流式细胞光度计

我们研制成功的FC-1型流式细胞光度计(流式细胞计)已于1990年12月17日通过院级鉴定,鉴定委员会经过认真的测试与评审认为:我们研制的流式细胞光度计是国内第一台能同时测定细胞的两个波段的荧光,前向散射光和90°散射光的多参数仪器,具有四路线性     

微生理计在受体研究中的应用

微生理计是八十年代末发展起来的一种基于光寻址电位传感器的新颖仪器。本主要介绍微生理计在受体研究中的应用和发展前景。     

流式细胞术在细菌快速检测中的应用

流式细胞仪(Flow cytometer)是集应用流体学、光学、电子学、生物学、免疫学等多门学科和技术于一体的新型高科技仪器。它的核心技术是流式细胞术(Flow cytometry,FCM),该技术是利用流式细胞仪,使单个细胞或其他微小生物粒子处于快速直线流动状态,且逐个通过光束,从而对单个细胞或微粒进行多参数(数量、大小、核酸含量、细胞活性、特定菌群或物种等)定量分析和分选的检测技术,具有快速、灵敏、精确以及便于操作等突出优点。本文简要介绍流式细胞仪的原理,并论述流式细胞技术在实验室研究、工业生产、临床诊断、环境评估等领域的细菌快速检测应用。     

流式细胞计无菌分选功能的开发

分选技术是流式细胞计一项重要功能。其分离细胞的速度及纯度是目前世界上任何其他医学仪器无法比拟的。其分选速度可高达3000—5000个细胞/秒;纯度可高达99％以上。 分选可分为两种,一种为一般分选,另一种为无菌分选。无菌分选需要在分选过程中严格保证无菌条件,使分选过程中细胞不受污染。以利于细胞的继续增殖。一般分选,国内其他实验室正在开展;而无菌分选国内尚未见报道。国外也只是部分实验室在应用。我们参考了一些国内外文献并借鉴了一些国外经验,在FACS440型流式细胞计上开发了无菌分选功能。本文介绍这种方法及应用。希望此文对今后推广这项技术起到促进作用。     

专家答读者问：流式细胞仪如何将不同类型的细胞分开

<正>流式细胞仪（flow cytometer）是一种在功能水平上对单细胞或其他生物粒子进行定量分析和分选的检测仪器，可以每秒钟分析上万个细胞/粒子，并能同时从一个细胞/粒子中获得多个参数。其应用范围非常广泛，而且还在不断拓展，细胞分选也是它的重要应用之一。它能够根据每个细胞的光散射和荧光特征，将特定的细胞从细胞群体中分选出来。下文以细胞为例具体说明流式细胞仪的工作原理、技术特点和应用。流式细胞仪能够利用细胞的光散射特征，     

流式细胞仪的原理、应用及最新进展

流式细胞术是一种采用激光束激发单行流动的细胞,对它的散射光和携带的荧光进行探测,从而完成细胞分析和分选的技术。以流式细胞术为核心技术,流式细胞仪集光学、电子学、生物学、免疫学等多门学科和技术于一体,能够高效分析微小颗粒（如细胞,细菌）的先进科技设备。它对社会产生了深远的影响,成为了科学研究的必要工具。最近几年,流式细胞仪取得了长足进步。为了深入的了解它,本文从流式细胞仪的工作原理和技术指标,在临床医学、生物学、生殖学和制药学中的应用,以及它的世界格局、仪器功能的最新进展三方面,进行了简明、扼要的论述。展望未来：功能专业化、自动化,体积小型化,多色多参数分析能力提高和分析分选速度更快成为流式细胞仪发展的趋势。     

流式细胞仪的原理、应用及最新进展

流式细胞术是一种采用激光束激发单行流动的细胞,对它的散射光和携带的荧光进行探测,从而完成细胞分析和分选的技术。以流式细胞术为核心技术,流式细胞仪集光学、电子学、生物学、免疫学等多门学科和技术于一体,能够高效分析微小颗粒(如细胞,细菌)的先进科技设备。它对社会产生了深远的影响,成为了科学研究的必要工具。最近几年,流式细胞仪取得了长足进步。为了深入的了解它,本文从流式细胞仪的工作原理和技术指标,在临床医学、生物学、生殖学和制药学中的应用,以及它的世界格局、仪器功能的最新进展三方面,进行了简明、扼要的论述。展望未来:功能专业化、自动化,体积小型化,多色多参数分析能力提高和分析分选速度更快成为流式细胞仪发展的趋势。     

流式细胞术免疫荧光测量中的直标及间标

直接标记和间接标记是免疫荧光测量中两种不同的标记方法.在流式细胞计测量中,一般说来,直接标记不易引入样品的非特异性结合,因此引入干扰少,样品的数据好处理,而间接标记由于有放大作用,容易引入非特异结合的干扰,严重时所得数据无法区分特异及非特异信号,造成数据分析的混乱,通过样品实测比较,认为在流式细胞计测量中应用直接样品更为合适.     

