眼底视网膜色素上皮层细胞脂褐素及氧化黑色素自体荧光寿命成像研究

利用一种基于时间相关单光子计数器的双光子激发荧光寿命显微成像技术，对猪眼底视网膜色素上皮层细胞内的脂褐素和氧化黑色素颗粒的空间分布及其荧光寿命特性进行了研究，尤其对于这些色素颗粒在光致氧化环境中的荧光寿命差异进行了分析.结果表明，利用荧光寿命测量能有效区分视网膜色素上皮层细胞中的多组分荧光团，利用荧光寿命的衰减参数可分辨正常及异常的荧光现象.该方法有望发展成为一种用于眼科临床诊断及病理学研究的高灵敏度的工具，对眼底细胞随年龄增长的衰老机理的研究具有重要的意义.     

Fluorescence lifetime imaging of oxygen in living cells

The usefulness of the fluorescent probe ruthenium tris(2,2′-dipyridyl) dichloride hydrate (RTDP) for the quantitative imaging of oxygen in single cells was investigated utilizing fluorescence lifetime imaging. The results indicate that the fluorescence behavior of RTDP in the presence of oxygen can be described by the Stem-Volmer equation. This shows that fluorescence quenching by oxygen is a dynamic quenching process. In addition, it was demonstrated that the fluorescence lifetime of RTDP is insensitive to pH, ion concentration, and cellular contents. This implies that a simple calibration procedure in buffers can be used to quantify oxygen concentrations within cells. First fluorescence imaging experiments on J774 macrophages show a nonuniform fluorescence intensity and a uniform fluorescence lifetime image. This indicates that the RTDP is heterogeneously partitioned throughout the cells, while the oxygen concentration is constant.     

Fluorescence lifetime imaging of intracellular calcium

Fluorescence lifetime imaging microscopy (FLIM) is a new methodology for studying the spatial and temporal dynamics of macromolecule, molecules, and ions in living cells. In FLIM image contrast is derived from the mean fluorescence lifetime at each point in a two-dimensional image. In our case the lifetime was measured by the phase-modulation method. We describe our FLIM apparatus, which consists of a fluorescence microscope, high-speed gated proximity focused MCP image intensifier, and slow-scan CCD camera. To accomplish subnanosecond time-resolved imaging, the gain of the image intensifier is modulated with a high-frequency signal, resulting in stationary phase-sensitive intensity images on the image intensifier. These images are recorded using a cooled slow-scan CCD camera and stored in an image processor. The lifetime images are created from a series of phase-sensitive images at various phase shift of the gain-modulation signal. We demonstrate calcium concentration imaging in living COS cells based on Ca²⁺-induced lifetime changes of Quin-2. The phase-angle image is mapped to the Ca²⁺ concentration image using anin vitro-determined calibration curve. The Ca²⁺ concentration was found to be uniform throughout the cell. In contrast, the intensity image shows significant spatial differences, which likely reflect variations in the thickness and distribution of probe within the cell.     

长时程双光子成像技术

双光子成像(Two-Photon Imaging)技术以其优越特性被广泛用于活细胞动态三维成像,但光功率极高的短脉冲光对焦平面荧光分子严重的光漂白极大地影响了双光子长时间成像的图像质量,针对双光子荧光漂白问题,本文提出一种优化光照的双光子(Optimized Lighting-Two Photon,OL-TP)成像技术。通过预扫描获取双光子图像分析高低阈值,以预设的高低阈值为标准优化一幅图像中不同区域的光照时长,利用扫描过程中记录的荧光信息和光照时间信息可以重建OL-TP图像,既保证信噪比又降低荧光漂白。重建的OL-TP图像与传统双光子图像基本一致,信噪比略有降低,但图像并未失真。对110 nm的荧光小球样本分别连续取30幅普通双光子和优化光照的双光子图像,到第30幅图时,重建后的优化光照双光子图像比普通双光子图像荧光漂白降低了28.86%。OL-TP通过优化光照时间大幅降低双光子成像的荧光漂白,使双光子荧光显微镜能够更好地对生物样本进行长时间观测。     

双光子激发钠分子荧光寿命的测量

本文研究了钠分子高位三重态荧光寿命的测量方法。利用倍频晶体模拟等频双光子激发过程和对荧光衰变曲线求卷积的数值计算方法。有效地消除了测量仪器响应函数的影响,测量了Na_2高位三重态2~3∏_g→a~3∑_u~+的荧光寿命。     

