In vivo imaging of human teeth and skin using real-time confocal microscopy

Confocal microscopy is currently being used to obtain images with higher lateral and axial resolution than conventional light microscopic techniques. Most current confocal microscopic applications describe the use of in vitro preparations. The tandem scanning microscope (TSM) can be applied in the in vivo microscopic evaluation of living tissue. This article discusses in vivo applications of the TSM in the study of human teeth and skin.     

The application of real-time confocal microscopy to the study of high-speed dental-bur-tooth-cutting interactions

A tandem scanning reflected light microscope (TSM) has been used to study the cutting interactions of dental burs with enamel. Confocal microscopy produces high-resolution images of subsurface structures in semi-transparent specimens such as teeth. The TSM has a real-time imaging ability which allows the visualization of the high-speed failure of a substrate which is being machined. This paper describes the criteria for successful imaging and their implementation in the design of a stage for controlling these cutting interactions. Examples of the results achieved are given and further applications for this technique in the field of biomaterials suggested.     

Intermediate aggregates resulting in the interaction of bile salt with liposomes studied by transmission electron microscopy and light scattering techniques

The interaction of sodium cholate (SC) with phosphatidylcholine liposomes was studied by means of transmission electron microscopy (TEM), changes in the mean particle size (quasielastic light scattering, QELS) and in the static light scattering (SLS) of the system during liposome solubilization. A good correlation was found between the TEM diameter of particles and the mean hydrodynamic diameter (HD) determined by QELS. The intermediate aggregates resulting in this interaction were dependent on the SC concentration in the system. Thus, an initial vesicle growth occurred when the SC concentration in the system was 13.79 mol%. Additional SC amounts (41.17 mol% SC) led to the formation of the largest vesicles (HD 410 nm). Increasing SC amounts led to a slight fall in the vesicle diameter and in the SLS of the system. Thus, for 47.08 mol% SC, TEM images still showed the presence of vesicles albeit with traces of smaller structures and signs of vesicle fusion. When SC concentration exceeded 48 mol% an abrupt decrease in SLS occurred, the size curve starting to show a bimodal distribution. Thus, for 50 mol% SC a sharp distribution curve appeared at 52 nm indicating the formation of small particles and TEM images showed clear signs of vesicle disintegration with formation of tubular structures. The subsequent self organization of these tubular structures (54 mol% SC) led to the formation of open multilayered structures in coexistence with small particles. A gradual increase in the number of these small particles (mixed micelles) led to the complete solubilization of liposomes.     

Pros and cons: cryo-electron microscopic evaluation of block faces versus cryo-sections from frozen-hydrated skin specimens prepared by different techniques

Over the last two decades, several different preparative techniques have been developed to investigate frozen‐hydrated biological samples by electron microscopy. In this article, we describe an alternative approach that allows either ultrastructural investigations of frozen human skin at a resolution better than 15 nm or sample throughput that is sufficiently high enough for quantitative morphological analysis. The specimen preparation method we describe is fast, reproducible, does not require much user experience or elaborate equipment. We compare high‐pressure freezing with plunge freezing, and block faces with frozen‐hydrated slices (sections), to study variations in cell thickness upon hydration changes. Plunge freezing is optimal for morphological and stereological investigations of structures with low water content. By contrast, high‐pressure freezing proved optimal for high‐resolution studies and provided the best ultrastructural preservation. A combination of these fast‐freezing techniques with cryo‐ultramicrotomy yielded well‐preserved block faces of the original biological material. Here we show that these block faces did not exhibit any of the artefacts normally associated with cryo‐sections, and – after evaporating a heavy metal and carbon onto the surface – are stable enough in the electron beam to provide high‐resolution images of large surface areas for statistical analysis in a cryo‐SEM (scanning electron microscope). Because the individual preparation steps use only standard equipment and do not require much experience from the experimenter, they are generally more usable, making this approach an interesting alternative to other methods for the ultrastructural investigation of frozen‐hydrated material.     

