Application of bead-based assays for flow cytometry analysis

To date microsphere-based assays in flow cytometry have focused on the detection of antibody or antigen. Most studies have been research based to evaluate the performance of the technique relative to conventional techniques. However, there have not been any carefully controlled studies of the sensitivity and specificity, as well as analytic sensitivity of the FMIA technique. As such, it is difficult to document advantages of this tecnique clearly. The data suggest that FMIA is considerably more sensitive than conventional techniques, and the ability to analyze for multiple analytes in one sample dilution is attractive. This ability to simultaneously analyze for multiple samples is primarily dependent upon the size difference as sensed by FALS of the microspheres. However, it is also possible to use microspheres of the same size but that differ in either fluorescence or RALS signal. If microspheres of the same size are used but one fluoresces red and the signal in the assay uses a green fluorochrome, then the two microspheres can be separated by their red fluorescence. Using this technique, one can increase the number of microspheres that can be used in an assay. It is also possible to use microspheres of the same size but with different abilities to scatter the incident light at right angles. The use of these microspheres is then similar to the nonfluorescent versus red microspheres. By the judicious combination of microsphere size, it is possible to easily differentiate eight different microspheres. With the addition of a fluorescebt dye and/or differences in right-angle light-scatter capabilities, the number of different microspheres that can be used simultaneously becomes quite large. In practice, the number of microspheres that can be differentiated is no doubt greater than the number of analytes that need to be assayed in one assay.Although the apparent increase in sensitivity and the ability to simultaneously detect and quantitate numerous analytes are important attributes of FMIA, there are drawbacks to this method. Although the FMIA lends itself well to one-step no-wash procedures, when wash steps are necessary they are time-consuming and ineffecient. Most wash steps in FMIA use centrifugation of the microspheres to remove them from the reagent. There is a significant loss of microspheres in these wash steps, which are time-consuming. There are studies ussing vacuum filtration of the suspension to separate the microspheres from the reagents. A number of different groups are pursuing an automated or semiautomated method for the efficient washing and reagent delivery system for FMIA. Commercial systems are being developed that may allow for the easier handling of these reagents.Numerous groups are investigating the use of microspheres and flow cytometry primarily in immunoassay development. The procedure has the advantages of the simultaneous yet discrete analysis of multiple analytes and the inherent increase in sensitivity using fluorescence over other signals. There will no doubt be wider applications     

Fluorescent nanometer microspheres as a reporter for sensitive detection of simulants of biological threats using multiplexed suspension arrays

We succeeded in using 40 nm FRET (fluorescence resonance energy transfer) microspheres conjugated to antibodies as the fluorescent reporters to perform the multiplexing suspension array measurements on two simulants of biological threats, ricin (A chain) and a crude spore preparation of Bacillus globigii (Bg). The microspheres were impregnated with two types of fluorophores in equal number (approximately 140 fluorophores in total per microsphere) and displayed bright PE-like fluorescence via a fluorescence resonance energy transfer mechanism. Activated microspheres (aldehyde groups) were directly coupled to antibodies and used to form sandwich-type immunoassays in a suspension array. For the crude preparations of Bg, the assay sensitivity using antibody-conjugated microspheres is an order of magnitude higher than that using the conventional fluorescent reporter, R-phycoerythrin (PE). Using the microspheres, Bg at the concentration of 5 ng/mL can be easily detected. For ricin, the assay sensitivity was similar to that obtained using PE as the reporter, but washing the reaction mixtures resulted in the fluorescence signals that were 2-3 times higher compared to those using PE. Ricin at a concentration of 1 ng/mL can be readily identified. Importantly, the two simulants do not interfere with each other in the multiplexing experiments. The 40 nm FRET microspheres are a new sensitive alternative as fluorescent reporters for detection in suspension arrays.     

Comparison of two fluorescence immunoassay methods for the detection of endocrine disrupting chemicals in water

We describe two fluorescence immunoassays capable of detecting endocrine disrupting compounds in waste water. The first fluorescence method is a heterogeneous assay using total internal reflection fluorescence (TIRF) detection. The second method is a homogeneous assay that utilizes energy transfer (ETIA). Both fluorescence immunoassays are compared with respect to detection principle and ability to quantify the model analytes estrone, estradiol, and ethinylestradiol in a complex matrix regarding recovery rates and limits of detection. Calibrations were performed for the three analytes using both fluorescence methods. Limits of detection between 0.01 and 0.85 microg/l are achieved. In addition, measurements in synthetic waste water spiked with the analytes were performed. Both immunoassays allow the detection in waste water with recovery rates in the range of 70-112%.     

