A computer-controlled titration--fluorescence spectrometer.

An automatic titration device coupled with a modified Perkin-Elmer MPF-2A fluorescence spectrometer has been interfaced to a PDP $\text{11}\text{34}$ computer. The combined instrument has been used to study the interaction of fluorescent probes with lipid bilayers. The system functions by filling a cuvette in the sample compartment of the spectrometer with approximately 2.5 ml of solution. This solution is then titrated with discrete 3-μl drops of probe and the fluorescent intensity corresponding to each drop is monitored by the computer. Both the filling of the cuvette and the dispensing of the 3-μl drops are performed with better than 1% reproducibility. Upon completion of the titration curve, the cuvette is evacuated, washed, and refilled and the temperature can be changed, all under computer control. Temperature-dependent spectrometer responses have largely been eliminated by the use of a new temperature-controlled cuvette holder. The dispensing of the various solutions, evacuation, washing of the cuvette, and mixing of titrant and solution are accomplished through a cuvette-titration device interface cap.     

Acousto-optic laser-scanning cytometer

An instrument has been developed that uses a computer-controlled rapidly scanning laser beam to make cytometric measurements on cells or particles and which can measure low levels of fluorescence when using low-power lasers (Gershman, Hoffman, and O'Connell, "Methods and Apparatus for Analysis of Particles and Cells.") The method used is based upon acousto-optic principles of light diffraction. A vertically polarized 5-mW He-Ne laser is directed into an acousto-optic Bragg cell in which a portion of the incident light undergoes a small angular variation or deflection. Suitable optics focus the beam to a 25 microns diameter spot, at the 1/e2 point, in a sample cuvette while translating the angular variation into a linear scan. The cuvette enclosing the sample is slowly moved (approximately 1 micron/ms) via a stepper drive into the scanning beam while the forward angle light scatter sensor is monitored for the presence of valid signal events. When an event occurs, appropriate software optimizes the position of the focused laser beam onto the cell. Subsequently, scanning is stopped to allow for cell interrogation times that last for milliseconds or longer.     

A portable, microprocessor operated instrument for measuring chlorophyll fluorescence kinetics in stress physiology

A portable instrument for measuring chlorophyll fluorescence induction kinetics is described and examples of measurements are given. The instrument is centered around a statistically-mixed bifurcated optical fiber. One fiber branch guides the actinic light to the sample, whereas the other branch carries the emitted chlorophyll fluorescence to the photodetector. Scattered actinic light is cut out from the detector by a red interference filter. The instrument measures fast as well as slow fluorescence induction kinetics, but is particularly well designed for analyzing fast kinetics. The high time resolution and strong, variable actinic light mean that both F_o (non-variable fluorescence) and F_m (maximal fluorescence at the P-peak) are well defined. A built in microprocessor unit with attached memory stores the fluorescence induction curve and calculates key fluorescence parameters such as F_o, F_m, F_v (variable fluorescence equals F_m?F_o), F_v/F_m (the photochemical efficiency of photosystem II) and t_1/2 (half rise time from F_o, to F_m). These values are digitally displayed after each recording and they (or the whole induction curve) can be stored in a memory and later retrieved. Because of a flexible setting of the instrument it can be used with high accuracy both for optically thick leaves and for diluted suspensions of algae or chloroplasts. A simple, light weight clamp cuvette for dark adaptation of leaves has been developed. It is equipped with a gate allowing the optical fiber to be inserted without daylight reaching the dark adapted portion of the leaf. The instrument has been developed for rapid monitoring of changes in activities and organization of the photosynthetic apparatus in vivo when plants are exposed to environmental stress both in the field and in the laboratory. Examples of measurements are given for differently treated leaves of Pinus sylvestris, Salix sp., Betula verrucosa, Zea mays, Epilobium angustifo-lium and for chloroplast thylakoids isolated from Spinacia oleracea.     

A computerized spectrophotometric instrumental system to determine the "vertical velocity" of sperm cells: a novel concept.

