激光共焦显微成像的最新进展及其在生命科学研究中的应用

激光扫描共聚焦显微镜近年来得到了迅速发展,是近代最先进的细胞生物医学分析仪器之一。通过它可以对观察样品进行无创断层扫描和成像,在生物学和医学研究诊断的各个方面都得到了广泛的应用。本文主要介绍了激光扫描共焦显微镜的基本原理和发展状况,并着重介绍了在共焦荧光显微镜中采用薄荧光层和切片成像特性图来表征成像状态的功能。这种方法一般用于表征共聚焦和多光子显微镜的成像特性,是比较显微镜切片成像条件、成像质量等相关性能的重要依据。     

Confocal microscopy via reciprocal optical fibre image detection

We describe a compact form of confocal scanning microscope using a semiconductor laser. Confocal operation is ensured by the use of a single mode optical fibre for both launching the light into the microscope and collecting the signal from the object. The collected light is allowed to re-enter the laser and the image is detected as a modulation on the signal from the laser power monitor diode. Images are compared with those obtained from traditional point detectors. The alignment tolerances of the reciprocal scheme are found to be greatly reduced over conventional confocal systems.     

Construction of a confocal microscope for real-time x-y and x-z imaging

We describe the construction of a simple 'real-time' laser-scanning confocal microscope, and illustrate its use for rapid imaging of elementary intracellular calcium signaling events. A resonant scanning galvanometer (8 kHz) allows x-y frame acquisition rates of 15 or 30 Hz, and the use of mirrors to scan the laser beam permits use of true, pin-hole confocal detection to provide diffraction-limited spatial resolution. Furthermore, use of a piezoelectric device to rapidly focus the objective lens allows axial (x-z) images to be obtained from thick specimens at similar frame rates. A computer with image acquisition and graphics cards converts the output from the microscope to a standard video signal, which can then be recorded on videotape and analyzed by regular image processing systems. The system is largely made from commercially available components and requires little custom construction of mechanical parts or electronic circuitry. It costs only a small fraction of that of comparable commercial instruments, yet offers greater versatility and similar or better performance.     

Confocal images of marrow stromal (Westen-Bainton) cells

A cytochemical method was used for imaging a defined subset of marrow stromal cells (alkaline phosphatase-positive reticulum cells, hereinafter referred to as Westen-Bainton cells), which are endowed with membrane-associated alkaline phosphatase. The use of two different types of confocal microscopes was compared: a tandem scanning reflected light microscope and a laser scanning confocal microscope equipped with a 633 nm (helium-neon) laser. Sharp confocal reflection images of the cytochemically stained stromal cells were obtained with both microscopes. Three-dimensional reconstructions were generated with both systems, revealing morphological features of Westen-Bainton cells related to both their actual shape and organization within tissue architecture, which were not otherwise appreciated. The observations were extended to individual cases of bone pathology, and demonstrated the value of confocal microscopy for the investigation of marrow-bone relationships in physiology and disease.     

Confocal scanning optical microscopy and three-dimensional imaging

Summary— Confocal scanning optical microscopy has significant advantages over conventional fluorescence microscopy: it rejects the out-of-locus light and provides a greater resolution than the wide-field microscope. In laser scanning optical microscopy, the specimen is scanned by a diffraction-limited spot of laser light and the fluorescence emission (or the reflected light) is focused onto a photodetector. The imaged point is then digitized, stored into the memory of a computer and displayed at the appropriate spatial position on a graphic device as a part of a two-dimensional image. Thus, confocal scanning optical microscopy allows accurate non-invasive optical sectioning and further three-dimensional reconstruction of biological specimens. Here we review the recent technological aspects of the principles and uses of the confocal microscope, and we introduce the different methods of three-dimensional imaging.     

Imaging of calcium wave propagation in guinea-pig ventricular cell pairs by confocal laser scanning microscopy.

