Microscopic optical projection tomography in vivo

We describe a versatile optical projection tomography system for rapid three-dimensional imaging of microscopic specimens in vivo. Our tomographic setup eliminates the in xy and z strongly asymmetric resolution, resulting from optical sectioning in conventional confocal microscopy. It allows for robust, high resolution fluorescence as well as absorption imaging of live transparent invertebrate animals such as C. elegans. This system offers considerable advantages over currently available methods when imaging dynamic developmental processes and animal ageing; it permits monitoring of spatio-temporal gene expression and anatomical alterations with single-cell resolution, it utilizes both fluorescence and absorption as a source of contrast, and is easily adaptable for a range of small model organisms.     

Correlative Stochastic Optical Reconstruction Microscopy and Electron Microscopy

Correlative fluorescence light microscopy and electron microscopy allows the imaging of spatial distributions of specific biomolecules in the context of cellular ultrastructure. Recent development of super-resolution fluorescence microscopy allows the location of molecules to be determined with nanometer-scale spatial resolution. However, correlative super-resolution fluorescence microscopy and electron microscopy (EM) still remains challenging because the optimal specimen preparation and imaging conditions for super-resolution fluorescence microscopy and EM are often not compatible. Here, we have developed several experiment protocols for correlative stochastic optical reconstruction microscopy (STORM) and EM methods, both for un-embedded samples by applying EM-specific sample preparations after STORM imaging and for embedded and sectioned samples by optimizing the fluorescence under EM fixation, staining and embedding conditions. We demonstrated these methods using a variety of cellular targets.     

Looking and listening to light: the evolution of whole-body photonic imaging

Optical imaging of live animals has grown into an important tool in biomedical research as advances in photonic technology and reporter strategies have led to widespread exploration of biological processes in vivo. Although much attention has been paid to microscopy, macroscopic imaging has allowed small-animal imaging with larger fields of view (from several millimeters to several centimeters depending on implementation). Photographic methods have been the mainstay for fluorescence and bioluminescence macroscopy in whole animals, but emphasis is shifting to photonic methods that use tomographic principles to noninvasively image optical contrast at depths of several millimeters to centimeters with high sensitivity and sub-millimeter to millimeter resolution. Recent theoretical and instrumentation advances allow the use of large data sets and multiple projections and offer practical systems for quantitative, three-dimensional whole-body images. For photonic imaging to fully realize its potential, however, further progress will be needed in refining optical inversion methods and data acquisition techniques.     

Optical microscopy in photosynthesis

Emerging as well as the most frequently used optical microscopy techniques are reviewed and image contrast generation methods in a microscope are presented, focusing on the nonlinear contrasts such as harmonic generation and multiphoton excitation fluorescence. Nonlinear microscopy presents numerous advantages over linear microscopy techniques including improved deep tissue imaging, optical sectioning, and imaging of live unstained samples. Nonetheless, with the exception of multiphoton excitation fluorescence, nonlinear microscopy is in its infancy, lacking protocols, users and applications; hence, this review focuses on the potential of nonlinear microscopy for studying photosynthetic organisms. Examples of nonlinear microscopic imaging are presented including isolated light-harvesting antenna complexes from higher plants, starch granules, chloroplasts, unicellular alga Chlamydomonas reinhardtii, and cyanobacteria Leptolyngbya sp. and Anabaena sp. While focusing on nonlinear microscopy techniques, second and third harmonic generation and multiphoton excitation fluorescence microscopy, other emerging nonlinear imaging modalities are described and several linear optical microscopy techniques are reviewed in order to clearly describe their capabilities and to highlight the advantages of nonlinear microscopy.     

光学技术在早期龋齿检测中的应用

介绍了光学技术在口腔医学早期龋齿无损检测领域的应用,包括基于牙齿自体荧光效应的定量光导荧光技术和激光龋齿检测技术;基于光散射效应的数字化显影光纤透照术,以及基于牙釉质双折射效应的偏振敏感光学相干断层术和偏振拉曼光谱技术.详细介绍了各种光学方法应用于龋齿检测的基本原理、实验方案和研究现状,并对不同的光学方法进行比较.最后,提出基于频域荧光寿命成像的早期龋齿检测方法,并对该方案的技术路线进行了介绍.     

Monomolecular multimodal fluorescence-radioisotope imaging agents

Diagnosis of diseases by different imaging methods can provide complementary information about the functional status of diseased tissues or organs. To overcome the current difficulties in coregistering images from different imaging modalities with a high degree of accuracy, we prepared near-infrared (NIR) monomolecular multimodal imaging agents (MOMIAs) consisting of a heptamethine carbocyanine and 111In-DOTA chelate that served as antennae for optical and scintigraphic imaging, respectively. Their spectral properties clearly show that coordination of indium to MOMIA increased the fluorescence intensity of the compounds. The MOMIAs are exceptionally stable in biological media and serum up to 24 h at 37 degrees C. Biodistribution of the compounds in mice obtained by fluorescence photon and gamma-counts demonstrated a similar distribution trend of the molecular probe in different tissues, suggesting that the detected fluorescence and gamma-emissions emanated from the same source (MOMIA). At 24 h postinjection, the MOMIAs were excreted by the renal and hepatobiliary systems and the blood level of a representative MOMIA was very low, thereby reducing background noise caused by circulating molecular probes. These findings demonstrate the feasibility of preparing single molecules with the capacity to emit discernible and diagnostic fluorescent and gamma-radiations for optical and nuclear imaging of living organisms.     

