High resolution colonoscopy in live mice

Endoscopy in humans is a powerful method for physicians to examine the gut for inflammatory or neoplastic changes. In medical and immunological research, animal models of intestinal diseases are established key tools to investigate the mucosal immune system, colitis and cancer development in the gut. Moreover, such models represent valid systems for testing of novel drugs. In the past, mice had to be killed in order to analyze colitis activity and tumor development. The following protocol describes a method to perform high resolution endoscopic monitoring of live mice. Mice developing colitis or colonic tumors are anesthetized and examined with a miniendoscope. The endoscope is introduced via the anus and the colon is carefully insufflated with an air pump. Endoscopic pictures obtained are of high quality and allow the monitoring and grading of tumors and inflammation. In addition, colonic biopsies can be taken. This protocol can be completed within 1 h.     

High resolution,label‐free photoacoustic imaging of live chicken embryo developing in bioengineered eggshell

Chicken embryos have been proven to be an attractive vertebrate model for biomedical research. They have helped in making significant contributions for advancements in various fields like developmental biology, cancer research and cardiovascular studies. However, a non‐invasive, label‐free method of imaging live chicken embryo at high resolution still needs to be developed and optimized. In this work, we have shown the potential of photoacoustic tomography (PAT) for imaging live chicken embryos cultured in bioengineered eggshells. Laser pulses at wavelengths of 532 and 740 nm were used for attaining cross‐sectional images of chicken embryos at different developmental stages. Cross‐sections along different depths were imaged to gain knowledge of the relative depth of different vessels and organs. Due to high optical absorption of vasculature and embryonic eye, images with good optical contrast could be acquired using this method. We have thus reported a label‐free method of performing cross‐sectional imaging of chicken embryos at high resolution demonstrating the capacity of PAT as a promising tool for avian embryo imaging.     

High resolution NMR study of mitochondria and submitochondrial fragments]

The PMR spectra of mitochondrias, inner and outer mitochondrial membranes and also, matrix and intermembrane material are presented. The essential effect of sonication on the structure of inner membranes of mitochondrias is demonstrated.     

High resolution imaging of vascular function in zebrafish

Rationale

The role of the endothelium in the pathogenesis of cardiovascular disease is an emerging field of study, necessitating the development of appropriate model systems and methodologies to investigate the multifaceted nature of endothelial dysfunction including disturbed barrier function and impaired vascular reactivity.

Objective

We aimed to develop and test an optimized high-speed imaging platform to obtain quantitative real-time measures of blood flow, vessel diameter and endothelial barrier function in order to assess vascular function in live vertebrate models.

Methods and Results

We used a combination of cutting-edge optical imaging techniques, including high-speed, camera-based imaging (up to 1000 frames/second), and 3D confocal methods to collect real time metrics of vascular performance and assess the dynamic response to the thromboxane A₂ (TXA₂) analogue, U-46619 (1 µM), in transgenic zebrafish larvae. Data obtained in 3 and 5 day post-fertilization larvae show that these methods are capable of imaging blood flow in a large (1 mm) segment of the vessel of interest over many cardiac cycles, with sufficient speed and sensitivity such that the trajectories of individual erythrocytes can be resolved in real time. Further, we are able to map changes in the three dimensional sizes of vessels and assess barrier function by visualizing the continuity of the endothelial layer combined with measurements of extravasation of fluorescent microspheres.

Conclusions

We propose that this system-based microscopic approach can be used to combine measures of physiologic function with molecular behavior in zebrafish models of human vascular disease.     

High temporal resolution video imaging of intracellular calcium

We have developed a system for imaging intracellular free calcium ion concentration ([Ca2+]i) at the highest rate possible with conventional video equipment. The system is intended to facilitate quantitative study of rapid changes in [Ca2+]i in cells that move. It utilizes intensified video cameras with nearly ideal properties and digital image processing to produce two images that can be ratioed without artifacts. Two dichroic mirrors direct images of cellular Indo-1 fluorescence at two different wavelengths to two synchronized video cameras, each consisting of a fast micro-channel plate image intensifier optically coupled with a tapered fiber optic bundle to a CCD image sensor. The critical technical issues in this dual-image system are: (1) minimization and correction of the small geometric and other types of differences in the images provided by the two cameras; and (2) the signal-to-noise ratio that can be achieved in single frames. We have used this system to obtain images of [Ca2+]i at 16.7 ms intervals in voltage-clamped single cardiac cells perfused internally with Indo-1 (pentapotassium salt). The images indicate that, except for the nuclear regions, [Ca2+]i is uniform during normal excitation-contraction coupling. In contrast, changes in [Ca2+]i propagate in rapid 'waves' during the spontaneous release of Ca2+ that accompanies certain 'Ca2(+)-overload conditions.'     