Cryo-electron diffraction as a tool to study local variations in the lipid organization of human stratum corneum

The human skin provides the body with a barrier against transepidermal water loss and the penetration of harmful agents (e.g. microbes) from outside. This barrier function is produced mainly by the outermost, nonviable layer of the epidermis, the stratum corneum (SC). The SC consists of terminally differentiated corneocytes surrounded by a continuous intercellular lipid domain, which contains mostly ceramides, cholesterol and free fatty acids. Small- and wide-angle X-ray diffraction studies have elucidated the lamellar and lateral lipid organizations in these domains. However, these techniques require bulk quantities of SC, as a result of which local structure information on the lipids cannot be obtained. Insights to these local lipid arrangements are important when new transdermal drug delivery systems have to be developed. Therefore, the technique of electron diffraction arose as a tool to study the lateral packing of the lipids in the intercellular domains of SC, locally. In a previous study, the suitability of electron diffraction was demonstrated using a lipid model system that resembled the lipid composition of the SC. The spacings calculated from the electron diffraction patterns were in good agreement with the spacings revealed by wide-angle X-ray diffraction. The results presented here succeed this previous study. We improved the microscope settings and developed a new preparation method to study ex vivo human SC by cryo-electron diffraction. The method is based on the conventional tape-stripping method and offers the possibility to study depth-related changes in the lipid organization of human SC. Diffraction patterns of both hexagonal and orthorhombic lipid lattices have been recorded with spacings that resembled those found in human SC by wide-angle X-ray diffraction. After lipid extraction, such diffraction patterns could no longer be detected in the samples.     

Applications of high-speed confocal imaging techniques in operative dentistry

All confocal scanning optical microscopes are suitable for making high-resolution images of many structures in teeth under near normal conditions. If the microscope can operate at high speed, then the number of applications widens considerably. The high-frame speed of the tandem scanning reflected light microscope (TSM) enables real-time examination of teeth in vivo, especially when the microscope is configured with a stabilising objective, featuring internal focusing elements. Experimental procedures examined microscopically on extracted teeth can include the cutting of the hard tissues, observation of fluid flow in dentine, the application of adhesives, and the fracturing of adhesive interfaces under load. Undertaking experiments where time is an important function has improved our knowledge of many of the materials/substrate interactions involved in dental operative procedures. Storing images on media other than video tape can be expensive, but reductions in the cost of computer memory is making digitisation and storage of images in real-time more widely available.     

Specialized scanning ion-conductance microscope for imaging of living cells

A specialized scanning ion conductance microscope (SICM) for imaging living cells has been developed from a conventional patch-clamp apparatus, which uses a glass micropipette as the sensitive probe. In contrast with other types of scanning probe microscope, the SICM probe has significant advantages for imaging living cells: it is most suitable for imaging samples immersed in water solutions; and since the probe senses ion current and does not need physical contact with the sample during the scan, any preliminary preparation of cells (fixation or adherence to a substrate) is unnecessary. We have successfully imaged murine melanocytes in growth medium. The microscope images the highly convoluted surface structures without damaging or deforming them, and reveals the true, three-dimensional relief of the cells. This instrument has considerable ability to operate, potentially simultaneously, in applications as diverse as real-time microscopy, electrophysiology, micromanipulation and drug delivery.     

Micromanipulation by laser microbeam and optical tweezers: from plant cells to single molecules

Complete manipulation by laser light allows precise and gentle treatment of plant cells, subcellular structures, and even individual DNA molecules. Recently, affordable lasers have become available for the construction of microbeams as well as for optical tweezers. This may generate new interest in these tools for plant biologists. Early experiments, reviewed in this journal, showed that laser supported microinjection of material into plant cells or tissues circumvents mechanical problems encountered in microinjection by fragile glass capillaries. Plant protoplasts could be fused with each other when under microscopical observation, and it was no major problem to generate a triple or quadruple fusion product. In the present paper we review experiments where membrane material was prepared from root hair tips and microgravity was simulated in algae. As many plant cells are transparent, it is possible to work inside living, intact cells. New experiments show that it is possible to release by optical micromanipulation, with high spatial resolutions, intracellular calcium from caged compounds and to study calcium oscillations. An example for avian cardiac tissue is given, but the technique is also suitable for plant cell research. As a more technical tool, optical tweezers can be used to spatially fix subcellular structures otherwise moving inside a cell and thus make them available for investigation with a confocal microscope even when the time for image formation is extended (for example at low fluorescence emission). A molecular biological example is the handling of chromosomes and isolated individual DNA molecules by laser microtools. For example, chromosomes can be cut along complex trajectories, not only perpendicular to their long axis. Single DNA molecules are cut by the laser microbeam and, after coupling such a molecule to a polystrene microbead, are handled in complex geometries. Here, the individual DNA molecules are made visible with a conventional fluorescence microscope by fluorescent dyes such as SYBRGreen. The cutting of a single DNA molecule by molecules of the restriction endonuclease EcoRI can be observed directly, i.e. a type of single molecule restriction analysis is possible. Finally, mechanical properties of individual DNA molecules can be observed directly.     