Optical and digital microscopic imaging techniques and applications in pathology

The conventional optical microscope has been the primary tool in assisting pathological examinations. The modern digital pathology combines the power of microscopy, electronic detection, and computerized analysis. It enables cellular-, molecular-, and genetic-imaging at high efficiency and accuracy to facilitate clinical screening and diagnosis. This paper first reviews the fundamental concepts of microscopic imaging and introduces the technical features and associated clinical applications of optical microscopes, electron microscopes, scanning tunnel microscopes, and fluorescence microscopes. The interface of microscopy with digital image acquisition methods is discussed. The recent developments and future perspectives of contemporary microscopic imaging techniques such as three-dimensional and in vivo imaging are analyzed for their clinical potentials.     

Achieving Molecular Selectivity in Imaging Using Multiphoton Raman Spectroscopy Techniques

In the case of most optical imaging methods, contrast is generated either by physical properties of the sample (Differential Image Contrast, Phase Contrast), or by fluorescent labels that are localized to a particular protein or organelle. Standard Raman and infrared methods for obtaining images are based upon the intrinsic vibrational properties of molecules, and thus obviate the need for attached fluorophores. Unfortunately, they have significant limitations for live-cell imaging. However, an active Raman method, called Coherent Anti-Stokes Raman Scattering (CARS), is well suited for microscopy, and provides a new means for imaging specific molecules. Vibrational imaging techniques, such as CARS, avoid problems associated with photobleaching and photo-induced toxicity often associated with the use of fluorescent labels with live cells. Because the laser configuration needed to implement CARS technology is similar to that used in other multiphoton microscopy methods, such as two-photon fluorescence and harmonic generation, it is possible to combine imaging modalities, thus generating simultaneous CARS and fluorescence images. A particularly powerful aspect of CARS microscopy is its ability to selectively image deuterated compounds, thus allowing the visualization of molecules, such as lipids, that are chemically indistinguishable from the native species.     

Optical sectioning microscopy

Confocal scanning microscopy, a form of optical sectioning microscopy, has radically transformed optical imaging in biology. These devices provide a powerful means to eliminate from images the background caused by out-of-focus light and scatter. Confocal techniques can also improve the resolution of a light microscope image beyond what is achievable with widefield fluorescence microscopy. The quality of the images obtained, however, depends on the user's familiarity with the optical and fluorescence concepts that underlie this approach. We describe the core concepts of confocal microscopes and important variables that adversely affect confocal images. We also discuss data-processing methods for confocal microscopy and computational optical sectioning techniques that can perform optical sectioning without a confocal microscope.     

Determination of optimal rhodamine fluorophore for in vivo optical imaging

Optical imaging has the potential to improve the efficacy of surgical and endoscopic approaches to cancer treatment; however, the optimal type of fluorescent probe has not yet been established. It is well-known that rhodamine-core-derived fluorophores offer a combination of desirable properties such as good photostability, high extinction coefficient, and high fluorescence quantum yield. However, despite the ubiquitous use of rhodamine fluorophores for in vivo optical imaging, it remains to be determined if unique chemical properties among individual rhodamine core family members affect fluorophore parameters critical to in vivo optical imaging applications. These parameters include preserved fluorescence intensity in low pH environments, similar to that of the endolysosome; efficient fluorescence signal despite conformational changes to targeting proteins as may occur in harsh subcellular environments; persistence of fluorescence after cellular internalization; and sufficient signal-to-background ratios to permit the identification of fluorophore-targeted tumors. In the present study, we conjugated 4 common rhodamine-core based fluorescent dyes to a clinically feasible and quickly internalizing D-galactose receptor targeting reagent, galactosamine serum albumin (GmSA), and conducted a series of in vitro and in vivo experiments using a metastatic ovarian cancer mouse model to determine if differences in optical imaging properties exist among rhodamine fluorophores and if so, which rhodamine core possesses optimal characteristics for in vivo imaging applications. Herein, we demonstrate that the rhodamine-fluorophore, TAMRA, is the most robust of the 4 common rhodamine fluorophores for in vivo optical imaging of ovarian cancer metastases to the peritoneum.     

Comparison of X-ray fluorescence and optical fluorescence measured behind scattering layers as a basis for X-ray fluorescence endoscopy.

