Flow cytometers using optical waveguides in place of lenses for specimen illumination and light collection

Optical waveguides represent alternatives to lenses for delivery of light to, and collection of light from, small regions of space such as the observation point(s) of a flow cytometer. The flow chamber and directly associated illumination and collection optics of a flow cytometer can be built using fiber optic waveguides in fixed positions or as an integrated optical assembly incorporating deposited or implanted waveguides, providing illumination and collection geometries and efficiencies comparable to conventional designs, with the advantage that the optical waveguide design, once assembled, never again requires alignment of the optics. A prototype apparatus in which fiber optics were used to illuminate and collect light from a point inside a thin-walled, round quartz capillary was observed to measure fluorescence of polystyrene spheres with precision close to that obtained from a conventional flow cytometer using the same laser source. The design of the fiber optic system is readily adaptable to construction of multiple illumination beam instruments; other optical waveguide flow cytometer designs that dispense with the capillary share this advantage and can also provide orifices for electronic volume sensing and for jetting prior to droplet sorting.     

Gravitational and magnetic activation methods applied to cultured cells (LK 35.2)

Monoclonal antibody 10.2-16 is directed toward the mouse class II major histocompatibility complex gene product 1-Ak expressed on the cell line LK35.2. Instead of activating cells by fluorophor we used (acrylamide-coated) heavy and magnetic microspheres of 0.6 micron in radius. These microspheres are chemically coupled (carbodiimide method) with the antibody toward the surface antigen. The cells are observed through a microscope with horizontal alignment, as they sediment in a (temperature controlled) tube with square cross-section. Stokes Law allows the determination of the density of cells (first alone) using viscosity and density of Dulbecco's modified Eagle's Medium together with the observed mean sedimentation velocity (66 microns/min) and a mean diameter of 10 microns. We found a density of 1.0558 +/- 0.0028 g/cm3 at 10 degrees C. Independently, thinly coated, heavy (and magnetizable) microspheres with the cited antibody are attached to cells and observed likewise. The increased sedimentation velocity permits us to show that the cells were fully covered with microspheres (290 per cell). A magnetic field gradient opposing gravity moved these cells against gravity with two different mean velocities, 340 microns/min and 850 microns/min. The higher velocity resulted in 290 particles per cell, the lower one in 130 particles per cell. The limits for the expansion of this method to smaller particle sizes (down to 10 nm) are evaluated.     

Hydrodynamic deposition: a novel method of cell immobilization.

A novel method of cell immobilization is described. The cell support consists of ceramic microspheres of approximately 50-75 microns diameter. The spheres are hollow, having a wall thickness of 10-15 microns and one entrance (ca. 20 microns diameter). The walls are porous with a mean pore size of approximately 90 nm. When a cell suspension (of S. cerevisiae) is passed through a column of such particles, cells are immobilized. Conditions are devised such that the overwhelming majority of cells are held in the central cavity of the support and not between the particles. Provided turbulence is avoided, the distribution of cells along the column length in the steady state is rather homogeneous. The facts that (a) essentially all particles, regardless of orientation, entrap cells, and (b) nonporous particles also entrap cells with high efficiency, indicate that filtration effects are irrelevant and that heretofore unrecognized hydrodynamic forces are alone responsible for the cell immobilization. Cells can be immobilized to high biomass densities, while the hydrodynamic properties of columns containing such immobilized cells are excellent. We describe an on-line electronic method for the real-time measurement of immobilized cellular biomass. Cell growth (so recorded) and metabolism continue to occur in such particles at high rates. Using the glycolytic production of ethanol by S. cerevisiae as a model reaction, volumetric productivities as great as any published are obtained. Thus the "lobster-pot effect" or "hydrodynamic deposition" represents a novel, promising, and generally applicable method of cell immobilization.     

Some applications of microspheres in flow cytometry

Microspheres of latex ranging from 0.1 to 10 microns in diameter are nowadays commercially available. Labelled with different fluorochromes, they are good standards to check the optical path and to calibrate flow cytometers. The kits available contain microspheres highly selected with a precise size and a narrow distribution, so as to allow an easy alignment of instruments. Mixed with the cell preparations, microspheres may be used as an internal standard, in order to compare samples from day to day. Phagocytic activity has been investigated after incubation of cells with fluorescent microspheres. Covalently bound to ligands such as antibodies, microspheres become a powerful and specific reagent to label cell surface antigens. The positive signal is enhanced, allowing the detection of poorly represented epitopes. This paper reviews some examples of these applications published in the flow cytometry field.     