Magnetophoretic position detection for multiplexed immunoassay using colored microspheres in a microchannel

This paper demonstrates a new magnetophoretic position detection method for multiplexed immunoassay using colored microspheres as an encoding tool in a microchannel. Colored microspheres conjugated with respective capture molecules are incubated with a mixture of target analytes, followed by reaction with the probe molecules which had been conjugated with superparamagnetic nanoparticles (SMNPs). Under the magnetic field gradient, the resulting microspheres are deflected from their focused streamlines in a microchannel, and respective colored microspheres are detected using color charge-coupled device (CCD) in a specific detection region of the microchannel. The color and position of respective colored microspheres are automatically decoded and analyzed by MATLAB program, and the position was correlated with the concentration of corresponding target analytes. As a proof-of-concept, we attempted to assay simultaneously three types of biotinylated immunoglobuline Gs (IgGs), such as goat, rabbit and mouse IgGs, using colored microspheres (red, yellow and blue, respectively). As the capture molecules, corresponding anti-IgGs were employed and target analytes were probed using streptavidin-modified superparamagnetic nanoparticles. As a result, three analytes were simultaneously assayed using colored microspheres with high accuracy, and detection limits of goat IgG, rabbit IgG and mouse IgG were estimated to be 10.9, 30.6 and 12.1fM, respectively. In addition, with adjustment of the flow rate and detection zone, the dynamic range could be controlled by more than one order of magnitude.     

Determinations of fluoroquinolones and nonsteroidal anti-inflammatory drugs in urine by extractive spectrophotometry and photoinduced spectrofluorimetry using multivariate calibration

Multivariate calibration methods are chemometric tools that may be applied to the analysis of spectroscopic data with multichannel detection. Two procedures, based on spectrophotometric and fluorimetric signals, are reported for the simultaneous determination of two fluoroquinolones (ciprofloxacin and ofloxacin) and two nonsteroidal anti-inflammatory drugs (diclofenac and mefenamic acid) using first- and second-order multivariate calibration methods. In the spectrophotometric method, an extractive procedure into chloroform using trioctylmethylammonium chloride-adogen as counter ion was optimized, with the object of extracting the analytes from urine samples and eliminating matrix interferences. After separation, the absorption spectrum of the organic phase was used as the analytical signal in a partial least squares method. A photoinduced spectrofluorimetric (PIF) method using excitation-emission fluorescence matrices, is proposed, to apply three-way chemometric calibration, with the aim of analyzing ofloxacin, ciprofloxacin, and diclofenac in urine samples without the previous extractive sample-cleaning step. For both procedures, recoveries around 100% were found for all the analytes. However, the PIF three-way chemometric method provides the most sensitive and selective procedure as the urine interferences are modulated using the three-way chemometric technique.     

Xanthan/chitosan gold chip for metal enhanced protein biomarker detection

Protein microarrays for disease diagnostics are required to accurately quantify analytes in the low pg/mL range. This task is hampered by weak signal strengths and too low detector sensitivity. Herein we present reflective gold chips coated with polyelectrolyte multilayers (PEMs) for signal enhancement in immunoassays for melanoma-relevant biomarkers. Among tested (semi)natural polysaccharides (xanthan, chitosan, carboxymethylcellulose, hyaluronic acid) PEMs composed of xanthan and chitosan performed best in terms of detection of low analyte concentrations (ED10), spot morphology, fluorescence background and variability (<10%). Fluorescence signals on gold slides with a 75 nm coating of seven crosslinked polyelectrolyte double layers were up to 50 times higher than on bare glass slides. In comparison to commercial substrates the signal to noise ratio is enhanced by up to factor 11. Furthermore sandwich assays for interleukins 6, 8, 10, tumour necrosis factor alpha (TNFα), vascular endothelial growth factor A (VEGF-A) and S100B show working ranges which cover significantly lower concentrations (up to 38-fold). Not limited to above assays the presented substrates, which combine a biocompatible interface with metal-based signal amplification, are a valuable tool in a variety of biosensor applications.     

High sensitivity multianalyte immunoassay using covalent DNA-labeled antibodies and polymerase chain reaction.