Fluorescence lifetime distributions in membrane systems

Membranes are complex biological systems that display heterogeneity at all spatial scales. At a molecular level, the heterogeneity arises from lipid and protein composition. At the cellular level, heterogeneity is due to membrane organization and large scale morphology. A quantitative evaluation of membrane heterogeneity at a microscopic level is very important for several fields of membrane studies. We have developed a method for the analysis of the decay of fluorescent membrane probes that can provide a quantity sensitive to membrane heterogeneity. This method is based on the analysis of the fluorescence decay using continuous lifetime distributions. The major challenge in the interpretation of the analysis results is in the identification, at a molecular level, of the mechanisms that influence the fluorescence decay. In this review we illustrate the principles of data analysis and we show examples of identification of the measured parameters with specific variables that affect membrane heterogeneity.     

Fluorescence lifetime characterization of magnesium probes: Improvement of Mg2+ dynamic range and sensitivity using phase-modulation fluorometry

We measured the Mg²⁺-dependent absorption spectra, emission spectra, quantum yields, and intensity decays of most presently available fluorescent magnesium probes. The lifetimes were found to be strongly Mg²⁺ dependent for Mag-quin-1, Mag-quin-2, magnesium green, and magnesium orange and increased 2- to 10-fold upon binding of Mg²⁺. The lifetimes of Mag-fura-2, Mag-fura-5, Mag-fura red, and Mag-indo-1 were similar in the presence and absence of Mg²⁺. Detailed timeresolved measurements were carried out for Mag-quin-2 and magnesium green using phase-modulation fluorometry. Apparent dissociation constants (K _d) were determined from the steady-state and time-resolved data. Their values were compared and discussed. Mg²⁺ sensing is described using phase and modulation data measured at a single modulation frequency. Phase angle and modulation data showed the possibility of obtaining a wider Mg²⁺-sensitive range than available from intensity measurements. A significant expansion in the Mg²⁺-sensitive range was found for Mag-quin-2 using excitation wavelengths from 343 to 375 nm, where the apparentK _d from the phase angle was found to vary from 0.3 to about 100 mM. Discrimination against Ca²⁺ was also measured for Mag-quin-2 and magnesium green. Significant phototransformation and/or photode-composition, which affect the sensitivity to Mg²⁺, were observed for Mag-quin-2 and magnesium green under intense and long illumination.     

时域两维荧光寿命显微测量研究

提出了一种新的时域两维荧光寿命显微测量技术,建立了一套荧光寿命成像显微系统,介绍了这种测量技术的数据处理方法。用标准样品对该系统进行了测试,实验表明,该系统的时间分辨率为2ps,在放大倍率为100倍的情况下,该系统的空间分辨率为8um。如果在现有的设备下采用更细的网格板和微位移系统,那么该系统的空间分辨率可小于1um.     

血卟啉和核黄素荧光寿命的测量

本文选用了波长为1.054μm的磷酸盐钕玻璃锁模激光器输出的单个PS激光脉冲,经KDP晶体倍频后的绿光(λ=0.527μm)做激发光源。用条纹相机测定了血卟琳、核黄素有机生物大分子的激发单态S_1的寿命。并就氧分子的猝灭效应对寿命的影响进行了初步讨论。     

Calcium imaging using fluorescence lifetimes and long-wavelength probes

We describe imaging of calcium concentrations using the long-wavelength Ca²⁺ indicators, Calcium Green, Orange, and Crimson. The lifetimes of these probes were measured using the frequency-domain method and were found to increase from 50% to severalfold in response to calcium. The two-dimensional images of the calcium concentration were obtained using a new apparatus for fluorescence lifetime imaging (FLIM). We also describe procedures to correct for the position-dependent frequency response of the gain-modulated image intensifier used in the FLIM apparatus. Importantly, the FLIM method does not require the probe to display shifts in the excitation or emission spectra. Using the FLIM method, calcium imaging is possible using probes which display changes in lifetime in response to calcium. Consequently, calcium imaging is possible with excitation wavelengths ranging from 488 to as long as 620 nm, where autofluorescence and/or photochemical damage is minimal. These probes are also suitable for calcium measurements of single cells using lifetime-based flow cytometry.     