Visible spectroscopic technique for flowing erythrocytes in capillary

An optical spectroscopic system for determining the rate of oxygen release from flowing erythrocytes in microvessel is developed. The apparatus consists of following units attached to an inverted microscope. 1) A scanning spectrophotometer, equipped with a grating and a photon counter, was connected to an eyepiece of the microscope through a narrow light-guide, as to obtain the absorption spectrum (wave length range: 450-650 nm) of a focused spot (phi = 7 microns). 2) The velocity of erythrocyte flow was measured by dual-spots cross-correlation method, using two photomultipliers (connected to A/D converter and microcomputer) with two light-guides inserted into another eyepiece. 3) The diameter of vessel was estimated from digitized video-images, using a color image-processor. The ability of the apparatus was tested with (a) hemoglobin solution, (b) flowing erythrocyte suspension and (c) capillaries of rat mesentery. The rate of oxygen release through the vessel wall was calculated.     

Ultrasonic particle-concentration for sheathless focusing of particles for analysis in a flow cytometer.

BACKGROUND: The development of inexpensive small flow cytometers is recognized as an important goal for many applications ranging from medical uses in developing countries for disease diagnosis to use as an analytical platform in support of homeland defense. Although hydrodynamic focusing is highly effective at particle positioning, the use of sheath fluid increases assay cost and reduces instrument utility for field and autonomous remote operations. METHODS: This work presents the creation of a novel flow cell that uses ultrasonic acoustic energy to focus small particles to the center of a flowing stream for analysis by flow cytometry. Experiments using this flow cell are described wherein its efficacy is evaluated under flow cytometric conditions with fluorescent microspheres. RESULTS: Preliminary laboratory experiments demonstrate acoustic focusing of flowing 10-microm latex particles into a tight sample stream that is approximately 40 microm in diameter. Prototype flow cytometer measurements using an acoustic-focusing flow chamber demonstrated focusing of a microsphere sample to a central stream approximately 40 microm in diameter, yielding a definite fluorescence peak for the microspheres as compared with a broad distribution for unfocused microspheres. CONCLUSIONS: The flow cell developed here uses acoustic focusing, which inherently concentrates the sample particles to the center of the sample stream. This method could eliminate the need for sheath fluid, and will enable increased interrogation times for enhanced sensitivity, while maintaining high particle-analysis rates. The concentration effect will also enable the analysis of extremely dilute samples on the order of several particles per liter, at analysis rates of a few particles per second. Such features offer the possibility of a truly versatile low-cost portable flow cytometer for field applications.     

The use of magnetite-doped polymeric microspheres in calibrating cell tracking velocimetry

Continuous magnetic separation, in which there is no accumulation of mass in the system, is an inherently dynamic process, requiring advanced knowledge of the separable species for optimal instrument operation. By determining cell magnetization in a well-defined field, we may predict the cell trajectory behavior in the well-characterized field environments of our continuous separators. Magnetization is determined by tracking the migration of particles with a technique known as cell tracking velocimetry (CTV). The validation of CTV requires calibration against an external standard. Furthermore, such a standard, devoid of the variations and instabilities of biological systems, is needed to reference the method against day-to-day shifts or trends. To this end, a method of synthesizing monodisperse, magnetite-doped polymeric microspheres has been developed. Five sets of microspheres differing in their content of magnetite, and each of approximately 2.7 microm diameter, are investigated. An average gradient of 0.18 T/mm induces magnetic microsphere velocities ranging from 0.45 to 420 microns/s in the CTV device. The velocities enable calculation of the microsphere magnetization. Magnetometer measurements permit the determination of magnetization at a flux density comparable to that of the CTV magnet's analysis region, 1.57 T. A comparison of the results of the CTV and magnetometer measurements shows good agreement.     

Flow cytometric measurement of rates of particle uptake from dilute suspensions by a ciliated protozoan

Flow cytometry is used to measure rates of ingestion of particles from dilute monodisperse suspensions by the ciliate Tetrahymena pyriformis. The particles used are polystyrene microspheres containing a fluorescent dye. Measurements were made directly, that is, by determining the fluorescence intensities from microspheres ingested by cells in samples collected from the experimental feeding apparatus. The fact that fluorescence intensities from individual cells can be grouped into discrete classes based on the numbers of fluorescent particles associated with the cells makes it possible to calibrate the flow cytometer and convert fluorescence measurements into numbers of particles ingested by average cells. At low particle concentration or high ciliate concentration, ingestion data must be corrected for depletion of particles during the assay, and a method for doing this is described. Experiments at various ciliate concentrations show that ingestion rates are not affected by this concentration. The methods developed should allow measurements of rates of ingestion of particles from concentrated and polydisperse suspensions. For such measurements, nonfluorescent particles together with a fraction of fluorescent tracer particles would be used.     

