Computerized quantification of tissue vascularization using high-resolution slide scanning of whole tumor sections.

Assessment of tissue vascularization using immunohistochemical techniques for microvessel detection has been limited by difficulties in generating reproducible quantitative data. The distinction of individual blood vessels and the selection of microscopic fields to be analyzed remain two factors of subjectivity. In this study, we used imaging analysis software and a high-resolution slide scanner for measurement of CD31-immunostained endothelial area (EA) in whole sections of human neuroblastoma xenograft and murine mammary adenocarcinoma tumors. Imaging analysis software provided objective criteria for analysis of sections of different tumors. The use of the criteria on images of entire tumor section acquired with the slide scanner constituted a rapid method to quantify tumor vascularization. Compared with previously described methods, the "hot spot" and the "random fields" methods, EA measurements obtained with our "whole section scanning" method were more reproducible with 8.6% interobserver disagreement for the "whole section scanning" method vs 42.2% and 39.0% interobserver disagreement for the "hot spot" method and the "random fields," respectively. Microvessel density was also measured with the whole section scanning method and provided additional data on the distribution and the size of the blood vessels. Therefore, this method constitutes a time efficient and reproducible method for quantification of tumor vascularization.     

Automation of mouse micronucleus genotoxicity assay by laser scanning cytometry

BACKGROUND: The evaluation of the safety of drugs and other chemicals is an important aspect of toxicology work. The mouse micronucleus assay is a standard in vivo genotoxicity assay. Chromosomal damage is an indicator of genotoxicity, which manifests in the formation of micronuclei in polychromatic erythrocytes from bone marrow and in peripheral blood erythrocytes. The assay is laborious to perform by manual counting. The laser scanning cytometer allows automated and rapid quantitation of cellular and subcellular fluorescence in monodisperse cell samples on a microscope slide. The object of this study was to evaluate the application of this new technology in the mouse micronucleus genotoxicity assay. Materials and Methods One hundred forty-four mice of various strains were dosed with combinations of carcinogens and antioxidants. Duplicate blood films were prepared 3 days later. One set of slides was stained with acridine orange, and the proportion of micronucleated erythrocytes was counted in 5,000 cells per slide. The duplicates were stained with propidium iodide (40 microg/ml). Five thousand cells per sample were examined using a laser scanning cytometer. The proportion of micronucleated erythrocytes was measured. RESULTS: A coefficient of correlation of 0.96 was found between the data from the two assays. The automation of the assay on the LSC produced a considerable time saving and efficiency gain. CONCLUSIONS: We conclude that with further development, laser scanning cytometry is likely to become the preferred modality for the performance of standard genotoxicity assays.     

Detection of glucagon in pancreatic A-cells by monoclonal antibodies

The production of a mouse monoclonal antibody from a hybrid myeloma and its use for the detection of glucagon in tissue sections is reported. The hybrid clone isolated after fusion of mouse myeloma cells with hyperimmune spleen cells from a mouse previously immunized with porcine glucagon allowed us a standardized and permanent source of monoclonal antibodies in a culture cell system. The monoclonal antibody (3 GL 31) specifically reacts with pancreatic A-cells in several species including pig, rabbit, tupaia belangeri and sheep. No immunoreactivity is observed against gut cells and neurons.     

Staining method for whole-body autoradiography.

Sagittal whole-body sections of frozen mice were cut on a hydraulicly driven microtome in a cryostat at--15 C by applying cotton or nylon-backed adhesive tape to the mouse before cutting. Section thickness was 20 mu. The sections, still adhering to the tape, were dried in the cryostat (-15C) under atmospheric pressure. After autoradiography, the sections were pressed to a glass slide spread with a mixture of albumin and glycerin. The slide was immersed in xylene at 30 C for 15 min. The tape was then removed from the slide, where the section remained to be stained with hematoxylin-eosin. The section thus obtained enabled the tissue histology to be related to the autoradiogram. This method may also be applied to histochemical studies of substances insoluble in xylene.     