We describe here the use of a confocal laser scanning microscope for imaging fast dynamic changes of the intracellular calcium ion concentration ([Ca2+]i) in isolated ventricular cell pairs. The scanning apparatus of our system, paired galvanometer mirrors, can perform narrow band scanning of an area of interest at a high temporal resolution of less than 70 msec per image. The actual [Ca2+]i is obtained directly through the fluorescence intensity of injected fluo-3, which responds to changes of [Ca2+]i in optically sectioned unit volumes of the cell. Images of the calcium wave obtained during propagation between paired cells revealed that the wavefront is constant in shape and propagates at constant velocity without any delay at the cell-to-cell junction. The confocal laser scanning microscope with depth-discriminating ability is a valuable tool for taking pictures of the sequence of biological events in living cells.     

Alkaline phosphatase cytochemistry in confocal scanning light microscopy for imaging the bone marrow stroma

This paper reports on the use of alkaline phosphatase cytochemistry and combined conventional and confocal reflection and fluorescence scanning light microscopic modes in the study of human marrow stroma. It was found that the end product of the enzyme reaction using Napthol AS phosphate as substrate and Fast Blue BB as coupler reflected the 633 nm (red) light from a Helium-Neon laser. Serial optical sections suitable for 3-D reconstruction and selectively depicting the marrow reticulum cells could be obtained from thick glycol methacrylate sections reacted for Alkaline phosphatase. Furthermore, the yellow background of uncoupled diazonium salt over cytochemically unreactive structures in the same specimens and fields was used for imaging haemopoietic cell mass by operating the microscope at 488 nm (argon ion laser, blue-green). These methods may offer advantages in the investigation of the bone marrow stroma and its interplay with haemopoiesis and osteogenesis in normal and disease conditions.     

激光扫描共聚焦显微镜活细胞成像方法优化

激光扫描共聚焦显微镜可用于固定样品和活细胞样品的成像,近年来得到了广泛的应用。本文介绍了激光扫描共聚焦显微镜的基本原理及其在活细胞成像中的应用,并以FV10-ASW Viewer4.2软件为例,从扫描速度、分辨率、降噪、光电倍增调节、多参数协同优化、成像质量评估、图像后期处理等多个角度总结了激光扫描共聚焦活细胞成像系统的方法优化和推荐参数设置。本文的工作可以为活细胞实验提供一定参考。     

Slicing embryos gently with laser light sheets

Light sheet microscopy is an easy to implement and extremely powerful alternative to established fluorescence imaging techniques such as laser scanning confocal, multi-photon and spinning disk microscopy. By illuminating the sample only with a thin slice of light, photo-bleaching is reduced to a minimum, making light sheet microscopy ideal for non-destructive imaging of fragile samples over extended periods of time. Millimeter-sized samples can be imaged rapidly with high resolution and high depth penetration. A large variety of instruments have been developed and optimized for a number of different samples: Bessel beams form thin light sheets for single cells, and selective plane illumination microscopy (SPIM) offers multi-view acquisition to image entire embryos with isotropic resolution. This review explains how light sheet microscopy involves a conceptually new microscope design and how it changes modern imaging in biology.     

Imaging aspects of cardiovascular disease at the cell and molecular level

Cell and molecular imaging has a long and distinguished history. Erythrocytes were visualized microscopically by van Leeuwenhoek in 1674, and microscope technology has evolved mightily since the first single-lens instruments, and now incorporates many types that do not use photons of light for image formation. The combination of these instruments with preparations stained with histochemical and immunohistochemical markers has revolutionized imaging by allowing the biochemical identification of components at subcellular resolution. The field of cardiovascular disease has benefited greatly from these advances for the characterization of disease etiologies. In this review, we will highlight and summarize the use of microscopy imaging systems, including light microscopy, electron microscopy, confocal scanning laser microscopy, laser scanning cytometry, laser microdissection, and atomic force microscopy in conjunction with a variety of histochemical techniques in studies aimed at understanding mechanisms underlying cardiovascular diseases at the cell and molecular level.     