BACKGROUND: The presently available cell motility-analyzers measure primarily the "horizontal" velocity and there is no instrument available for "vertical" velocity measurement. This development was based on the turbidimetric method of sperm motility analysis. METHODS: Sperm was layered at the bottom of the cuvette containing buffer solution and exposed to the spectrophotometric light path at different heights to track the vertically moving sperms. The vertical movement was materialized with the development of an electromechanical up-down movement devise for the cuvette accomplished with the help of a cuvette holder-stepper motor-computer assembly. The entire system was controlled by the necessary motion control, data acquisition, and data processing software developed for cuvette movement and data analysis. RESULTS: Using goat sperm as the model a unique computer-based spectrophotometric system has been developed for the first time to determine the average "vertical" velocity of motile cells. CONCLUSIONS: Undertaking upward movement against gravity is much tougher as compared with horizontal movement. Consequently average vertical velocity is expected to be a much better identifying parameter for assessing semen and other motile cell quality. The novel instrumental system developed by us has thus the potential for immense application in human infertility clinics, animal-breeding centres, centres for conservation of endangered species, and also for research work on vertical velocity of spermatozoa and other motile cells, such as bacteria, protozoa, etc.     

Design of flow chamber with electronic cell volume capability and light detection optics for multilaser flow cytometry

A multibeam optical detection system has been developed with a high optical efficiency, achieved through a reduction in the number of optical interfaces employed in the system. This reduction is made possible by a combination of employing simple lenses, gluing the objective lens directly upon the face of the flow cuvette and the extraction of only one fluorescence signal from each laser beam. A modified flow chamber is also described that includes fluidic resistance elements for the elimination of most of the electric shielding normally associated with electronic cell volume measurements.     

Violet laser diodes in flow cytometry: an update.

INTRODUCTION: In previous studies we and others have demonstrated the usefulness of violet laser diodes (VLDs) as replacement laser sources for krypton-ion lasers on stream-in-air cytometers. Previously available VLDs had a maximum available power of less than 25 mW; this was sufficient for excitation of densely labeled cell surface antigens using fluorochromes such as Cascade Blue or Pacific Blue, but may have been insufficient for applications requiring higher levels of photon saturation, such as low-level expression of Cyan Fluorescent Protein (ECFP) in CFP-YFP FRET applications. In this follow-up study, we have tested more powerful VLDs emitting at 55 mW, and a beam-merged dual module VLD with 100 mW combined output, for their ability to excite a variety of violet-excited fluorochromes, including CFP. METHODS: A dual module VLD (two linear polarized VLDs with their beams merged by a polarized beam combiner) emitting at 404 nm was mounted on a BD FACSVantage DiVa stream-in-air cytometer. The individual polarized 55 mW beams or the 100 mW combined beams were used to analyze PBMCs labeled with the violet-excited probes Cascade Blue, Alexa Fluor 405, Cascade Yellow and Pacific Orange dyes. Violet-excited fluorescent microsphere mixtures with decreasing fluorescence levels were also used to detect the minimum sensitivity threshold and precision of these lasers. VLD excitation on a gel-coupled cuvette flow cytometer was used as a sensitivity baseline. RESULTS: The dual module 100 mW VLD gave both sensitivity and precision levels approaching that observed for lower-power sources on a cuvette cytometer. Single polarized VLD modules at 55 mW gave slightly decreased sensitivity for the microspheres standards and all the tested fluorochromes compared to the 100 mW source. CONCLUSIONS: While 55 mW laser sources performed adequately in the stream-in-air format, increasing the power to 100 mW did give a small but detectable increase in instrument sensitivity. This sensitivity level approached that of cuvette systems.     

A simple method for determining the boundary layer resistance in leaf cuvettes

Abstract. A new method is described for determining the boundary layer resistance over wet filter paper exposed within a leaf cuvette, based on the energy balance of the filler paper. The boundary layer resistance is calculated by an iterative procedure from measurements of the relative humidity and temperature of the air in the cuvette. Comparisons between the new and the conventional method, involving measurement of the filter paper temperature, show close agreement.
To simplify the method further, a graph has been constructed for the relationship between boundary layer resistance and cuvette relative humidity at temperatures from 15 to 35°C, determined at one value of the ratio of the flow rate through the cuvette to the filter paper area.
An analysis of errors suggests that the new method is less sensitive than the conventional to errors in temperature and humidity.     

Preliminary results in the fluorometric investigation of fermentation processes

A flow cuvette for fluorescence exciting and measuring directly on the surface of fermentation broths was developed. Compared with the commonly used cuvette the disturbances by inhomogeneities of the samples and by the inner filter effect could be lowered to an appreciable extent.     