Detection of glucagon in pancreatic A-cells by monoclonal antibodies

Summary The production of a mouse monoclonal antibody from a hybrid myeloma and its use for the detection of glucagon in tissue sections is reported. The hybrid clone isolated after fusion of mouse myeloma cells with hyperimmune spleen cells from a mouse previously immunized with poreine glucagon allowed us a standardized and permanent source of monoclonal antibodies in a culture cell system. The monoclonal antibody (3 GL 31) specifically reacts with pancreatic A-cells in several species including pig, rabbit, tupaia belangeri and sheep. No immunoreactivity is observed against gut cells and neurons.Supported by the Deutsche Forschungsgemeinschaft, Carvas SFB 90     

A relationship between slide quality and image quality in whole slide imaging (WSI)

This study examined the effect of tissue section thickness and consistency--parameters outside the direct control of the imaging devices themselves--on WSI capture speed and image quality. Preliminary data indicates that thinner, more consistent tissue sectioning (such as those produced by automated tissue sectioning robots) results in significantly faster WSI capture times and better image quality. A variety of tissue types (including human breast, mouse embryo, mouse brain, etc.) were sectioned using an (AS-200) Automated Tissue Sectioning System (Kurabo Industries, Osaka Japan) at thicknesses from 2 - 9 microm (at one microm intervals) and stained with H&E by a standard method. The resulting slides were imaged with 5 different WSI devices (ScanScope CS, Aperio, CA; iScan, BioImagene, CA; DX40, DMetrix, AZ; NanoZoomer, Hamamatsu Photonics K.K., Japan; Mirax Scan, Carl Zeiss Inc., Germany) with sampling periods of 0.43 - 0.69 microm/pixel. Slides with different tissue thicknesses were compared for image quality, appropriate number of focus points, and overall scanning speed. Thinner sections (i.e. 3 microm sections versus 7 microm) required significantly fewer focus points and had significantly lower (10-15%) capture times. Improvement was seen with all devices and tissues tested. Furthermore, a panel of experienced pathologist judged image quality to be significantly better (for example, with better apparent resolution of nucleoli) with the thinner sections. Automated tissue sectioning is a very new technology; however, the AS-200 seems to be able to produce thinner, more consistent, flatter sections than manual methods at reasonably high throughput. The resulting tissue sections seem to be easier for a WSI system's focusing systems to deal with (compared to manually cut slides). Teaming an automated tissue-sectioning device with a WSI device shows promise in producing faster WSI throughput with better image quality.     

From bedside to bench to clinic trials: identifying new treatments for severe asthma

Asthmatics with a severe form of the disease are frequently refractory to standard medications such as inhaled corticosteroids, underlining the need for new treatments to prevent the occurrence of potentially life-threatening episodes. A major obstacle in the development of new treatments for severe asthma is the heterogeneous pathogenesis of the disease, which involves multiple mechanisms and cell types. Furthermore, new therapies might need to be targeted to subgroups of patients whose disease pathogenesis is mediated by a specific pathway. One approach to solving the challenge of developing new treatments for severe asthma is to use experimental mouse models of asthma to address clinically relevant questions regarding disease pathogenesis. The mechanistic insights gained from mouse studies can be translated back to the clinic as potential treatment approaches that require evaluation in clinical trials to validate their effectiveness and safety in human subjects. Here, we will review how mouse models have advanced our understanding of severe asthma pathogenesis. Mouse studies have helped us to uncover the underlying inflammatory mechanisms (mediated by multiple immune cell types that produce Th1, Th2 or Th17 cytokines) and non-inflammatory pathways, in addition to shedding light on asthma that is associated with obesity or steroid unresponsiveness. We propose that the strategy of using mouse models to address clinically relevant questions remains an attractive and productive research approach for identifying mechanistic pathways that can be developed into novel treatments for severe asthma.     

