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  • Multiphoton Microscopy – a Satisfied Wish List

    The colorful picture shows colon tumor cells, fluorescently labelled and lineage traced from a multicolor tracer. The gray color codes for the second harmonic generation (SHG) signal from Collagen 1. Lineage traced tumor cells are shown in magenta, blue, green, yellow and red. All channels were recorded with two-photon excitation, using the SP8 DIVE by Leica Microsystems. Sample and image were kindly provided by J. van Rheenen, H. Snippert, Utrecht (the Nederlands,) and I. Steinmetz, Leica Microsystems Mannheim.
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  • Mission Impossible Accomplished: Tunable Colors for Non-descanning Detection

    Leica Microsystems’ 4Tune detector, the key component of the SP8 DIVE Deep In Vivo Explorer, provides spectrally tunable image recording with non-descanning detection. An innovative solution for multiparameter multiphoton microscopy. The colorful image on the right shows multiphoton microscopy of an unstained mouse skin section acquired using the 4Tune detector. The green color codes for autofluorescence of muscle tissue. Red shows second harmonic generation of fibers upon illumination with 900 nm. The blue pattern is generated by third harmonic generation at lipid boundaries from illumination at 1230 nm.
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  • Laser Beam Shaping for Multicolor Multiphoton Microscopy

    Multiphoton Microscopy is one of the current hot topics in life science research. The new Leica TCS SP8 DIVE from Leica Microsystems presents a series of beneficial new innovations, including a freely tunable non-descanning detector and an ingenious beam manipulating device VBE. The variable beam expander offers free tuning of both beam diameter and axial IR-correction for up to four IR beams simultaneously.
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  • Chronic Stress in Mice Remodels Lymph Vasculature to Promote Tumour Cell Dissemination

    Chronic stress induces signalling from the sympathetic nervous system (SNS) and drives cancer progression, although the pathways of tumour cell dissemination are unclear. Here we show that chronic stress restructures lymphatic networks within and around tumours to provide pathways for tumour cell escape. We show that VEGFC derived from tumour cells is required for stress to induce lymphatic remodelling and that this depends on COX2 inflammatory signalling from macrophages. Pharmacological inhibition of SNS signalling blocks the effect of chronic stress on lymphatic remodelling in vivo and reduces lymphatic metastasis in preclinical cancer models and in patients with breast cancer.
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  • Clarifying Tissue Clearing

    Biological specimens are intrinsically three dimensional; however because of the obscuring effects of light scatter, imaging deep into a tissue volume is problematic. Although efforts to eliminate the scatter by “clearing” the tissue have been ongoing for over a century, there have been a large number of recent innovations. This review introduces the physical basis for light-scatter in tissue, describes the mechanisms underlying various clearing techniques, and discusses several of the major advances in light microscopy for imaging cleared tissue.
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  • Multiphoton Microscopy Publication List

    Multiphoton Microscopy is an advanced technique for imaging thick samples. Applications range from the visualization of the complex architecture of the whole brain to the study of tumor development and metastasis or the responses of the immune system in living animals. On this regularly updated reference list you can find selected publications on reseach using multiphoton microscopy.
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  • 4Pi-RESOLFT Nanoscopy

    Here we apply the 4Pi scheme to RESOLFT nanoscopy using two-photon absorption for the on-switching of fluorescent proteins. We show that in this combination, the lobes are so low that low-light level, 3D nanoscale imaging of living cells becomes possible. Our method thus offers robust access to densely packed, axially extended cellular regions that have been notoriously difficult to super-resolve. Our approach also entails a fluorescence read-out scheme that translates molecular sensitivity to local off-switching rates into improved signal-to-noise ratio and resolution.
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  • Developments in Multiphoton Excitation Microscopy

    Basics, history, and applications of multiphoton microscopy. Honouring Goeppert-Mayer’s prediction of simultaneous two-photon absorption by an atom or molecule reported in the 1930s in her PhD dissertation thesis, we can state that multiphoton excitation (MPE) microscopy, more frequently identified with two-photon excitation (2PE) fluorescence microscopy, is a key microscopy method in many areas from medicine to biology, from biophysics to materials science.
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  • Neuroscience and Microscopy

    Neurobiology, the science of nerves and the brain, has mainly been driven forward in the last 200 years by microscopic investigations. The structures of cellular and subcellular structures, interaction and the three-dimensional assembly of neurons were made visible by various microscopy techniques. The optical microscope is also a necessary tool for visualizing micropipettes in electrophysiological measurements. Thirdly, many types of functional imaging are performed by means of optical microscopy.
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  • Lasers for Confocal

    True confocal scanning microscopy (TCS) requires bright diffraction-limited illumination.
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  • What is an OPO?

    Multiphoton microscopy with OPO: imaging with excitation wavelengths up to 1.300 nm. Because light scattering is dependent on the wavelength, better tissue penetration can be achieved by using longer excitation wavelengths. This is where excitation with infrared light, two-photon processes, and the OPO (optical parameter oscillator) can dramatically improve image quality.
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  • From Molecules to Tissues

    Cancer research using confocal and multiphoton microscopy. Sequencing of the human genome stimulated a radical change in the approach to biomedical research. The comprehension of the mechanisms regulating life gained a scale-up in throughput to speed up the retrieval of data for a global vision of a system of incomparable complexity.
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