An instrument capable of imaging chlorophyll a fluorescence from intact leaves at very low irradiance and at cellular and subcellular levels of organization

An instrument capable of imaging chlorophyll a fluorescence, from intact leaves, and generating images of widely used fluorescence parameters is described. This instrument, which is based around a fluorescence microscope and a Peltier-cooled charge-coupled device (CCD) camera, differs from those described previously in two important ways. First, the instrument has a large dynamic range and is capable of generating images of chlorophyll a fluorescence at levels of incident irradiance as low as 0.1 μmol m^?2 s^?1. Secondly, chlorophyll fluorescence, and consequently photosynthetic performance, can be resolved down to the level of individual cells and chloroplasts. Control of the instrument, as well as image capture, manipulation, analysis and presentation, are executed through an integrated computer application, developed specifically for the task. Possible applications for this instrument include detection of early and differential responses to environmental stimuli, including various types of stress. Images illustrating the instrument's capabilities are presented.     

Co-immobilization of different enzyme activities to non-woven polyester surfaces

Co-immobilization was applied to combine complementary enzyme reactions. Therefore, trypsin was co-immobilized together with both, lipase and alpha-amylase, onto the surface of non-woven polyester material. The progress of the immobilization reaction was directly monitored by investigating covalent fixation of the enzymes to the polyester flees using (1)H-MAS-NMR. Co-immobilization of the different types of enzymes to the polyester support showed retained enzymatic activity. However, a competition of binding to the support was observed. Increasing amounts of one type of enzyme reduced the degree of immobilization for the other type. In order to investigate the distribution of trypsin and alpha-amylase on the polyester support, the flees was treated with a mixture of rhodamine isothiocyanate labeled with anti-trypsin antibodies and fluorescein isothiocyanate labeled with anti-alpha-amylase antibodies. Using fluorescence microscopy, the co-immobilization was analyzed by selective excitation of both chromophores at 480 and 530 nm, respectively. In addition, fluorescence spectroscopy was applied by direct labeling of trypsin and lipase prior to co-immobilization to the polyester support. A special prism of plexiglass was constructed, which fit into a 10 x 10 mm fluorescence cuvette in that way that a diagonal plane was formed within the cuvette. The non-woven support was fixed in the cuvette and fluorescence spectra were obtained to characterize the amount of different enzymes linked to the support. Using FRET it was demonstrated that a uniform distribution of the various enzyme species was achieved, where the different enzyme activities are bound on the support in close neighborhood to one another.     

Construction and evaluation of a frequency-domain epifluorescence microscope for lifetime and anisotropy decay measurements in subcellular domains

The measurement of time-resolved fluorescence parameters in living cells provides a powerful approach to study cell structure and dynamics. An epifluorescence microscope was constructed to resolve multi-component fluorescence lifetimes and complex anisotropy decay rapidly in labile biological samples. The excitation source consisted of focused, polarized laser light modulated by an impulse-driven Pockels' cell; parallel acquisition of phase angles and modulation amplitudes at more than 40 frequencies (5-250 MHz) was obtained by multi-harmonic cross-correlation detection. Lifetime decay was measured against standard solutions introduced into the light path proximal to the microscope objective. Anisotropy decay was measured by rotation of a Glan-Thompson polarizer in the emission path. Phase reference light was split from the beam proximal to the microscope. Optical components were selected to avoid depolarization and to optimize fluorescence detection efficiency. The dichoric was replaced by a 1 mm square mirror. Fitting routine statistics were optimized for model discrimination in realistic biological samples. Instrument performance was evaluated using fluorescein in H2O/glycerol and H2O/ethylene glycol mixtures and in Swiss 3T3 fibroblasts in monolayer culture. Objective depolarization effects were evaluated by measurement of anisotropy decay using objectives of different numerical aperture. Lifetime and anisotropy decay measured by microscopy (0.5 micron laser spot) agreed with data obtained by cuvette fluorimetry. New biological applications for time-resolved fluorescence microscopy are discussed.     

A new type of climatized gas exchange chamber for net photosynthesis and transpiration measurements in the field

Summary A temperature- and humidity-controlled plant chamber for CO₂ and H₂O exchange measurements in the field is described in which the heat exchanger assembly and humidity controlling water vapour trap are separated from the plant cuvette. The shape and construction material of the plant cuvette can vary according to the demands of the experimental conditions and the size and growth form of the plant. The natural illumination field is only slightly altered in this plant cuvette. In the chamber, the temperature and humidity conditions can either be held constant throughout a wide range of conditions or can be programmed to track ambient condition. In this manner, not only temperature and absolute humidity are replicated, but it is also possible to reproduce the natural conditions of water vapour gradient between the evaporating surfaces in the mesophyll and the atmosphere, the relative humidity of the air, and the temperature difference between the leaf and the ambient air. Thus, the chamber appears to be an appropriate instrument to investigate with sufficient accuracy the reactions of individual plants in cultivation or in natural communities under field conditions.     