RELMα可通过抑制PTEN信号通路来促进气道重塑并增加炎症反应

本研究旨在考察抵抗素样分子-α(resistin-like molecule-α,RELMα)在哮喘小鼠模型和小鼠肺上皮细胞中的表达及对气道重塑和炎症反应的影响。本研究通过卵清蛋白(ovalbumin,OVA)诱导小鼠哮喘模型,并评估了小鼠肺组织中RELMα、collagen I和fibronectin-1的表达。为了研究RELMα对PTEN信号通路的调控作用,本研究利用shRNA-RELMα、pcDNA3.0-RELMα和pcDNA3.0-PTEN转染小鼠肺上皮细胞系TC-1来上调或下调RELMα及PTEN的表达。通过Western blotting检测了TC-1细胞中RELMα、collagenⅠ、fibronectin-1、PTEN、TNF-α、IL-1β和IL-6的表达。研究发现,与对照小鼠相比,OVA致敏的哮喘小鼠的肺组织中RELMα、collagen I和fibronectin-1的表达显著升高。上调RELMα可显著升高collagenⅠ、fibronectin-1、TNF-α、IL-1β和IL-6的表达并抑制PTEN信号通路的活化。上调PTEN则可抑制collagenⅠ、fibronectin-1、TNF-α、IL-1β和IL-6的表达。本研究表明,RELMα在哮喘发病过程中高表达,上调RELMα可抑制PTEN信号通路来促进气道重塑并增加炎症反应。     

Immunohistochemical detection of <Emphasis Type="Italic">Mycobacterium tuberculosis</Emphasis> in tissues of consumptives using laser scanning microscopy

A simple and reliable method for detection of Mycobacterium tuberculosis (MBT) in histological specimens of lung tissue of consumptives using obtained anti-MBT polyclonal antibodies and laser scanning confocal microscopy was proposed. The method detected both colonies and single MBT and localized intraand extracellularly in caseous necrosis areas and perifocal regions. It was noted that automatic image capture of a large amount of tissue (up to 2 × 2 × 0.1 mm) and subsequent combination of optical sections in a threedimensional image provided the opportunity to carry out automated search and counting of MBT in tissues. Registration of the emission spectrum was allowed separating specific signals from nonspecific fluorescence in specimens.     

Von Kossa's Method for Renal Mineralization: Application for Multiple Specimens Using Capillary Gap Technology

Mineralization of renal tissue was investigated using Von Kossa's method and capillary gap technology. Combining these techniques allowed the simultaneous processing of 100 slides, reduced the volume of 5% silver nitrate required, and produced consistent dark brown to black silver deposits in positive control sections. A 25-fold savings in silver nitrate was achieved. By markedly reducing individual slide handling, technician time also was greatly reduced. Two or three slide sets, each containing approximately 100 slides, can be conveniently stained daily.     

Serial Sections; Simplified Handling of Paraffin Ribbons on a Floating-Out Bath

Pieces of para & ribbon containing serial sections are arranged in overlapping rows on a microscope slide coated with albumen or glycerol. The assembly of sections is then floated free by immersing the slide in a bath of warm water. The rows of sections forming the assembled unit adhere to each other along their overlapping edges. After the sections have softened and expanded, the unit is picked up on a slide, covered with wet filter paper, rolled flat with a photographic print roller, and allowed to dry.     

Genetic labeling of neuronal subsets through enhancer trapping in mice

The ability to label, visualize, and manipulate subsets of neurons is critical for elucidating the structure and function of individual cell types in the brain. Enhancer trapping has proved extremely useful for the genetic manipulation of selective cell types in Drosophila. We have developed an enhancer trap strategy in mammals by generating transgenic mice with lentiviral vectors carrying single-copy enhancer-detector probes encoding either the marker gene lacZ or Cre recombinase. This transgenic strategy allowed us to genetically identify a wide variety of neuronal subpopulations in distinct brain regions. Enhancer detection by lentiviral transgenesis could thus provide a complementary method for generating transgenic mouse libraries for the genetic labeling and manipulation of neuronal subsets.     

Imaging of cell surface antigens on tumor lymph-node sections using fluorescence quantum dots

In this work we explored the potential of quantum dots for fluorescent detection of lymphoid surface antigens. To optimize detection with quantum dots, we upgraded a fluorescent microscope that allowed us obtaining multiple images from different quantum dots on a single section. Specimens stained with quantum dots remained stable over two weeks and practically did not bleach under the mercury lamp during scores of minutes. Double staining of frozen sections with direct conjugates of quantum dots with primary mouse monoclonal antibodies demonstrated direct conjugate high specificity and sensitivity. High stability of quantum dots’ fluorescence allows their use in diagnostics to analyze antigen coexpression on lymphoid tissue sections. “Spillover” of fluorescent signals from quantum dots into adjacent fluorescent channels maximally separated by 40 nm did not exceed 8%, which renders spectral compensation unnecessary.     