A multianalyte immunoassay for simultaneous detection of three analytes (hTSH, hCG and beta-Gal) has been demonstrated using DNA-labeled antibodies and polymerase chain reaction (PCR) for amplification of assay response. The labeled antibodies were prepared by covalently coupling uniquely designed DNA oligonucleotides to each of the analyte-specific monoclonal antibodies. Each of the DNA oligonucleotide labels contained the same primer sequences to facilitate co-amplification by a single primer pair. Assays were performed using a two-antibody sandwich assay format and a mixture of the three DNA-labeled antibodies. Dose-response relationships for each analyte were demonstrated. Analytes were detected at sensitivities exceeding those of conventional enzyme immunoassays by approximately three orders of magnitude. Detection limits for hTSH, beta-Gal and hCG were respectively 1 x 10(-19), 1 x 10(-17) and 1 x 10(-17) mol. Given the enormous amplification afforded by PCR and the existing capability to differentiate DNA based on size or sequence differences, the use of DNA-labeled antibodies could provide the basis for the simultaneous detection of many analytes at sensitivities greater than those of existing antigen detection systems. These findings in concert with previous reports suggest this hybrid technology could provide a new generation of ultra-sensitive multianalyte immunoassays.     

Multiplexed Fluorescent Microarray for Human Salivary Protein Analysis Using Polymer Microspheres and Fiber-optic Bundles

Herein, we describe a protocol for simultaneously measuring six proteins in saliva using a fiber-optic microsphere-based antibody array. The immuno-array technology employed combines the advantages of microsphere-based suspension array fabrication with the use of fluorescence microscopy. As described in the video protocol, commercially available 4.5 μm polymer microspheres were encoded into seven different types, differentiated by the concentration of two fluorescent dyes physically trapped inside the microspheres. The encoded microspheres containing surface carboxyl groups were modified with monoclonal capture antibodies through EDC/NHS coupling chemistry. To assemble the protein microarray, the different types of encoded and functionalized microspheres were mixed and randomly deposited in 4.5 μm microwells, which were chemically etched at the proximal end of a fiber-optic bundle. The fiber-optic bundle was used as both a carrier and for imaging the microspheres. Once assembled, the microarray was used to capture proteins in the saliva supernatant collected from the clinic. The detection was based on a sandwich immunoassay using a mixture of biotinylated detection antibodies for different analytes with a streptavidin-conjugated fluorescent probe, R-phycoerythrin. The microarray was imaged by fluorescence microscopy in three different channels, two for microsphere registration and one for the assay signal. The fluorescence micrographs were then decoded and analyzed using a homemade algorithm in MATLAB.     

A Fast Universal Immobilization of Immunoglobulin G at 4°C for the Development of Array-based Immunoassays

To maintain the antibody activity and enhance performance of array-based immunoassays, protein G was used to allow a shorter duration of immunoglobulin G immobilization at 4°C, with the antibody placed in the appropriate orientation. The multiplexed detection of six pain-related message molecules (PRMMs) was used as examples for the development of array-based immunoassays: substance P, calcitonin gene-related peptide, nerve growth factor, brain-derived neurotrophic factor, tumor necrosis factor-α, and β-endorphin. Protein G- and non-protein G-coated slides were tested. Compared to non-protein G immunoassays, protein G shortened the antibody immobilization time at 4°C from overnight to 2 hours. Only protein G-facilitated immunoassays succeeded in simultaneously detecting all six PRMMs with high specificity. Dose-response curves showed that the limits of detection of the protein G-multiplexed immunoassays for the PRMMs was approximately 164, 167, 120, 60, 80, and 92 pg/ml, respectively. Thus, protein G effectively shortens the duration of antibody immobilization at 4°C, allowing the use of sensitive array-based immunoassays for the simultaneous detection of PRMMs.     

Characterization of an inexpensive, nontoxic, and highly sensitive microarray substrate

An agarose film has been proposed as an efficient substrate for producing microarrays. The original film preparation procedure was simplified significantly by grafting the agarose layer directly onto unmodified microscope glass slides instead of aminated glass slides, and the blocking procedure was replaced with a wash in 0.1x standard saline citrate (SSC) and 0.5% sodium dodecyl sulfate (SDS) without decreasing the performance of the produced microarrays. Characterization of the grafted agarose film using atomic force microscopy (AFM) and scanning electron microscopy (SEM) showed that the agarose film had a 10-fold increase in surface roughness compared to glass and that the interior of the agarose film was porous, with pore sizes between 100-500 nm. A comparison of hybridization on aldehyde-activated agarose-coated microarray slides and commercial amino-reactive microarray slides showed that aldehyde-activated agarose-coated slides had the highest signal-to-noise ratio of 850, suggesting that the aldehyde-activated agarose microarray slides are suitable in applications where analytes have a wide concentration range. By immobilizing the DNA probes using ultraviolet (UV) light, the signal-to-noise ratio was further increased to 3000 on the agarose microarray slides. The specificity of the UV cross-linked DNA probes was demonstrated using 21 and 25 bp long capture probes, enabling discrimination of target molecules differing in only one base.     