High resolution optical imaging of infarction in intact organs

We describe a method to visualize green fluorescent protein (GFP)-labeled cells in intact organs through combined confocal and reflected laser light imaging. This method allows us a three-dimensional (3-D) view of specific cell types in situ. Imaging of tissues from transgenic mice in which the endothelial cells are labeled with GFP under the control of endothelial-specific tyrosine receptor kinase 2 (TIE2) shows the spatial distribution of the GFP-labeled endothelial cells in intact organs. We have used this method to examine the tissue necrosis in the intact heart and kidney resulting from myocardial and renal infarction. In myocardial infarction produced by surgically occluding the left anterior descending coronary artery, the border of the infarct was highly cellular and showed a disrupted endothelial network and scar tissue appearing as a dense layer of reflection. The induced renal infarction produced by ligating the renal artery in the pedicle showed a clear infarct border in the affected kidney. The 3-D reconstruction of specific cell types in the context of the surrounding tissues should be useful for studying the overall organization and the relationship between different structures in the intact organ in normal and disease states.     

High resolution q-space imaging studies of water in elastin

We report on the direct measurement of the molecular diffusion coefficients of water confined to purified bovine nuchal ligament elastin by high resolution q-space NMR imaging. The experimental data indicate that water trapped within an elastin fiber has two distinguishable molecular diffusion coefficients. The component with the slowest mobility has a diffusion coefficient on the order of 10(-6) cm(2)/s that varies inversely with the diffusion time and is seen to reduce near 37 degrees C. The component with higher mobility has a diffusion coefficient reminiscent of free water but is observed to also behave similarly at 37 degrees C. From our experimental data we extract the surface-to-volume ratio of pores within elastin and associated changes as a function of temperature.     

High resolution imaging by organic secondary ion mass spectrometry

Secondary-ion mass spectrometry (SIMS) is based on the acceleration of high-energy primary ions onto a target. Secondary electrons, neutrals and ions are emitted from the target, reflecting its chemical composition. This enables simultaneous analysis and localization of target molecules, giving valuable information that is difficult or impossible to obtain with other analytical methods. The secondary ions can be extracted and detected by any type of mass analyzer. SIMS is unique in its ability to detect several target molecules simultaneously in small samples and to image their localization at subcellular resolution. The recent development of bioimaging SIMS opens up new possibilities in biotechnology and biological research with applications in biomedicine and pathology. The current development of this technique has the potential to become as important for biotechnology as the advent of the electron microscope, confocal microscope or in situ hybridization.     

High resolution imaging of receptor binding in analyzing neuropsychiatric diseases

A method for analyzing high resolution imaging of receptor binding activity in human post-mortem brain specimens is described. The autoradiography technique employed is based on methods previously described by others in which coverslips dipped in tritium-sensitive nuclear track emulsion are placed over a tissue section that has been incubated in a medium containing radioactively-tagged ligand. With this approach, there is a 370-fold increase in resolution from approximately 120 microns available with tritium-sensitive films to 0.33 micron attainable with the emulsion approach. Since the coverslip autoradiogram remains superimposed on the tissue section, individual grains can be routinely quantitated in specific cell types and discrete subregions of the neuropil with the aid of a user-interactive image processing system. Overall, the improved resolution that this approach provides makes it possible to determine whether a particular neuronal sub-type may be preferentially altered by disease processes affecting the brain.     

Rapid and accurate analysis of stem cell-derived extracellular vesicles with super resolution microscopy and live imaging

Extracellular vesicles (EVs) have prevalent roles in cancer biology and regenerative medicine. Conventional techniques for characterising EVs including electron microscopy (EM), nanoparticle tracking analysis (NTA) and tuneable resistive pulse sensing (TRPS), have been reported to produce high variability in particle count (EM) and poor sensitivity in detecting EVs below 50?nm in size (NTA and TRPS), making accurate and unbiased EV analysis technically challenging. This study introduces direct stochastic optical reconstruction microscopy (d-STORM) as an efficient and reliable characterisation approach for stem cell-derived EVs. Using a photo-switchable lipid dye, d-STORM imaging enabled rapid detection of EVs down to 20–30?nm in size with higher sensitivity and lower variability compared to EM, NTA and TRPS techniques. Imaging of EV uptake by live stem cells in culture further confirmed the potential of this approach for downstream cell biology applications and for the analysis of vesicle-based cell-cell communication.     