细胞影像分析大型仪器应用于本科实验教学的探索

本文分析了细胞影像分析大型仪器在本科《细胞生物学》实验教学中的应用现状。结合国内其他高校该科目的教学模式和实践,我们探索了激光共聚焦显微镜、流式细胞仪、细胞成像多功能微孔板检测系统等细胞影像分析大型仪器在教学中的应用,对深化本科《细胞生物学》实验教学内容和提高优质资源的共享效率有积极意义。     

《流式细胞光度术》

《流式细胞光度术》(Flow cytometry)由M. G. Ormerod编著,1990年IRL出版社出版,279页。流式细胞光度术的飞跃发展,引起越来越多科研人员的兴趣,迫切需要掌握它。该书设计成既能帮助新入门的科研人员,又能对资历较深的研究人员提供指导,它拓宽了新方法的应用。该书首先叙述了流式细胞光度术的原理,随后详细阐明制备和分析样品的检验技术。它们包括:DNA分析;细胞分类;染色体分析和分类;动态细胞情况测量。     

Fluorescent labeling of nano-sized vesicles released by cells and subsequent quantitative and qualitative analysis by high-resolution flow cytometry

We provide a protocol for a high-resolution flow cytometry-based method for quantitative and qualitative analysis of individual nano-sized vesicles released by cells, as developed and previously described by our group. The method involves (i) bright fluorescent labeling of cell-derived vesicles and (ii) flow cytometric analysis of these vesicles using an optimized configuration of the commercially available BD Influx flow cytometer. The method allows the detection and analysis of fluorescent cell-derived vesicles of ～100 nm. Integrated information can be obtained regarding the light scattering, quantity, buoyant density and surface proteins of these nano-sized vesicles. This method can be applied in nanobiology to study basic aspects of cell-derived vesicles. Potential clinical applications include the detailed analysis of vesicle-based biomarkers in body fluids and quality control analysis of (biological) vesicles used as therapeutic agents. Isolation, fluorescent labeling and purification of vesicles can be done within 24 h. Flow cytometer setup, calibration and subsequent data acquisition can be done within 2-4 h by an experienced flow cytometer operator.     

Automated analysis of the cytokinesis-block micronucleus assay for radiation biodosimetry using imaging flow cytometry

The cytokinesis-block micronucleus (CBMN) assay is employed in biological dosimetry to determine the dose of radiation to an exposed individual from the frequency of micronuclei (MN) in binucleated lymphocyte cells. The method has been partially automated for the use in mass casualty events, but it would be advantageous to further automate the method for increased throughput. Recently, automated image analysis has been successfully applied to the traditional, slide-scoring-based method of the CBMN assay. However, with the development of new technologies such as the imaging flow cytometer, it is now possible to adapt this microscope-based assay to an automated imaging flow cytometry method. The ImageStream^X is an imaging flow cytometer that has adequate sensitivity to quantify radiation doses larger than 1 Gy while adding the increased throughput of traditional flow cytometry. The protocol and analysis presented in this work adapts the CBMN assay for the use on the ImageStream^X. Ex vivo-irradiated whole blood samples cultured for CBMN were analyzed on the ImageStream^X, and preliminary results indicate that binucleated cells and MN can be identified, imaged and enumerated automatically by imaging flow cytometry. Details of the method development, gating strategy and the dose response curve generated are presented and indicate that adaptation of the CBMN assay for the use with imaging flow cytometry has potential for high-throughput analysis following a mass casualty radiological event.     

Integration of a barcode reader with a commercial flow cytometer.

This report describes the application and installation of a barcode reader on a standard EPICS Elite flow cytometer. The barcode reader system eliminates keyboard entry of sample information on the cytometer. The system automates the transfer of sample information already present in our laboratory database to the cytometer at run time. The system uses a standard "off-the-shelf" bar code wand with a personal computer keyboard interface and requires no additional software at run time. No typing of sample information is required by the operator at any stage of normal sample operation at the cytometer. All operations are automatically coded into the cytometry software using the macro functions of the software. Tubes are inserted into the tube reader and sample information is transferred automatically into the cytometer. We have found that the system allows rapid and continuous operation of routine clinical and research samples. This automated data entry also reduces the possibility of data input errors.     

Small-volume rapid-mix device for subsecond kinetic analysis in flow cytometry.

BACKGROUND: Rapid-mix flow cytometry has emerged as a powerful tool for mechanistic analysis of ligand binding, cell response, and molecular assembly. Although progress has come from improving sample delivery capabilities, little attention has been paid to the volumetric requirements associated with precious biological reagents. METHODS: By using programmable syringes, valves, and other fluidic components, we created a modular, precisely regulated rapid-mix device for the delivery of small-volume samples to the flow cytometer. The device was tested using a bead-based assay in which the binding kinetics between native biotin and fluorescein biotin-bearing beads were characterized. RESULTS: Bead suspensions and reagents paired in 35- to 45-microl aliquots were efficiently mixed by the device and delivered to the flow cytometer. Kinetic data associated with the fluorescein biotin beads were analyzed and used to calibrate the performance characteristics of the device in terms of sample delivery and mixing efficiency. CONCLUSION: The rapid-mix device is capable of detecting subsecond kinetics of biological reactions using microliter volume of samples. Dimensions of the device have been minimized, and the quantitative aspects of sample delivery and analysis have been optimized. Further, the modular design has been optimized for adaptation to a variety of experimental protocols.     