Development of a streak-camera-based time-resolved microscope fluorimeter and its application to studies of membrane fusion in single cells

A time-resolved microscope fluorimeter based on a synchroscan streak camera and a fast pulsed laser system has been developed to measure the fluorescence lifetime decay under the fluorescence microscope. This system allows one to measure the nanosecond fluorescence lifetimes of fluorophores in a small spot (0.8-6.3 microns diameter) in single cultured cells under a fluorescence microscope, while the cells are being viewed under a high-power objective lens. A signal acquisition time between a second and a minute was usually sufficient to obtain fluorescence decay curves with good quality for 10(3)-10(5) fluorophores localized in 1 microns 2 domain. A signal-to-noise ratio better than 30 was obtained for approximately 30,000 fluorescein-labeled band 3 molecules in a 2 microns 2 region in a single human erythrocyte ghost after signal accumulation for 30 s. The measured lifetimes for a variety of fluorescent probes attached to proteins in solution and lipids in liposomes showed a good agreement with those measured in a cuvette under standard conditions by time-correlated single photon counting. With the development of this instrument, microscope fluorimetry has become a practical, straightforward, quantitative technique for investigation of molecular processes in single cells in culture. Time-resolved microscope fluorimetry has been applied to observe fusion of liposomes in vitro and that of endosomes in single cells by monitoring resonance energy transfer. Inspection of individual liposomes and endosomes revealed the extent of fusion for each vesicle. Since the use of time-resolved microscope fluorimetry eliminates the need for subcellular fractionation or the complex correction procedures in steady-state microfluorimetry, it greatly simplifies the assay for endosome fusion in vivo. The results showed that extensive fusion of sequentially formed endosomes takes place all over the cell matrix in cultured cells. This suggests that extensive fusion with incoming endosomes takes place in many endosomal compartments, possibly sorting organelles, or that the early endosomes fuse with the preexisting network of tubular cisternae of the endosomal compartment at many points in the network. It is concluded that time-resolved microscope fluorimetry is a powerful noninvasive technique for studies of in situ biochemistry and biophysics using cells and tissues.     

NADH and flavin fluorescence responses of starved yeast cultures to substrate additions

Model experiments were performed with starved yeast (Saccharomyces cerevisiae) cultures in a batch reactor in order to develop a better understanding of NAD(P)H and flavin culture fluorescence. Fluorescence was monitored during aerobic-anaerobic-aerobic transitions and ethanol and glucose substrate addition experiments. Interpretations of the fluorescence responses obtained are provided, with consideration given to redox compartmentation and the formation of ethanol shortly after a glucose addition. An analytical spectrofluorophotometer was interfaced to a personal computer and adapted to measure fluorescence in a bioreactor. This was achieved by the use of quartz fiber-optic waveguides to convert the right-angle cuvette geometry of the analytical spectrofluorophotometer to an open-ended fluorescence probe geometry, resulting in a flexible culture fluorescence apparatus. Features of the apparatus include variable excitation and emission wavelengths, allowing for detection of NAD(P)H or flavin fluorescence, as well as small slit widths, a variable sampling rate, excitation and emission scanning capabilities, and good sensitivity.     

A portable steady-state porometer for measuring the carbon dioxide and water vapour exchanges of leaves under natural conditions

A portable porometer is described for measuring the steady-state CO₂ and H₂O exchange rates of leaves under natural conditions. The porometer has an open gas exchange system which monitors the differences in concentrations of CO₂ and H₂O entering and leaving a cuvette which is clamped on or around leaves. The cuvette is designed to maintain ambient air temperature and humidity around the leaf. This instrument may also be used to determine CO₂ response curves in the field. Examples of diurnal courses are presented for attached leaves of different species having high and low rates of CO₂ exchange.     