Optical plankton analyser: a flow cytometer for plankton analysis, II: Specifications

An analysing flow cytometer, the optical plankton analyser (OPA), is presented. The instrument is designed for phytoplankton analysis, having a sensitivity comparable with commercially available flow cytometers, but a significantly extended particle size range. Particles of 500 microns in width and over 1,000 microns in length can be analysed. Sample flow rates of up to 55 microliters/s can be used. Also, the dynamic range of the instrument is significantly increased for particles larger than about 5 microns. The optics, hydraulics, and electronics of the instrument are described, including the best form for a low fluid shear cuvette. The new pulse quantification technique we call digital integration is presented. This technique is essential for the instrument to handle both short and very long particles with a large dynamic range. Test measurements demonstrating particle size range and dynamic range are presented. Dynamic ranges of 10,000 and 100,000 were typically observed, measuring field samples with Microcystis aeruginosa colonies, whereas one sample showed a dynamic range of 10(6). A simple method for interpretation of time of flight (TOF) data in terms of particle morphology is presented. The specifications of the instrument are given.     

Cell analysis system based on compact disk technology

BACKGROUND: A cell analysis system was developed to enumerate and differentiate magnetically aligned cells selected from whole blood. The cellular information extracted is similar to the readout of musical information from a compact disk (CD). Here we describe the optical design and data processing of the system. The performance of the system is demonstrated using fluorescent-labeled cells and beads. Materials and Methods System performance was demonstrated with 6-microm polystyrene beads labeled with magnetic nanoparticles and allophycocyanin (APC) and immunomagnetically aligned leukocytes, fluorescently labeled with Oxazine750 and CD4-APC, CD8-Cy5.5, and CD14-APC/Cy7 in whole blood. RESULTS: The sensitivity of the system was demonstrated using APC-labeled beads. With this system, beads containing 333 APC molecules could easily be resolved from the background. This level of sensitivity was not achievable with a commercial flow cytometer. A maximum of 20,000 immunomagnetically labeled cells could be aligned and analyzed in between 0.6 m of Ni lines, distributed over a surface area of 18 mm(2) and extracted from a blood volume that depended on the height of the chamber. The utility of the system was demonstrated by performing a three-color CD4-CD8-CD14 assay. CONCLUSIONS: We built a cell analysis system based on immunomagnetic cell selection and alignment and analysis of fluorescent signals employing CD-technology that is as good or better than current commercial analyzers. The cell analysis can be performed in whole blood or any other type of cell suspension without extensive sample preparation.     

Diffraction rings obtained from a suspension of skeletal myofibrils by laser light illumination. Study of internal structure of sarcomeres.

Diffraction rings corresponding to the first, second, and third order were obtained by laser light illumination from a suspension of rabbit glycerinated psoas myofibrils (diameter, 1-2 microns; average length of the straight region, 44 microns; average sarcomere length, 2.2-2.6 microns) of which the optical thickness was appropriately chosen. Dispersed myofibrils were nearly randomly oriented in two dimensions, so that the effects of muscle volume were minimized; these effects usually interfere significantly with a quantitative analysis of laser optical diffraction in the fiber system. The diameters of diffraction rings represented the average sarcomere length. By using this system, we confirmed the ability of the unit cell (sarcomere) structure model to explain the intensity change of diffraction lines accompanying the dissociation from both ends of thick filaments in a high salt solution. The length of an A-band estimated from the relative intensity of diffraction rings and that directly measured on phase-contrast micrographs coincided well with each other. Also, we found that myofibrils with a long sarcomere length shorten to a slack length accompanying the decrease in overlap between thick and thin filaments produced by the dissociation of thick filaments.     