Multi-photon excitation microscopy in intact animals

Two‐photon excitation fluorescence microscopy and backscattered‐second harmonic generation microscopy permit the investigation of the subcellular events within living animals but numerous aspects of these experiments need to be optimized to overcome the traditional microscope geometry, motion and optical coupling to the subject. This report describes a stable system for supporting a living instrumented mouse or rabbit during endogenous reduced nicotinamide adenine dinucleotide and exogenous dye two‐photon excitation fluorescence microscopy measurements, and backscattered‐second harmonic generation microscopy measurements. The system was a modified inverted LSM510 microscope (Carl Zeiss, Inc., Thornwood, NY, U.S.A.) with a rotating periscope that converted the inverted scope to an upright format, with the objective located approximately, 15 cm from the centre of the microscope base, allowing easy placement of an instrumented animal. An Olympus 20× water immersion objective was optically coupled to the tissue, without a cover glass, via a saline bath or custom hydrated transparent gel. The instrumented animals were held on a specially designed holder that poised the animal under the objective as well as permitted different ventilation schemes to minimize motion. Using this approach, quality images were routinely collected in living animals from both the peripheral and body cavity organs. The remaining most significant issue for physiological studies using this approach is motion on the micrometre scale. Several strategies for motion compensation are described and discussed.     

Advances in phase‐sensitive acoustic microscopy studies of polymer blend films: annealing effects and micro‐elastic characterization of PS/PMMA blends

The unique phase‐sensitive acoustic microscope is used for the structural and mechanical characterization of thin films of polystyrene/polymethylmethacrylate blends. The effect of annealing on blends of polystyrene/polymethylmethacrylate spin coated from different solvents unto a substrate is studied. Varying the solvents according to vapour pressure and spin coating at different speeds (for thickness variation) led to changes in phase domain distributions and overall structural properties before annealing. Annealing in vacuum at 190°C for 48 h resulted in the elimination of solvent effects with all samples reverting to a similar morphology irrespective of common solvent and thickness. The Young's moduli at specific points on the film (E_polystyrene= 3.4 ± 0.3 GPa, E_{polymethylmethacrylate}= 4.2 ± 0.4 GPa) and over a given area (E_{polystyrene/polymethylmethacrylate}= 3.9 ± 0.4 GPa) were determined by combinatory use of the atomic force microscope and phase‐sensitive acoustic microscope. These results demonstrate a minimally invasive method for the quantitative characterization of polymer blend films.     

Application of differential interference contrast with inverted microscopes to the in vitro perfused nephron

The study of in vitro perfused individual nephron segments requires a microscope which provides: (1) easy access to the specimen for measurement of cellular solute flux and voltage; (2) an image with high resolution and contrast; (3) optical sectioning of the object at different levels; and (4) rapid recording of the morphological phenomena. This paper describes an example of commercially available apparatus meeting the above requirements, and illustrates its efficiency. The microscope is of the inverted type (Zeiss IM 35) equipped with differential-interference-contrast (DIC) with a long working distance, and an automatically controlled camera system. The microscopic image exhibits cellular and intercellular details in the unstained transporting mammalian nephron segments despite their tubular structure and great thickness and makes obvious function-structure correlations (e.g. cell volume changes); luminal and contraluminal cell borders are well resolved for controlled microelectrode impalement.     