Electrode and cuvette for rapid continuous CO2 tension and pH measurement in blood

An electrode and cuvette system has been developed for the continuous and rapid measurement of either blood CO2 tension or pH. The CO2 electrode consists of a 1.5-mm-diameter flat-tip glass pH electrode covered by a film of carbonic anhydrase solution, over which a 25-micron-thick dimethyl silicone membrane is attached. Porous ceramic filled with 20% polyacrylamide, equilibrated with a salt solution, serves as a salt bridge between a Ag-AgCl reference electrode and the pH electrode surface. The electrode is housed in a four-port cuvette assembly. Blood from a vessel of interest is delivered to the cuvette by means of an occlusive roller pump. The cuvette maintains the electrode and blood at a constant temperature and directs a continuous jet of blood against the electrode surface. The cuvette also allows for easy and frequent calibration of the electrode with either gas or liquid standards. The 90% response time of the CO2 electrode is 3.0 s for liquids and 1.3 s for gases. Removal of the dimethyl silicone membrane and carbonic anhydrase film yields a pH electrode that can continuously measure blood pH with a 90% response time of 1.6 s.     

Gold-coated capillary based 2,4-dichlorophenoxyacetic acid chemi-luminescent assays: possibilities towards multianalysis

The application of gold-coated glass capillaries for the design of a sensitive chemiluminescent immunoassay for 2,4-dichlorophenoxyacetic acid (2,4-D) is reported. The gold coating on the glass capillaries has been partially characterized and its effect on enhancing the signal intensity has been measured. A simple photo-multiplier tube-based photon detector is used for this purpose. At least three times improvement in the signal intensity is observed compared to uncoated glass capillaries, with a consequent improvement in the sensitivity of detection. Using such gold-coated glass capillaries, 2,4-D in the range 10(-9) to 10(-13) mol/l is detectable at a precision of +/-15% (CV%) and a limit of detection of 10(-15) mol/l is achievable. The possibility of using such gold-coated capillaries with a portable multianalytical set-up for field studies is also demonstrated.     

Enhanced separation and detection of serum bilirubin species by capillary electrophoresis using a mixed anionic surfactant—protein buffer system with laser-induced fluorescence detection

The four major bilirubin species in serum are separated by capillary electrophoresis and detected using laser-induced fluorescence detection. The optimum buffer system consists of 40 mM sodium dodecyl sulfate (SDS)—0.012 mM bovine serum albumin (BSA). The use of the SDS—BSA mixture in the mobile phase allows for the separation of four major bilirubin species at physiological pH with untreated capillaries. The results show that the use of BSA as a run buffer modifier in SDS solution improves separation efficiency and increases sample solubility via pH changes of the run buffer. The limits of detection for the bilirubin species using laser-induced fluorescence are between 30 and 150 nM, depending on the bilirubin species; not only is this approximately two orders of magnitude lower than with visible-light absorption methods, it allows the bilirubin species in normal sera to be quantitatively measured without sample pretreatment.     

数字PCR仪校准方法研究

数字PCR仪是核酸绝对定量的重要仪器,因此确保数字PCR仪检测结果的准确性十分重要。通过对国内市场上数字PCR仪的比较分析,剖析了数字PCR仪的性能指标,对数字PCR仪的校准方法进行了探讨,设定了拷贝数浓度相对示值误差、拷贝数浓度重复性、荧光通道一致性和反应单元个数重复性作为数字PCR仪整机校准的计量技术指标,采用具有溯源性的国家有证标准物质,对方法进行了试验验证。验证结果表明了校准思路和方法的可行性,该方法操作性强,能够满足仪器技术要求以及用户需求, 提高了数字PCR仪检测结果的准确性和可靠性,对进一步拓展和深化数字PCR 技术的应用具有积极的促进作用。     

Capillary gel electrophoresis for rapid, high resolution DNA sequencing.

Capillary gel electrophoresis has been demonstrated for the separation and detection of DNA sequencing samples. Enzymatic dideoxy nucleotide chain termination was employed, using fluorescently tagged oligonucleotide primers and laser based on-column detection (limit of detection is 6,000 molecules per peak). Capillary gel separations were shown to be three times faster, with better resolution (2.4 x), and higher separation efficiency (5.4 x) than a conventional automated slab gel DNA sequencing instrument. Agreement of measured values for velocity, resolution and separation efficiency with theory, predicts further improvements will result from increased electric field strengths (higher voltages and shorter capillaries). Advantages of capillary gel electrophoresis for automatic DNA sequencing instruments and for genomic sequencing are discussed.