Development of an automatic machine for in situ hybridization and immunohistochemistry.

An instrument for the automation of in situ hybridization and immunohistochemistry has been developed. This machine is capable of analyzing 20 microscope glass slides via all of the steps required for colorimetric in situ hybridization or immunohistochemistry. The slides are placed specimen-side down on a specialized Teflon slide-holder set in the reaction chamber of the machine. The system uses a unique type of capillary action between the slide and the holder. The holder has two small holes and is designed to apply, incubate and sequentially add and remove reagents from the slide surface. The system performs the complete processes of in situ hybridization and immunohistochemistry from dewaxing to colorization. Some applications were carried out using this instrument. Cultured cells infected with cytomegalovirus, adenovirus, or herpes simplex virus were hybridized with homologous biotinylated probes, and showed strong purple signals with alkaline phosphatase in the presence of nitroblue tetrazolium and 5-bromo-4-chloro-3-indolyl phosphate. Automatic in situ hybridization using other colorimetric detection systems (e.g., peroxidase-labeled probes/diaminobenzidine/H2O2) was also examined in cells infected with Chlamydia trachomatis and in paraffin-embedded hepatic tissue sections from patients with hepatitis. For conventional immunohistochemical staining, formalin-fixed and paraffin-embedded tissues were used. Glial fibrillary acidic protein and gamma-immunoglobulins were detected automatically in human brain white matter and tonsillar tissues, respectively, as peroxidase-based reddish signals. The intensity of staining was equal to that achieved by manual methods.     

Flow cytometry of human gynecologic specimens using log chromomycin A3 fluorescence and log 90 degrees light scatter.

Flow cytometry and electronic cell sorting are being investigated to screen gynecologic specimens for cervical neoplasia. Cellular DNA content is quantitated by Chromomycin A3 fluorescence and cell size is quantitated by 90 degrees light scatter; the logarithms of the measured intensities are used to produce a two parameter histogram. To determine the cell types responsible for signals in various histogram regions, systematic electronic cell sorting is performed. The sorted fractions are sedimented into microscope slides and stained by the Papanicolaou technique. The cells in each fraction are identified by conventional cytomorphologic criteria. Morphologic analysis of sorted cells reveals histogram regions corresponding to specific cell types. One very important region contains the highest concentration of signals from abnormal cells and is therefore the best region to analyze for specimen abnormality. However, because a significant number of signals in this region are from normal cells, specimens cannot be diagnosed by their analysis. Another important histogram region is composed primarily of signals from endocervical columnar and metaplastic cells. The presence of such cells is a good criterion for specimen adequacy, therefore analysis of signals in this region is essential to assess specimen adequacy for automatic screening.     

Flow microfluorometric and light-scatter measurement of nuclear and cytoplasmic size in mammalian cells.

A technique for rapid measurement of nuclear and cytoplasmic size relationships in mammalian cell populations has been developed. Based on fluorescence staining of either the nucleus alone or in combination with the cytoplasm using two-color fluorescence methods, this technique permits the simultaneous determination of nuclear and cytoplasmic diameters from fluorescence and light-scatter measurements. Cells stained in liquid suspension pass through a flow chamber at a constant velocity, intersecting a laser beam which excites cell fluorescence and causes light scatter. Depending upon which analysis procedure is used, optical sensors measure nuclear fluorescence and light scatter (whole cell size) or two-color nuclear and cytoplasmic fluorescence from individual cells crossing the laser beam. The time durations of signals generated by the nucleus and cytoplasm are converted electronically into signals proportional to the respective diameters and are displayed as frequency distribution hitograms. Illustrative examples of measurements on uniform microspheres, cultured mammalian cells and human exfoliated gynecologic cells are presented.     

Sample preparation and liquid chromatography-tandem mass spectrometry for multiple steroids in mammalian and avian circulation