Laser spatial scanning in flow cytometry]

The main flow laser cytometry principles, based on the elastic light scattering, spheres of its applications, problems of its realization and utilization in the immunological investigations and diagnostics are analysed. The experimental model of a flow cytometer with laser probing beam space scanning, originally proposed by the authors, is described. The apparatus was tested by polystyrene latex spheres and biological objects. The experiments showed that the achieved sensitivity was enough to register red blood cells, their complexes and bacterial cells.     

Calibration of a flow cytometer against a microphotometer for morphologic cell identification

The calibration of a flow cytometer against a microphotometer, to allow the correlation of cell morphology with fluorescence intensity, is described. Using three human lymphoblastoid cell lines, the photomultiplier amplification of the microphotometer and the flow cytometer that gave optimum linearity between fluorescence intensity and DNA content for the two instruments was established. Thereafter, at these settings, there was satisfactory linear agreement between the fluorescence intensity profiles, as measured by the flow cytometer and the microphotometer, of stained cell populations. Day-to-day variation was also minimal, and it was demonstrated that the application of this procedure can provide an alternative to the employment of the sorting facility of a flow cytometer for the morphologic identification of cell subpopulations during flow cytometric analysis.     

Peculiarities of cytometrical methods of DNA content determination in the nucleus

This work has proposed a new theoretical approach to analysis of histograms of DNA content, which are obtained by the method of flow cytometry, in cells of Drosophila melanogaster imaginal discs. The precision of measurements of the DNA amount in G₁ and G₂(M) phases has been shown to be limited by precision of instrument tuning of zero of the flow cytometer. Use of the calculative zero of the flow cytometer and of dividing cells as standards of the DNA content is able to increase severalfold the precision of the DNA measurements in nuclei of the species. Comparative analysis of errors of various methods of measurement of the DNA content in cell nuclei is also performed. For methods of flow fluorescent cytometry, confocal scanning, and cytophotometry of the Feulgen-stained nuclei, it has been shown that, at present, the mean square errors of the DNA content measurements are within the interval of values considered acceptable for biological studies (0.02 < CV < 0.06).     

The use of blue-excitable nucleic-acid dyes for the detection of bacteria in well water using a simple field fluorometer and a flow cytometer

The blue-excitable nucleic acid dyes Coriphosphine O (CPO), YOYO-1, and YOPRO-1 were evaluated to rapidly detect the presence of bacteria in well water samples using a simple field fluorometer (Turner Designs, Sunnyvale, CA, Model 10-AU-005) and a tabletop flow cytometer (Coulter Epics XL). The dyes were first titrated on the Turner Designs Model 10-AU field fluorometer with log-fold dilutions of Esherichia coli, since this organism is the indicator organism for water contamination. A detection limit of 10(4) Colony Forming Units per ml (CFU/ml) was established for YOPRO-1 and 10(5) CFU/ml for YOYO-1. The detection limit with CPO was determined to be 10(7) CFU/ml due to the high background fluorescence of the dye. The dyes were also evaluated with ragweed pollen to gauge the effect of a biological interferent. Ten well-water samples were subsequently analyzed using the technique. The results showed that only YOYO-1 correctly detected all the samples that were positive according to the reference laboratory. YOPRO-1 correctly detected only one of four positive samples. Analysis with the CPO dye was inconclusive due to high background fluorescence. The samples were then subjected to analysis on the flow cytometer. Results obtained with YOYO-1 compared well to those obtained on the fluorometer and by the reference techniques. YOPRO-1 performed better on the flow cytometer than with the simple fluorometer, correctly detecting three of four positive samples. Although the CPO results showed a very slight increase of green fluorescence with positive samples, they were largely indistinguishable from negative samples. This study suggests YOYO-1 could be useful with either a simple fluorometer or with a tabletop flow cytometer in screening water samples for the presence of bacterial contamination.     

Flow microsphere immunoassay-based method of virus quantitation.

A sensitive assay for adenovirus quantitation in vitro was developed using the flow microsphere immunoassay (FMIA) approach. Polystyrene microspheres were covalently coated with purified anti-adenoviral antibodies and incubated with virus-containing samples. After incubation, the samples were stained with DNA-specific fluorescent dyes, and microsphere-associated fluorescence was quantitated with a flow cytometer. The adsorption of virus to microspheres was examined under different experimental conditions. The flow cytometric assay was determined to be as accurate in detecting adenovirus as titering on 293 cells. The proposed method can be used to quantify virus in viral stocks and in biological samples.     

Analysis of the chromosome number in cells by flow cytometry

A new flow-cytometric method is described that permits analysis of the number of chromosomes of individual cells. Preliminary stained mitotic cells are passed through a specially designed flow chamber in which they are destroyed just before passing through the focused laser beam of the flow cytometer. Signals from chromosomes of the destroyed cells are counted, and the results are represented as a distribution of the number of chromosomes in the cells. The method may be applied for the detection of relatively rare cells with abnormal numbers of chromosomes in biological and clinical research.