ratio-labelled probes and on the sensitivity of comparative genomic hybridization (CGH) to detect gene amplifications or losses is discussed. Standard preparations consisting of solutions of defined mixtures of fluorescent dyes or objects stained with defined ratios of fluorophores, are proposed to correct for the errors observed.     

Violet laser diodes as light sources for cytometry

BACKGROUND: Violet laser diodes have recently become commercially available. These devices emit 5-25 mW in the range of 395-415 nm, and are available in systems that incorporate the diodes with collimating optics and regulated power supplies in housing incorporating thermoelectric coolers, which are necessary to maintain stable output. Such systems now cost several thousand dollars, but are expected to drop substantially in price. Materials and Methods A 4-mW, 397-nm violet diode system was used in a laboratory-built flow cytometer to excite fluorescence of DAPI and Hoechst dyes in permeabilized and intact cells. Forward and orthogonal light scattering were also measured. RESULTS: DNA content histograms with good precision (G(0)/G(1) coefficient of variation 1.7%) were obtained with DAPI staining; precision was lower using Hoechst 33342. Hoechst 34580, with an excitation maximum nearer 400 nm, yielded the highest fluorescence intensity, but appeared to decompose after a short time in solution. Scatter signals exhibited relatively broad distributions. CONCLUSIONS: Violet laser diodes are relatively inexpensive, compact, efficient, and quiet light sources for DNA fluorescence measurement using DAPI and Hoechst dyes; they can also excite several other fluorescent probes.     

The utility of antisera to canine growth hormone and canine prolactin for immunocytochemical staining of the dog pituitary gland

Summary Fluorescent microspectrophotometry using dichroic mirror vertical epi-illumination of tissue sections stained with the PAS reaction (periodic acid and pararosaniline Schiff reagent) provides a measure of the relative concentration of 1:2 glycols within and between tissue sections. In PAS reacted sections of agarose gel, pararosaniline Schiff fluorescence increases linearly as the concentration of agarose increases (r=0.97, p<0.05). The concentration of glycogen within liver as measured by a phenol-based tissue assay is linearly correlated with pararosaniline Schiff fluorescence of formalin fixed liver sections (r=0.87, p<0.05). These relationships are unaffected by alcina blue or hematoxylin. Heretofore the amount of color reaction as measured by densitometry at the pararosaniline absorption peak was claimed to be an unreliable indicator of the amount of reactive glycol present in tissue. Our observations indicate that when the concentration of Schiff reagent exceeds an empiric limit relative to available polysaccharides, the Schiff reagent-tissue complex reflects light at the excitation wavelength instead of fluorescing the emission spectra. This can be circumvented by using dilute pararosaniline-Schiff reagent, shortening the staining period, and lowering the temperature of the staining medium.While routine PAS staining reactions are followed by washing in running water to develop the red color seen with broad spectrum illumination, water development is unnecessary for the dye-tissue complex to fluoresce. The fluorescent emission peak and the maximum excitation peak of both developed and undeveloped pararosaniline-Schiff-reagent-tissue complexes are 645–50 nm and 540–45 nm, respectively. These spectral characteristics are not changed by binding to oxidation products of different glycoproteins or polysaccharides. Intense exposure to room light, but not 100 repetitive short (0.13 s) exposures, causes partial photodecomposition.Quantitative assessment of cytofluorescence requires definition of the optical system used to measure emission. In the microspectrophotometer employed in this study, dichroic mirrors reflect light with variable efficiency depending on wavelength from the light source to the stage, and variably block light reflected or emitted from the specimen, serving as crude barrier filters. These dichroic mirror characteristics are influenced by the exact nature of the optical coating on the surface of each individual mirror. Since the optical coating of similar mirrors may vary, the properties of individual mirrors must be considered in the interpretation of spectral data and in determining the proper optical conditions for quantification of cytofluorescence.This investigation was supported by National Institutes of Health Research Service Award IF32 NS 517701 PTHA from the National Institute of Neurological and Communicative Disorders and Stroke and the National Cancer Institute Grant R01 CA 17341     

Three-photon induced fluorescence of the calcium probe Indo-1.

We report the calcium-dependent emission spectral properties of the calcium probe Indo-1 for three-photon excitation. We found that Indo-1 could be readily excited with the femtosecond pulses from a mode-locked Ti:sapphire laser at 885 nm. This wavelength is too long for two-photon excitation, which is expected to occur for wavelengths no longer than twice the longest single-photon absorption wavelength of 400 nm. For excitation at 885 nm the emission intensity was found to depend on the cube of the laser power, as expected for simultaneous interaction with three photons. At wavelengths below 840 nm the emission intensity depends on the square of the laser power, indicating two-photon excitation at shorter wavelengths. The intensity decays of Indo-1 were found to be dependent on Ca2+ and essentially identical for one- and three-photon excitation. The emission anisotropy of Indo-1 was found to be considerably higher for three-photon excitation than for one-photon excitation, consistent with cos6 theta photoselection, as compared with cos2 theta photoselection for one-photon excitation. The high values of the anisotropy are in agreement with those expected for a three-photon process. Calcium-dependent emission spectra were observed for Indo-1 with three-photon excitation, demonstrating that three-photon excitation of Indo-1 can be used for calcium imaging by emission intensity ratio measurements. The calcium-dependent emission spectra indicate a higher three-photon cross-section for the calcium-free form of Indo-1 than for the calcium-bound form. The possible advantages of three-photon excitation include the availability of the appropriate wavelengths with solid-state lasers, enhanced spatial resolution due to a reduced size of the excited volume, absence of light quenching, and possibly high selectivity of the three-photon excitation process.