Computerized quantification of immunofluorescence-labeled axon terminals and analysis of co-localization of neurochemicals in axon terminals with a confocal scanning laser microscope

The confocal scanning laser microscope (CSLM) offers improved optical resolution and contrast, high photometric precision, and the ability to make optical sections. These benefits were explored for use in quantitative analysis of immunofluorescence-labeled axon terminals. Guidelines were obtained for adjustments of the CSLM parameters. In the present applications, bleaching of the fluorescence did not represent a serious obstacle to analysis with the CSLM. A method was developed to distinguish the background fluorescence from the specific fluorescence labeling. This procedure made way for the development of automated quantification of immunolabeled axon terminals. The automated procedures substantially reduced the man-hour expenditure for analysis and provided highly reproducible quantifications compared with manual methods. The increased resolution and contrast of the CSLM allowed measurements of the fluorescence signal strength of individual axon terminals. The CSLM also allowed detection of co-localized neurochemicals in axon terminals.     

Laser scanning cytometry for comet assay analysis

BACKGROUND: The comet assay (single-cell gel electrophoresis) is a sensitive method for evaluating nuclear DNA damage. Previously used evaluation methods for the comet assay are time consuming and have an inherent risk of biased selection of comets due to manual selection and categorization of comet images. Laser scanning cytometry (LSC), the principle of which is equivalent to flow cytometry, enables quantification of fluorescence emitted from the cells on a microscope slide. In the present study, we explored whether LSC could be used to determine the degree of DNA damage demonstrated by the comet assay. METHODS: DNA damage was induced by ultraviolet A irradiation of keratinocytes and visualized by the comet assay. The evaluation included (a) LSC determination of DNA-specific fluorescence in 1,000 comet heads (undamaged DNA), (b) image acquisition of comets by rescanning of the microscope slide, and (c) digital image analysis and computation of tail moment and DNA content in the comet tails. RESULTS: Cells with damaged DNA were observed in a sub-G(1) area because the comet head loses DNA to the tail. We found a strong inverse correlation between tail moment and DNA content per nucleus. CONCLUSIONS: LSC enables an automated method for cell recognition and evaluation of the comets, thus providing quantitative information about nuclear DNA damage without subjective selection of analyzed comets.     

Concentration of elements in mitotic chromatin as measured by x-ray microanalysis

Unfixed frozen-dried and uncoated tissue sections of the mouse duodenum were placed on carbon planchets and analyzed in a scanning electron microscope fitted with energy dispersive X-ray equipment. Computer analysis of the X-ray spectra allowed elemental microanalysis of the nucleus, cytoplasm, and mitotic chromatin regions in the cryptal and villus enterocytes. The peak to continuum ratio of S, Cl, K, and Ca were higher in mitotic chromatin than any of the other sites measured. The redistribution of Ca at mitosis is postulated to help explain both chromosome condensation and assembly of the mitotic spindle apparatus.     

Fink-Heimer Silver Impregnation of Degenerating Axons and Terminals in Mounted Cryostat Sections of Fresh and Fixed Brains

The silver impregnation method of Fink and Heimer (Brain Res., 4: 369-74, 1967) has been used on cryostat sections of both fresh frozen and formalin-fixed brain tissue mounted on slide. The fixed brains were soaked in 25% sucrose for 2-3 days before freezing. The slides used for mounting were dipped in a 0.5% aqueous gelatin solution containing 50 mg of chrome-alum per 100 ml, drained and allowed to dry in a vertical position. Sections of fresh tissue were fixed for 16 hr in a 10% formalin solution buffered with phosphates to pH 7.0. Staining was carried out according to the Fink-Heimer procedure II and gave results comparable to those obtained on unmounted frozen sections of formalin-fixed material