High resolution in vivo bioluminescent imaging for the study of bacterial tumour targeting

The ability to track microbes in real time in vivo is of enormous value for preclinical investigations in infectious disease or gene therapy research. Bacteria present an attractive class of vector for cancer therapy, possessing a natural ability to grow preferentially within tumours following systemic administration. Bioluminescent Imaging (BLI) represents a powerful tool for use with bacteria engineered to express reporter genes such as lux. BLI is traditionally used as a 2D modality resulting in images that are limited in their ability to anatomically locate cell populations. Use of 3D diffuse optical tomography can localize the signals but still need to be combined with an anatomical imaging modality like micro-Computed Tomography (μCT) for interpretation.In this study, the non-pathogenic commensal bacteria E. coli K-12 MG1655 and Bifidobacterium breve UCC2003, or Salmonella Typhimurium SL7207 each expressing the luxABCDE operon were intravenously (i.v.) administered to mice bearing subcutaneous (s.c) FLuc-expressing xenograft tumours. Bacterial lux signal was detected specifically in tumours of mice post i.v.-administration and bioluminescence correlated with the numbers of bacteria recovered from tissue. Through whole body imaging for both lux and FLuc, bacteria and tumour cells were co-localised. 3D BLI and μCT image analysis revealed a pattern of multiple clusters of bacteria within tumours. Investigation of spatial resolution of 3D optical imaging was supported by ex vivo histological analyses. In vivo imaging of orally-administered commensal bacteria in the gastrointestinal tract (GIT) was also achieved using 3D BLI. This study demonstrates for the first time the potential to simultaneously image multiple BLI reporter genes three dimensionally in vivo using approaches that provide unique information on spatial locations.     

High resolution electrocardiography

Over the past decade, significant advances were made in the research, diagnosis, and treatment of cardiovascular diseases. Such progress was in every sphere of cardiology that includes non-invasive, minimally invasive, and invasive technologies. Interpretive electrocardiography, cardiac pacemakers, cardiac stents, and angioplasty are some areas where the progress has been significant. Non-invasive methods of diagnosis of cardiac disorders involve digital recording of cardiac signals at the body surface (chest) and subsequent computerized analysis. Such methods and instruments provide a vital first step to the diagnosis of the heart without involving surgical procedures. One such non-invasive field is High Resolution Electrocardiography (HRECG). A high-resolution electrocardiogram detects very low amplitude signals in the ventricles called 'Late Potentials' in patients with abnormal heart conditions. A standard electrocardiogram cannot detect these signals. The presence of late potentials is widely accepted to have prognostic significance in patients after Acute Myocardial Infarction (AMI) High Resolution Electrocardiography enhances the diagnostic capabilities of ECGs. This article describes the principles involved in HRECG and the techniques that are employed to derive such superior diagnostic capabilities. The use of these techniques may lead to more discoveries in the causes of cardiac disorders and improved drug discoveries to combat such conditions.     

High resolution scintiautoradiography

An electron microscopic scintiautoradiographic method for studying histological sections is reported. An increase in the silver grain yield is attained by using a scintillator in embedding medium. The amplification effect for 3H-labeling reaches 3-fold and for 14C reaches a 15-fold. No lessening of autoradiographic resolution was observed. On the basis of these preliminary results only qualitative evaluation of data is discussed.     

High resolution imaging of photosynthetic activities of tissues, cells and chloroplasts in leaves

Through imaging of chlorophyll fluorescence, it is possible to produce parameterized fluorescence images that estimate the operating quantum efficiency of photosystem II (PSII) photochemistry and which can be used to reveal heterogeneous patterns of photosynthetic performance within leaves. The operating quantum efficiency of PSII photochemistry is dependent upon the effective absorption cross-section of the light-harvesting system of PSII and the photochemical capacity of PSII. The effective absorption cross-section is decreased by the process of down-regulation, which is widely thought to operate within the pigment matrices of PSII and which results in non-photochemical quenching of chlorophyll fluorescence. The photochemical capacity is non-linearly related to the proportion of PSII centres in the 'open' state and results in photochemical quenching of chlorophyll fluorescence. Examples of heterogeneity of the operating quantum efficiency of PSII photochemistry during the induction of photosynthesis in maize leaves and in the chloroplast populations of stomatal guard cells of a leaf of Tradescantia albifora are presented, together with analyses of the factors determining this heterogeneity. A comparison of the operating quantum efficiency of PSII photochemistry within guard cells and adjacent mesophyll cells of Commelina communis is also made, before and after stomatal closure through a change in ambient humidity.     