Cell analysis system based on immunomagnetic cell selection and alignment followed by immunofluorescent analysis using compact disk technologies

BACKGROUND: Although the flow cytometer has become the standard in cell analysis, it has limitations. Recently, we introduced a new cell analysis method based on immunomagnetic selection and aligning of cells. No flow system is needed and cell analysis can be performed in whole blood. METHODS: Whole blood is incubated with fluorescent labels and immunomagnetic nanoparticles. The blood is injected into a capillary that is in a strong magnetic field. The immunomagnetic-labeled cells move upward and align themselves along ferromagnetic lines present on the upper surface of the capillary. An optical focus and tracking system analogous to that used in a conventional compact disk player focuses a 635-nm laser-diode on the magnetically aligned cells. The emitted fluorescence signals are projected on two photomultipliers. Allophycocyanin (APC)-labeled CD4 (CD4-APC) and Cyanin5.5 (Cy5.5)-labeled CD8 (CD8-Cy5.5) antibodies and Oxazine750, all red excited, are used as fluorescent labels. RESULTS: A differential white blood cell count performed in whole blood is obtained using the CD4-APC in combination with Oxazine750. The results are compared with the Technicon-H1 hematology analyzer. Correlation coefficients of 0.91 for neutrophilic granulocytes, 0.93 for lymphocytes, 0.93 for monocytes, and 0.96 for eosinophilic granulocytes were obtained. Immunofluorescence is demonstrated using CD4-APC and CD8-Cy5.5. The absolute counts obtained for CD4+ and CD8+ are compared with the Coulter Epics XL flow cytometer. Correlation coefficients of, respectively, 0.91 and 0.94 were obtained. CONCLUSION: We conclude that our system is as capable as a standard flow cytometer or hematology analyzer for a reliable routine white blood cell analysis, including immunophenotyping, and can be used as an easy-to-handle disposable white blood cell test.     

New suspension culture system (Mini-AR).

A new suspension culture system (Mini-AR) based on the Stoke's drag law for suspended particles is described. This apparatus can be utilized for the maintenance of mammalian kidney cells in both short- and long-term cultures.     

Evaluation of a green laser pointer for flow cytometry.

Flow cytometers typically incorporate expensive lasers with high-quality (TEM00) output beam structure and very stable output power, significantly increasing system cost and power requirements. Red diode lasers minimize power consumption and cost, but limit fluorophore selection. Low-cost DPSS laser pointer modules could possibly offer increased wavelength selection but presumed emission instability has limited their use. A $160 DPSS 532 nm laser pointer module was first evaluated for noise characteristics and then used as the excitation light source in a custom-built flow cytometer for the analysis of fluorescent calibration and alignment microspheres. Eight of ten modules tested were very quiet (RMS noise < or = 0.6% between 0 and 5 MHz). With a quiet laser pointer module as the light source in a slow-flow system, fluorescence measurements from alignment microspheres produced CVs of about 3.3%. Furthermore, the use of extended transit times and < or =1 mW of laser power produced both baseline resolution of all 8 peaks in a set of Rainbow microspheres, and a detection limit of <20 phycoerythrin molecules per particle. Data collected with the transit time reduced to 25 micros (in the same instrument but at 2.4 mW laser output) demonstrated a detection limit of approximately 75 phycoerythrin molecules and CVs of about 2.7%. The performance, cost, size, and power consumption of the tested laser pointer module suggests that it may be suitable for use in conventional flow cytometry, particularly if it were coupled with cytometers that support extended transit times.     

Use of xantham gum to suspend large particles during flow cytometric analysis and sorting

In this report we describe the use of xantham gum as a biologically inert material for increasing the viscosity of a suspension of cells or particles during flow cytometric analysis and sorting. A 0.1% concentration of xantham gum in culture medium or saline will increase the viscosity approximately 9-fold. For suspensions of multicellular spheroids 100-400 microns in diameter the measured sedimentation velocity was approximately 9 times slower than that in medium alone. Thus, spheroids of 100 microns diameter remain in suspension in 0.1% xantham gum for 66 min, compared to 7.5 min in culture medium. This allows extended periods of sorting without stirring or agitating the sample suspension. The xantham gum solution is noncytotoxic for periods up to 8 h as measured by clonogenicity assay. Xantham gum has the added advantage that the viscosity is significantly reduced when the solution is subjected to shear stress, such as during flow. This technique should be applicable to extended sorting of suspensions of spheroids, plant cells, and other large particles, as well as for analyzing and sorting single cells for extended periods.     

Flow cytometric competitive binding assay for determination of actinomycin-D concentrations

A single step, separation free competitive binding reaction between the fluorescent antibiotic mithramycin and actinomycin-D for common binding sites on DNA coated 10 microns diameter microspheres is described. The fluorescence of the microspheres is measured with a flowcytometer. In the presence of a constant amount of mithramycin, the microsphere fluorescence is inversely proportional to actinomycin-D concentration.     