Recent developments in the technology of capillary-fiber optics suitable for X-rays in the range of approximately 4-10keV point to the possible realization of endoscopes applicable in X-ray fluorescence analysis. A general problem is the determination of scattering and absorption processes with consideration to tissue optics, X-ray scattering and X-ray absorption in a diagnostic partial volume. Therefore comparative investigations were performed in order to answer these questions. Zinc-oxide nanoparticles configured as single particles and ZnO clusters provided the fluorescence source in cell layers. An artificial scattering material was employed, which closely approximated the tissue optical conditions and the X-ray optical application conditions in possible diagnostic situations. As a result imaging of spatially resolved X-ray contrasts was better than adequate optical fluorescence imaging by approximately one magnitude. Hence a very important precondition for realizing X-ray fluorescence endoscopy is fulfilled.     

Near-field optical imaging of abasic sites on a single DNA molecule

Scanning near-field optical microscopy (SNOM) imaging was performed to allow for the direct visualization of damaged sites on individual DNA molecules to a scale of a few tens of nanometers. Fluorescence in situ hybridization on extended DNA molecules was modified to detect a single abasic site. Abasic sites were specifically labelled with a biotinlylated aldehyde-reactive probe and fluorochrome-conjugated streptavidin. By optimizing the performance of the SNOM technique, we could obtain high contrast near-field optical images that enabled high-resolution near-field fluorescence imaging using optical fiber probes with small aperture sizes. High-resolution near-field fluorescence imaging demonstrated that two abasic sites within a distance of 120 nm are clearly obtainable, something which is not possible using conventional fluorescence in situ hybridization combined with far-field fluorescence microscopy.     

分子生物光子学的进展

随着分子生物学和标记技术的进步,光学成像和分析有了很快的发展,无论是从理论上还是应用上都有所突破,展现了良好的前景。本文综述了近年来在分子生物探测中光子学的情况,简介了几种突破光学衍射极限的探测方法,着重阐明了与生化技术密切相关的荧光共振能量转移和荧光相关光谱显微术及其在分子生物学中的应用。     

Multiphoton microscopy for the in-situ investigation of cellular processes and integrity in cryopreservation

In this study we demonstrate a new noninvasive imaging method to monitor freezing processes in biological samples and to investigate life in the frozen state. It combines a laser scanning microscope with a computer-controlled cryostage. Nearinfrared (NIR) femtosecond laser pulses evoke the fluorescence of endogenous fluorophores and fluorescent labels due to multiphoton absorption.The inherent optical nonlinearity of multiphoton absorption allows 3D fluorescence imaging for optical tomography of frozen biological material in-situ. As an example for functional imaging we use fluorescence lifetime imaging (FLIM) to create images with chemical and physical contrast.     

Optical detection of synaptic vesicle exocytosis and endocytosis.

Recent advances in optical methods have catalyzed a detailed study of individual visualized synapses in several model systems. Quantal events at small central synapses, as well as single granule exocytosis in secretory cells, have been detected using quantitative fluorescence imaging. Sensitive detection of exocytosis and endocytosis at individual synapses has advanced our knowledge of synaptic vesicle trafficking.     

荧光成像技术及其在生命科学中的应用

近年来,荧光成像技术发展迅速,其成像系统通常为目前最先进的分析检测仪器之一的激光共聚焦显微镜,荧光探针是荧光成像技术的核心之一。作为新兴光学成像技术,荧光成像技术在生命科学领域中应用广泛,可用于蛋白质及金属离子检测,肿瘤疾病的诊断,并为药物新剂型的研究提供了新思路。     

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.     

间充质干细胞双标记光学成像的体内试验研究

目的:验证双标记生物发光成像活体观测MSCs在肝癌裸鼠模型向肿瘤病灶的趋化作用的可行性。方法:应用fluorescence(荧光)与bioluminescence(生物发光)两种成像方法,对MSCs进行CM-Di I荧光标记及对人肝癌细胞Hep G2进行Fluc-慢病毒感染并由此建立裸鼠肝癌模型,构建双标记成像系统,应用精诺真小动物光学成像仪在裸鼠肝癌模型中观测间充质干细胞向肿瘤的趋化作用。结果:在鼠尾静脉注射标记MSCs细胞后21天荧光成像可见MSCs主要积聚于肿瘤病灶处及肝脏。生物发光成像后可监测到病灶处由luciferase标记肿瘤细胞(Hep G2)发出荧光;将荧光成像与生物发光成像所得图像经后处理融合后,可见证间充质干细胞像肿瘤病灶定向迁徙的生物过程。经肿瘤病理切片证实间充质干细胞成功迁徙至肿瘤病灶中。结论:应用间充质干细胞双标记光学成像系统实现MSCs在活体内对肿瘤的趋化过程进行观测是可行的。这种成像方法可作为下一步以MSCs为载体的肿瘤基因治疗的有效监测手段。