High temporal and spatial resolution studies of bone cells using real-time confocal reflection microscopy

Chick and rat bone-derived cells were mounted in sealed coverslip-covered chambers; individual osteoclasts (but also osteoblasts) were selected and studied at 37°C using three different types of high-speed scanning confocal microscopes: (1) A Noran Tandem Scanning Microscope (TSM) was used with a low light level, cooled CCD camera for image transfer to a Noran TN8502 frame store-based image analysing computer to make time lapse movie sequences using 0.1 s exposure periods, thus losing some of the advantage of the high frame rate of the TSM. Rapid focus adjustment using computer controlled piezo drivers permitted two or more focus planes to be imaged sequentially: thus (with additional light-source shuttering) the reflection confocal image could be alternated with the phase contrast image at a different focus. Individual cells were followed for up to 5 days, suggesting no significant irradiation problem. (2) Exceptional temporal and spatial resolution is available in video rate laser confocal scanning microscopes (VRCSLMs). We used the Noran Odyssey unitary beam VRCSLM with an argon ion laser at 488 nm and acousto-optic deflection (AOD) on the line axis: this instrument is truly and adjustably confocal in the reflection mode. (3) We also used the Lasertec 1LM11 line scan instrument, with an He-Ne laser at 633 nm, and AOD for the frame scan. We discuss the technical problems and merits of the different approaches. The VRCSLMs documented rapid, real-time oscillatory motion: all the methods used show rapid net movement of organelles within bone cells. The interference reflection mode gives particularly strong contrasts in confocal instruments. Phase contrast and other interference methods used in the microscopy of living cells can be used simultaneously in the TSM.     

Computed tomography of cryogenic biological specimens based on X-ray microscopic images

Soft X-ray microscopy employs the photoelectric absorption contrast between water and protein in the 2.34-4.38 nm wavelength region to visualize protein structures down to 30 nm size without any staining methods. Due to the large depth of focus of the Fresnel zone plates used as X-ray objectives, computed tomography based on the X-ray microscopic images can be used to reconstruct the local linear absorption coefficient inside the three-dimensional specimen volume. High-resolution X-ray images require a high specimen radiation dose, and a series of images taken at different viewing angles is needed for computed tomography. Therefore, cryo microscopy is necessary to preserve the structural integrity of hydrated biological specimens during image acquisition. The cryo transmission X-ray microscope at the electron storage ring BESSY I (Berlin) was used to obtain a tilt series of images of the frozen-hydrated green alga Chlamydomonas reinhardtii. The living specimens were inserted into borosilicate glass capillaries and, in this first experiment, rapidly cooled by plunging into liquid nitrogen. The capillary specimen holders allow image acquisition over the full angular range of 180 degrees. The reconstruction shows for the first time details down to 60 nm size inside a frozen-hydrated biological specimen and conveys a clear impression of the internal structures. This technique is expected to be applicable to a wide range of biological specimens, such as the cell nucleus. It offers the possibility of imaging the three-dimensional structure of hydrated biological specimens close to their natural living state.     

Microscopic real time observation of failure, wear and deformation on coating/subsurface

The deposition of surface coatings on industrial component is widely used for reducing wear and friction in the tribological application. Tribological properties of various kinds of coatings have been systematically analyzed. This paper mainly deals with the investigation of failure mechanism of the coating/subsurface through the microscopic observation in real time through the repetition of sliding friction. The results of observations suggest that the mechanical failure is characterized by the intrinsic properties of coating and substrate materials, e.g. the relation between the thickness of coating and the depth of the plastically deformed region in the substrate. In the present study the microscopic real time observation is performed to investigate the failure of coating/subsurface by use of ‘frictional surface microscope system’, which is assembled by combining a metallographic microscope and a frictional device operated in the field of view of the microscope.     

Robust fluorescent labelling of micropipettes for use in fluorescence microscopy: application to the observation of a mosquito borne parasite infection

The ability to monitor micropipette injections with a high‐resolution fluorescent microscope has utility for a variety of applications. Herein, different approaches were tested for creating broad‐band fluorescently labelled glass micropipettes including: UV cured glass glues, baked glass enamel containing fluorescent dyes as well as nanodiamonds attached during pipette formation in the microforge. The most robust and simplest approach was to use labelled baked enamel on the exterior of the pipette. This approach was tested using pipettes designed to mimic a mosquito proboscis for the injection of the malaria parasite, Plasmodium spp., into the dermis of a living mouse ear. The pipette (～30 micron diameter) was easily detected in the microscopy field of view and tolerated multiple insertions through the skin. This simple inexpensive approach to fluorescently labelling micropipettes will aid in the development of procedures under the fluorescent microscope.     