Optical plankton analyser: a flow cytometer for plankton analysis, I: Design considerations

The design criteria for a flow cytometer (FCM) for the analysis of field samples of phytoplankton are described. The criteria are based on the occurrence of a wide variety of particle sizes in field samples, normally at low concentrations. The instrument should be able to analyse cells and colonies from 0.5 to 500 microns diameter and of over 2,000 microns length. A minimum flow rate of 4 microliters.s-1 was calculated from natural plankton concentrations. Commercially available FCMs are not suited to measure this range of sizes at this rate. Further limitations of standard FCMs are uneven illumination or incomplete processing of long signals. In addition, long filamentous colonies can break into small fragments caused by too high acceleration in the standard flow cuvette. Recognition of these limitations is of importance for the flow cytometry of phytoplankton. The new design was developed to avoid these limitations. A dynamic range 5 to 6 decades could be accomplished by a combination of logarithmic amplifiers, a slit-shaped focal spot, and a pulse integration system that can process long pulses. Multilaser capability to identify different phytoplankton species, a low fluid shear cuvette, and a trigger gate-extension for inhomogeneously fluorescent algal filaments were included in the design.     

The reaction of protein tryptophanyl residues with reduced nicotinamide adenine dinucleotide. Structure of a model adduct.

This paper describes in detail a simple, light producing and handling system which differs greatly from the commercial unit presently used by most investigators, and which overcomes a number of its disadvantages. The apparatus is designed so that it can easily be substituted for the light producing, dispersing, and collimating section of the commercial photoelectric scanners, with no further changes in the commercial scanners except the substitution of optical flats for the collimating and condensing lenses in the bottom and top, respectively, of the rotor chamber. The most outstanding feature of this new system is that the use of a faster monochromator ($\text{f}\text{75.3}$) and a cylindrical lens theoretically increases light intensity by up to 100 times that of the commercial scanner, under otherwise identical conditions. Other advantages include the following: (1) For collecting and collimating light, two pairs of mirrors give a precell optical system focused in the radial direction at all wavelengths of light; (2) these components and the lamp are located on a table outside the centrifuge, so virtually any size of lamp can be used; (3) the entire precell optical system is a self-contained unit which, within reasonable limits, may be moved to any desired location without markedly affecting the quality of the collimated light; and (4) the optical path length has been shortened, providing less dissipation of light energy. The principles behind the selection and design of the key components are discussed. New alignment procedures and apparatus developed to aid in fast, easy, accurate alignment are described and discussed. Several components for use with a system using a computer-controlled stepping motor scanner for collection of data are also described. This system is simple enough and is documented in sufficient detail so that other interested workers, even those with little or no optics experience, can duplicate and use the system.     

Fluorescence response and sensitivity determination for ATC 3000 flow cytometer

The fluorescence emitted by labeled particles after interaction with exciting light is conditioned by laser beam geometry and by the mode of fluorescence collection and filtration. A laser elliptic focusing mode is described, and the fluorescence characteristics of the sample cell flow are calculated. Fluorescence collection and detection through optical filters were analyzed, and efficiency was calculated for the ATC 3000 flow cytometer (Odam-Bruker, Wissembourg, France). A mathematical model is proposed for calculation of the fluorescence signal and its fluctuations. The background noise for the ATC 3000 was quantified experimentally using fluorescent microspheres of a known number of bound equivalent fluorescein isothiocyanate (FITC) molecules. These experimental measurements were found to fit the theoretical predictions, thus validating the proposed model.     

Alginate hydrogel microspheres and microcapsules prepared by spinning disk atomization

Our spinning disk atomization (SDA) can, relative to other existing techniques, produce micron-sized particles with very narrow size distribution. The aim of this work is to present this technology for the production of alginate microspheres and microcapsules. We atomized and gelled aqueous alginate solutions into very narrowly dispersed microspheres with sizes ranging from 300 to 600 microm. Here, the interest is to produce, at high rate, particles of a given size with a narrow size distribution and also to show a new method of encapsulation using SDA. The viscosity and flow rate contributions in the drop formation is qualitatively analyzed to show how they affect droplet size. In addition, a technique for high degree of encapsulation is presented in which yeast is used as a model system. The production of yeast-loaded microspheres by SDA shows the potential of the technique for biotechnology applications.