Blood samples from wild mammals and birds are often limited in volume, allowing researchers to quantify only one or two steroids from a single sample by immunoassays. In addition, wildlife serum or plasma samples are often lipemic, necessitating stringent sample preparation. Here, we validated sample preparation for simultaneous liquid chromatography--tandem mass spectrometry (LC-MS/MS) quantitation of cortisol, corticosterone, 11-deoxycortisol, dehydroepiandrosterone (DHEA), 17β-estradiol, progesterone, 17α-hydroxyprogesterone and testosterone from diverse mammalian (7 species) and avian (5 species) samples. Using 100 μL of serum or plasma, we quantified (signal-to-noise (S/N) ratio ≥ 10) 4-7 steroids depending on the species and sample, without derivatization. Steroids were extracted from serum or plasma using automated solid-phase extraction where samples were loaded onto C18 columns, washed with water and hexane, and then eluted with ethyl acetate. Quantitation by LC-MS/MS was done in positive ion, multiple reaction-monitoring (MRM) mode with an atmospheric pressure chemical ionization (APCI) source and heated nebulizer (500°C). Deuterated steroids served as internal standards and run time was 15 minutes. Extraction recoveries were 87-101% for the 8 analytes, and all intra- and inter-run CVs were ≤ 8.25%. This quantitation method yields good recoveries with variable lipid-content samples, avoids antibody cross-reactivity issues, and delivers results for multiple steroids. Thus, this method can enrich datasets by providing simultaneous quantitation of multiple steroids, and allow researchers to reimagine the hypotheses that could be tested with their volume-limited, lipemic, wildlife samples.     

Direct and nondestructive verification of PNA immobilization using click chemistry

The fluorogenic 1,3-Huisgen dipolar cycloaddition reaction was used as part of a novel immobilization strategy of PNA capture probes on a microarray. By using this click chemistry, azidocoumarin-anchored PNA probes were immobilized on phenyl acetylene-modified glass slides with the simultaneous generation of the fluorescent triazolylcoumarin moiety. Since the emitting moieties are generated in the immobilization reaction itself, fluorescent signals can be used to directly monitor the integrity of immobilization in a nondestructive manner. By using this strategy, PNA microarrays were prepared and successfully employed to perform microarray-based diagnosis of selected mutations in the breast cancer susceptibility gene BRCA1.     

Multi-wavelength immunoassays using surface plasmon-coupled emission

We describe a new method for multi-wavelength immunoassays using surface plasmon-coupled emission (SPCE). This phenomenon is coupling of excited fluorophores with a nearby thin metal film, in our case silver, resulting in strongly directional emission into the underlying glass substrate. The angle at which the radiation propagate through the prism depends on the surface plasmon angle for the relevant wavelength. These angles depend on emission wavelength, allowing measurement of multiple analytes using multiple emission wavelengths. We demonstrated this possibility using antibodies labeled with either Rhodamine Red-X or AlexaFluor 647. These antibodies were directed against an antigen protein bound to the silver surface. The emission from each labeled antibody occurred at a different angle on the glass prism, allowing independent measurement of surface binding of each antibody. This method of SPCE immunoassays can be readily extended to 4 or more wavelengths.     

Blinded evaluation of DNA extraction and genotyping of stained Cryptosporidium on glass slides

AIMS: A blinded trial was performed on Cryptosporidium genotyping using polymerase chain reaction (PCR)/restriction fragment length polymorphism analysis of the Cryptosporidium oocyst wall protein (COWP) gene between DNA extracted from oocyst suspensions as compared with DNA from fixed and stained faecal smears on glass microscope slides. METHODS AND RESULTS: Sixty-five faecal smears on slides were stained by one of three different methods comprising 50 positives and 15 negatives as determined by the observation of Cryptosporidium oocysts by microscopy. The expected result in terms of detection and the COWP genotype detected was achieved using DNA extracted from 94% of the slides tested. CONCLUSIONS: This study shows that DNA, which can be amplified by PCR, is present in stained smears on glass microscope slides. SIGNIFICANCE AND IMPACT OF THE STUDY: The method may be useful for molecular epidemiological studies on a range of gastrointestinal pathogens where samples are collected from locations remote from the testing laboratory.     

In situ hybridization: use of 35S-labeled probes on paraffin tissue sections

The following protocol is for radioactive in situ hybridization detection of RNA using paraffin-embedded tissue sections on glass microscope slides. Steps taken to inhibit RNase activity such as diethyl pyrocarbonate (DEPC) treatment of solutions and baked glassware are unnecessary. The tissue is fixed using 4% paraformaldehyde, hybridized with (35)S-labeled RNA probes, and exposed to nuclear-track emulsion. The entire procedure takes 2-3 days prior to autoradiography. The time required for autoradiography is variable with an average time of 10 days. Parameters that affect the length of the autoradiography include: (1) number of copies of mRNA in the tissue, (2) incorporation of label into the probe, and (3) amount of background signal. Additional steps involved in the autoradiography process, including development of the emulsion, cleaning of the microscope slides, counterstaining of the tissue, and mounting coverslips on the microscope slides, are discussed. In addition, a general guide to the interpretation of the in situ results is provided.