利用转盘共聚焦显微镜进行快速实验的新方法

转盘共聚焦显微镜是快速激光共聚焦显微镜的一种,与传统的激光共聚焦显微镜相比具有一些相同点,也有其特有的优势。本文主要介绍转盘共聚焦显微镜的基本原理及如何利用转盘共聚焦显微镜进行快速实验及应用实例,并与传统激光共聚焦显微镜进行比较。转盘共聚焦显微镜具有速度快、灵敏度高、对样品光损伤和光淬灭程度低、操作灵活简单,是随着实验技术发展使用越来越广泛的实验仪器。     

Confocal laser scanning microscopy

Many technological advancements of the past decade have contributed to improvements in the photon efficiency of the confocal laser scanning microscope (CLSM). The resolution of images from the new generation of CLSMs is approaching that achieved by the microscope itself because of continued development in digital imaging methods, laser technology and the availability of brighter and more photostable fluorescent probes. Such advances have made possible novel experimental approaches for multiple label fluorescence, live cell imaging and multidimensional microscopy.     

Principles and practices of laser scanning confocal microscopy

The laser scanning confocal microscope (LSCM) is an essential tool for many biomedical imaging applications at the level of the light microscope. The basic principles of confocal microscopy and the evolution of the LSCM into today's sophisticated instruments are outlined. The major imaging modes of the LSCM are introduced including single optical sections, multiple wavelength images, three-dimensional reconstructions, and living cell and tissue sequences. Practical aspects of specimen preparation, image collection, and image presentation are included along with a primer on troubleshooting the LSCM for the novice.     

激光共聚焦显微镜与光学显微镜之比较

激光扫描共聚焦显微镜在活细胞的动态检测、光学切片和三维结构重建等方面较光学显微镜有质的飞跃。本文对激光扫描共聚焦显微镜和光学显微镜进行了比较和讨论,并简单介绍多光子激光扫描显微镜。     

Fluorescence and confocal laser scanning microscopy imaging of elastic fibers in hematoxylin-eosin stained sections

 We have studied the possibility of associating fluorescence microscopy and hematoxylin-eosin staining for the identification of elastic fibers in elastin-rich tissues. Elastic fibers and elastic laminae were consistently identified by the proposed procedure, which revealed itself to be easy and useful for the determination of such structures and their distribution. The fluorescence properties of stained elastic fibers are due to eosin staining as revealed by fluorescence analysis of the dye in solution, with no or only minor contribution by the elastin auto-fluorescence. The main advantage of this technique resides in the possibility of studying the distribution of elastic fibers in file material without further sectioning and staining. The use of the confocal laser scanning microscope greatly improved the resolution and selectivity of imaging elastic fibers in different tissues. The determination of the three-dimensional distribution and structure of elastic fiber and laminae using the confocal laser scanning microscope was evaluated and also produced excellent results. Accepted: 28 August 1996     

延迟荧光分析和激光共聚焦技术在检测非洲菊发育过程中表皮细胞叶绿素变化中的应用

以非洲菊Gerberahybrida为研究对象,对其生长发育过程（P1．P6期）中外轮舌状花进行延迟荧光（delayedfluorescence,DF）分析,并利用激光共聚焦成像系统对其各期表皮细胞中叶绿素的分布和相对含量进行检测,以研究非洲菊外轮舌状花发育过程中延迟荧光改变与其叶绿素变化的关系。结果发现在非洲菊外轮舌状花从P1到P6期颜色由嫩绿色变为绿色再逐渐变为金黄色的过程中,其荧光强度变化是先升高后降低。激光共聚焦成像结果表明,其花瓣表皮细胞中叶绿素的相对含量从P1到P4期先是逐渐增多,而后从P4到P6期逐渐减少。到后期只是在保卫细胞中还能观察到叶绿素的存在。实验结果表明应用DF技术,可以有效、无损伤地快速检测非洲菊花瓣中叶绿素的相对含量,结合荧光光谱分析以及激光共聚焦扫描显微成像技术,研究花瓣在发育过程中的叶绿素降解情况。     

Localization and high-resolution imaging of cortical neurotransmitter compartments using confocal laser scanning microscopy: GABA and glutamate interactions in rat cortex.