Frequency-domain fluorescence lifetime imaging for endoscopic clinical cancer photodetection: Apparatus design and preliminary results

We describe a new fluorescence imaging device for clinical cancer photodetection in hollow organs in which the tumor/normal tissue contrast is derived from the fluorescence lifetime of endogenous or exogenous fluorochromes. This fluorescence lifetime contrast gives information about the physicochemical properties of the environment which are different between normal and certain diseased tissues. The excitation light from a CW laser is modulated in amplitude at a radio frequency by an electrooptical modulator and delivered by an optical fiber through an endoscope to the hollow organ. The image of the tissue collected by the endoscope is separated in two spectral windows, one being the backscattered excitation light and the other the fluorescence of the fluorochrome. Each image is then focused on the photocathode of image intensifiers (II) whose optical gain is modulated at the same frequency as the excitation intensity, resulting in homodyne phase-sensitive images. By acquiring stationary phase-sensitive frames at different phases between the excitation and the detection, it is possible to calculate in quasi-real time the apparent fluorescence lifetime of the corresponding tissue region for each pixel. A result obtained by investigating the endogenous fluorochromes present in the mucous membrane of an excised human bladder is presented to illustrate this method and most of the optical parameters which are of major importance for this photodetection modality have been evaluated.     

应用小波边缘检测技术分析荧光寿命显微像

研究了小波图象边缘检测技术在荧光寿命显微像分析中的应用，利用小波分析的多尺度特性进行了荧光寿命显微像的边缘提取，结果表明，这种方法非常有效。     

眼底视网膜色素上皮层细胞脂褐素及氧化黑色素自体荧光寿命成像研究

利用一种基于时间相关单光子计数器的双光子激发荧光寿命显微成像技术,对猪眼底视网膜色素上皮层细胞内的脂褐素和氧化黑色素颗粒的空间分布及其荧光寿命特性进行了研究,尤其对于这些色素颗粒在光致氧化环境中的荧光寿命差异进行了分析.结果表明,利用荧光寿命测量能有效区分视网膜色素上皮层细胞中的多组分荧光团,利用荧光寿命的衰减参数可分辨正常及异常的荧光现象.该方法有望发展成为一种用于眼科临床诊断及病理学研究的高灵敏度的工具,对眼底细胞随年龄增长的衰老机理的研究具有重要的意义.关键词：双光子激发荧光荧光寿命成像视网膜色素上皮层     

Polystyrene Microspheres in Tissue-Simulating Phantoms Can Collisionally Quench Fluorescence

Tissue-simulating phantoms that replicate intrinsic optical properties in a controlled manner are useful for quantitative studies of photon transport in turbid biological media. In such phantoms, polystyrene microspheres are often used to simulate tissue optical scattering. Here, we report that using polystyrene microspheres in fluorescent tissue-simulating phantoms can reduce fluorophore quantum yield via collisional quenching. Fluorescence lifetime spectroscopy was employed to characterize quenching in phantoms consisting of a fluorescein dye and polystyrene microspheres (scattering coefficients _s 100-600cm^–1). For this range of tissue-simulating phantoms, analysis using the Stern-Volmer equation revealed that collisional quenching by polystyrene microspheres accounted for a decrease in fluorescence intensity of 6-17% relative to the intrinsic intensity value when no microspheres (quenchers) were present. The intensity decrease from quenching is independent of additional, anticipated losses arising from optical scattering associated with the microspheres. These results suggest that quantitative fluorescence measurements in studies employing such phantoms may be influenced by collisional quenching.     

Recent developments in monitoring calcium and protein interactions in cells using fluorescence lifetime microscopy

Time-resolved fluorescence lifetime microscopy (TRFLM) allows the combination of the sensitivity of fluorescence lifetime to environmental parameters to be monitored in a spatial manner in single living cells, as well as providing more accurate, sensitive, and specific diagnosis of certain clinical diseases and chemical analyses. Here we discuss two applications of TRFLM: (1) the use of nonratiometric probes such as Calcium Crimson, for measuring Ca²⁺; and (2) quantification of protein interaction in living cells using green and blue fluorescent protein (GFP and BFP, respectively) expressing constructs in combination with fluorescence resonance energy transfer microscopy (FRET). With respect to measuring Ca²⁺ in biological samples, we demonstrate thatintensity-based measurements of Ca²⁺ with single-wavelength Ca²⁺ probes such as Calcium Crimson may falsely report the actual Ca²⁺ concentration. This is due to effects of hydrophobicity of the local environment on the emission of Calcium Crimson as well as interaction of Calcium Crimson with proteins, both of which are overcome by the use of TRFLM. The recent availability of BFP (P4-3) and GFP (S65T) (which can serve as donor and acceptor, respectively) DNA sequences which can be attached to the carboxy-or amino-terminal DNA sequence of specific proteins allows the dual expression and interaction of proteins conjugated to BFP and GFP to be monitored in individual cells using FRET. Both of these applications of TRFLM are expected to enhance substantially the information available regarding both the normal and the abnormal physiology of cells and tissues.     