High resolution imaging of collagen organisation and synthesis using a versatile collagen specific probe

Collagen is the protein primarily responsible for the load-bearing properties of tissues and collagen architecture is one of the main determinants of the mechanical properties of tissues. Visualisation of changes in collagen three-dimensional structure is essential in order to improve our understanding of collagen fibril formation and remodelling, e.g. in tissue engineering experiments. A recently developed collagen probe, based on a natural collagen binding protein (CNA35) conjugated to a fluorescent dye, showed to be much more specific to collagen than existing fluorescent techniques currently used for collagen visualisation in live tissues. In this paper, imaging with this fluorescent CNA35 probe was compared to imaging with second harmonic generation (SHG) and the imaging of two- and three-dimensional collagen organisation was further developed. A range of samples (cell culture, blood vessels and engineered tissues) was imaged to illustrate the potential of this collagen probe. This images of collagen organisation showed improved detail compared to images generated with SHG, which is currently the most effective method for viewing three-dimensional collagen organisation in tissues. In conclusion, the fluorescent CNA35 probe allows easy access to high resolution imaging of collagen, ranging from very young fibrils to more mature collagen fibres. Furthermore, this probe enabled real-time visualisation of collagen synthesis in cell culture, which provides new opportunities to study collagen synthesis and remodelling.     

Subcellular imaging in the live mouse

Fluorescent proteins are available in multiple colors and have properties such as intrinsic brightness and high quantum yield that make them optimally suited for in vivo imaging with subcellular resolution in the live mouse. In this protocol, cancer cells in live mice are labeled with green fluorescent protein (GFP) in the nucleus and red fluorescent protein (RFP) in the cytoplasm. GFP nuclear labeling is effected by linkage of GFP to histone H2B, and a retroviral vector is used for cytoplasmic labeling with RFP. Double-labeled cells are injected by various methods. High-resolution imaging systems with microscopic optics, in combination with reversible skin flaps over various organs, enable the imaging of dual-color labeled cells at the subcellular level in live animals. The double transfection and selection procedures described here take 6-8 weeks. Cancer cell trafficking, deformation, extravasation, mitosis and cell death can be imaged with clarity.     

Reversible excitation light-induced enhancement of fluorescence of live mammalian mitochondria.

During continuous irradiation with near-ultraviolet light (l = 36510 nm; 16 mW/mm(2)) for 2-3 min, live mammalian cells increased reversibly the intensity of one or more peaks of their autofluorescence spectrum from an initial ('ground') level to a two- to threefold higher ('active') level. The effect is characterized by the existence of two states of quantum efficiency and a mechanism of transition that expresses a threshold and a refractory period. It appears that mitochondria are the principal sources of the rising autofluorescence intensity; however, not all mitochondria are capable of expressing it. Studying cells from various organisms that belong to various branches of the phylogenetic tree, we found the rapid increase of autofluorescence only in placental mammalian cells. We speculate that the effect may point to the ability of placental mammalian mitochondria to generate pulsating light signals.     

Photobleaching-corrected FRET efficiency imaging of live cells

Fluorescent resonance energy transfer (FRET) imaging techniques can be used to visualize protein-protein interactions in real-time with subcellular resolution. Imaging of sensitized fluorescence of the acceptor, elicited during excitation of the donor, is becoming the most popular method for live FRET (3-cube imaging) because it is fast, nondestructive, and applicable to existing widefield or confocal microscopes. Most sensitized emission-based FRET indices respond nonlinearly to changes in the degree of molecular interaction and depend on the optical parameters of the imaging system. This makes it difficult to evaluate and compare FRET imaging data between laboratories. Furthermore, photobleaching poses a problem for FRET imaging in timelapse experiments and three-dimensional reconstructions. We present a 3-cube FRET imaging method, E-FRET, which overcomes both of these obstacles. E-FRET bridges the gap between the donor recovery after acceptor photobleaching technique (which allows absolute measurements of FRET efficiency, E, but is not suitable for living cells), and the sensitized-emission FRET indices (which reflect FRET in living cells but lack the quantitation and clarity of E). With E-FRET, we visualize FRET in terms of true FRET efficiency images (E), which correlate linearly with the degree of donor interaction. We have defined procedures to incorporate photobleaching correction into E-FRET imaging. We demonstrate the benefits of E-FRET with photobleaching correction for timelapse and three-dimensional imaging of protein-protein interactions in the immunological synapse in living T-cells.