Scanning force microscopy on live cultured cells: Imaging and force-versus-distance investigations

Extensive measurements with the scanning force microscope on living cells in their native liquid environment are described with the purpose of critically assessing the extent of the interaction between the SFM tip and the (soft) cell materials and the effect of such interaction on topographic information. Images are obtained under various force conditions and systematically correlated with force-versus-distance curves. As a result, detailed indications about tip indentation are given, thickness estimates deduced and identification of submembranous cytoplasmic structures suggested.     

Comparison of holotomographic microscopy and coherence-controlled holographic microscopy

Quantitative phase imaging (QPI) is a powerful tool for label-free visualisation of living cells. Here, we compare two QPI microscopes – the Telight Q-Phase microscope and the Nanolive 3D Cell Explorer-fluo microscope. Both systems provide unbiased information about cell morphology, such as individual cell dry mass, perimeter and area. The Q-Phase microscope uses artefact-free, coherence-controlled holographic imaging technology to visualise cells in real time with minimal phototoxicity. The 3D Cell Explorer-fluo employs laser-based holotomography to reconstruct 3D images of living cells, visualising their internal structures and dynamics. Here, we analysed the strengths and limitations of both microscopes when examining two morphologically distinct cell lines – the cuboidal epithelial MDCK cells which form multicellular clusters and solitary growing Rat2 fibroblasts. We focus mainly on the ability of the devices to generate images suitable for single-cell segmentation by the built-in software, and we discuss the segmentation results and quantitative data generated from the segmented images. We show that both microscopes offer slightly different advantages, and the choice between them depends on the specific requirements and goals of the user.     

Measurements of cells in culture by scanning acoustic microscopy

A novel method allowing the determination of thickness, attenuation and impedance of both living and fixed cells in culture using a single image recorded with a scanning acoustic microscope is described. The method is based on the recording of the image data locating the surface of the cell far below the geometric focus. In this way only the normal incident acoustic wave is used for image formation. Higher values of impedance and attenuation coefficients were found in the cell periphery than in the central part of the cell. This phenomenon is suggested to be due to the different organization of cytoskeletal elements.     

Real time two-photon absorption microscopy using multi point excitation

In this communication we present the development of a real time two-photon absorption microscope, based on parallel excitation with many foci. This pattern of foci is created by a two-dimensional microlens array. The fluorescence is detected by direct, non descanned detection on a CCD camera. Due to the parallel nature of both excitation and detection it is possible to speed up image acquisition significantly. This makes the instrument especially suitable for studying living specimens and/or real time processes. The optical design of the instrument is discussed and an imaging example is given. We specifically address the relation between the axial sectioning capability and the distance between the illumination foci at the sample.     

水介质对超声空蚀纳米生成物形貌的影响

为探究水介质下超声空蚀纳米结构的生成机制,研究不同水介质条件下超声空蚀纳米生成物的形貌特征。利用超声振动空蚀实验装置,在4种不同水介质中分别对45钢样品进行超声空蚀实验,通过激光共聚焦显微镜、扫描电子显微镜对实验后样品表面空蚀纳米生成物形貌进行分析。结果表明:45钢在不同水介质中空蚀生成的纳米微结构有很大差异;在去离子水和Na Cl溶液中空蚀坑环状区域纳米结构呈现为不规则絮状结构,在自来水和Na₂SO₄溶液中生成的空蚀坑周围形成了纳米多层片状结构;在自来水中,随着超声时间的增加,纳米单层片状结构先是长度方向尺寸增大,后逐渐叠加成纳米多层片状结构,总厚度增大。45钢在自来水中超声空蚀生成的纳米多层片状结构的尺寸,与实验时间和介质中离子有关,源于空蚀-腐蚀耦合作用产生;自来水中的SO₄^2-等离子也为片状纳米层间的组装起到促进作用。