This report compares the application of confocal laser scanning fluorescence microscopy with standard epifluorescence microscopy for the simultaneous localization of the neurotransmitters gamma-aminobutyric acid and glutamate in rat cerebral cortex. With this approach, sections of fixed rat brain are treated with primary antibodies against gamma-aminobutyric acid (rabbit-derived) and glutamate (mouse-derived), followed by treatment with fluorescein isothiocyanate-tagged donkey anti-rabbit and rhodamine-tagged goat anti-mouse secondary antibodies, respectively. The results demonstrate that images from immunofluorescence localizations with a confocal laser scanning microscope have superior resolution and contrast as a result of significant reductions of background flare caused by emission from out-of-focus structures in the field of view. The confocal microscope achieves this improved image quality by optically sectioning through a specimen at narrow planes of focus and then compiling a composite image of an object of interest. The composite image can be further enhanced by using various image processing options. The combined use of double immunofluorescence and confocal laser scanning microscopy provides an important means to simultaneously study the anatomical relationships of pre- and post-synaptic elements in a complex neural system.     

Fluorescence Microscopy Gets Faster and Clearer: Roles of Photochemistry and Selective Illumination

Significant advances in fluorescence microscopy tend be a balance between two competing qualities wherein improvements in resolution and low light detection are typically accompanied by losses in acquisition rate and signal-to-noise, respectively. These trade-offs are becoming less of a barrier to biomedical research as recent advances in optoelectronic microscopy and developments in fluorophore chemistry have enabled scientists to see beyond the diffraction barrier, image deeper into live specimens, and acquire images at unprecedented speed. Selective plane illumination microscopy has provided significant gains in the spatial and temporal acquisition of fluorescence specimens several mm in thickness. With commercial systems now available, this method promises to expand on recent advances in 2-photon deep-tissue imaging with improved speed and reduced photobleaching compared to laser scanning confocal microscopy. Superresolution microscopes are also available in several modalities and can be coupled with selective plane illumination techniques. The combination of methods to increase resolution, acquisition speed, and depth of collection are now being married to common microscope systems, enabling scientists to make significant advances in live cell and in situ imaging in real time. We show that light sheet microscopy provides significant advantages for imaging live zebrafish embryos compared to laser scanning confocal microscopy.     

Video-rate scanning two-photon excitation fluorescence microscopy and ratio imaging with cameleons

A video-rate (30 frames/s) scanning two-photon excitation microscope has been successfully tested. The microscope, based on a Nikon RCM 8000, incorporates a femtosecond pulsed laser with wavelength tunable from 690 to 1050 nm, prechirper optics for laser pulse-width compression, resonant galvanometer for video-rate point scanning, and a pair of nonconfocal detectors for fast emission ratioing. An increase in fluorescent emission of 1.75-fold is consistently obtained with the use of the prechirper optics. The nonconfocal detectors provide another 2.25-fold increase in detection efficiency. Ratio imaging and optical sectioning can therefore be performed more efficiently without confocal optics. Faster frame rates, at 60, 120, and 240 frames/s, can be achieved with proportionally reduced scan lines per frame. Useful two-photon images can be acquired at video rate with a laser power as low as 2.7 mW at specimen with the genetically modified green fluorescent proteins. Preliminary results obtained using this system confirm that the yellow "cameleons" exhibit similar optical properties as under one-photon excitation conditions. Dynamic two-photon images of cardiac myocytes and ratio images of yellow cameleon-2.1, -3.1, and -3.1nu are also presented.     

Measuring and interpreting point spread functions to determine confocal microscope resolution and ensure quality control

This protocol outlines a procedure for collecting and analyzing point spread functions (PSFs). It describes how to prepare fluorescent microsphere samples, set up a confocal microscope to properly collect 3D confocal image data of the microspheres and perform PSF measurements. The analysis of the PSF is used to determine the resolution of the microscope and to identify any problems with the quality of the microscope's images. The PSF geometry is used as an indicator to identify problems with the objective lens, confocal laser scanning components and other relay optics. Identification of possible causes of PSF abnormalities and solutions to improve microscope performance are provided. The microsphere sample preparation requires 2-3 h plus an overnight drying period. The microscope setup requires 2 h (1 h for laser warm up), whereas collecting and analyzing the PSF images require an additional 2-3 h.