激光诱导荧光寿命及其测量

激光诱导荧光特性的研究可用于包括心血管病在内的多种疾病的诊断。荧光发射包括光谱（频域）和时间（时域）两方面的信息，后者表现为荧光寿命。在很多情况下，测量荧光寿命是比测量光谱更为有效的诊断方法。本文从理论上讨论了荧光寿命问题，并介绍两种测量方法，可用于测量人体正常组织和病变组织的激光诱导荧光寿命     

Video fluorescence microscopic techniques to monitor local lipid and phospholipid molecular order and organization in cell membranes during hypoxic injury

Digitized video microscopy is rapidly finding uses in a number of fields of biological investigation because it allows quantitative assessment of physiological functions in intact cells under a variety of conditions. In this review paper, we focus on the rationale for the development and use of quantitative digitized video fluorescence microscopic techniques to monitor the molecular order and organization of lipids and phospholipids in the plasma membrane of single living cells. These include (1) fluorescence polarization imaging microscopy, used to measure plasma membrane lipid order, (2) fluorescence resonance energy transfer (FRET) imaging microscopy, used to detect and monitor phospholipid domain formation, and (3) fluorescence quenching imaging microscopy, used to spatially map fluid and rigid lipid domains. We review both the theoretical as well as practical use of these different techniques and their limits and potential for future developments, and provide as an illustrative example their application in studies of plasma membrane lipid order and topography during hypoxic injury in rat hepatocytes. Each of these methods provides complementary information; in the case of hypoxic injury, they all indicated that hypoxic injury leads to a spatially and temporally heterogeneous alteration in lipid order, topography, and fluidity of the plasma membrane. Hypoxic injury induces the formation of both fluid and rigid lipid domains; the formation of these domains is responsible for loss of the plasma membrane permeability barrier and the onset of irreversible injury (cell death). By defining the mechanisms which lead to alterations in lipid and phospholipid order and organization in the plasma membrane of hypoxic cells, potential sites of intervention to delay, prevent, or rescue cells from hypoxic injury have been identified. Finally, we briefly discuss fluorescence lifetime imaging microscopy (FLIM) and its potential application for studies monitoring local lipid and phospholipid molecular order and organization in cell membranes.     

Direct Observation of Lipid Domains in Free-Standing Bilayers Using Two-Photon Excitation Fluorescence Microscopy

The direct observation of temperature-dependent lipid phase equilibria, using two-photon excitation fluorescence microscopy on giant unilamellar vesicles (GUVs) composed of different lipid mixtures, provides novel information about the physical characteristics of lipid domain coexistence. Physical characteristics such as the shape, size, and time evolution of different lipid domains are not directly accessible from the traditional experimental approaches that employ either small and large unilamellar vesicles or multilamellar vesicles. In this review article, we address the most relevant findings reported from our laboratory regarding the direct observation of lipid domain coexistence at the level of single vesicles in artificial and natural lipid mixtures. In addition, key points concerning our experimental approach will be discussed. The unique advantages of the fluorescent probe 6-dodecanoyl-2-dimethylaminonaphthalene (LAURDAN) under two-photon excitation fluorescence microscopy is particularly addressed, especially, the possibility of obtaining information on the phase state of different lipid domains directly from the fluorescent images.     

Improved Routine Bio-Medical and Bio-Analytical Online Fluorescence Measurements Using Fluorescence Lifetime Resolution

Fluorescence techniques are widely used as sensitive detection methods in bio-analytics. The use of the bio-physical parameter fluorescence lifetime additional to the spectral characteristics of fluorescence has the potential to improve fluorescence-related detection methods in terms of selectivity in signal recognition, robustness against disturbing influences, and the accessibility of novel bio-chemical process parameters. This article describes the technical set up of a time-resolving instrument with either a fixed time-gated detection principle for improved evaluation of tissue metabolism by an online monitoring of the tissue autofluorescence or a direct fluorescence lifetime detection principle for lifetime-based fluorescent assays.