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Author: Bingbing Cheng Publisher: ISBN: Category : Diagnostic imaging Languages : en Pages : 135
Book Description
Fluorescence microscopic imaging in centimeter-deep tissue has been highly sought-after for many years because much interesting in vivo micro-information--such as microcirculation, tumor angiogenesis, and cancer metastasis--may deeply locate in tissue. However, it is very challenging because of strong tissue light scattering. This includes: how to confine the fluorescence emission into a small volume to achieve high spatial resolution; how to increase fluorescence emission efficiency to compensate the signal attenuation caused by small emission volume and tissue scattering/absorption; and how to reduce background fluorescence noise and exclusively differentiate signal photons from background photons to increase signal-to-noise ratio (SNR) and sensitivity. Ultrasonic scattering is two to three orders of magnitude less than light scattering in opaque biological tissue. Therefore, light focusing has been replaced by ultrasonic focusing to achieve high spatial resolution in deep tissue. In addition, high intensity focused ultrasound (HIFU) can noninvasively heat a small region deep within the body (hundreds of microns in lateral). If one can develop a contrast agent whose fluorescence emission is sensitive to this HIFU-induced temperature change and a sensitive imaging system which can detect the ultrasound-controlled photons that have been scattered many times, centimeter-deep tissue fluorescence microscopic imaging can be achievable. This study is focused on developing a fundamentally different imaging technology: ultrasound-switchable fluorescence (USF), including the contrast agent development and the imaging system development. Basically, the USF contrast agent developed in this work is thermosensitive and its fluorescence emission has a switch-like relationship with temperature. Its fluorescence emission can be switched on or off by a focused ultrasound beam generated from a HIFU transducer within its focal volume. Then the diffused USF photons propagate out and are detected by a sensitive USF imaging system. First, the excellent USF imaging contrast agents were developed by using the environment-sensitive fluorophores and thermosensitive polymers. We started investigating environment-sensitive fluorophores from visible light range up to near infrared (NIR) range since only NIR light can penetrate centimeter-deep in opaque biological tissues. Two basic thermosensitive polymers and their co-polymers were used, including: poly (N-isopropylacrylamide) (PNIPAM) and pluronic. Both linear polymer and nanoparticle based USF contrast agents were explored. Second, a sensitive frequency domain (FD) USF imaging system and an effective signal identification algorithm were developed. The lock-in amplifier adopted in the FD-USF imaging system and the correlation algorithm significantly improved the SNR and detection sensitivity. Third, the feasibility of USF imaging in centimeter-deep tissue with high resolution was demonstrated in both tissue-mimicking phantoms and ex vivo biological tissues. Multi-color high-resolution USF imaging in centimeter-deep tissue with high SNR and picomole sensitivity were also achieved. Fourth, the feasibility of in vivo USF imaging was demonstrated in living mice by using different types of USF contrast agents via both intravenous and local injections. In summary, the results provided in this work demonstrated for the first time the feasibility of centimeter-deep tissue fluorescence microscopic imaging with high SNR and picomole sensitivity via USF in tissue-mimicking phantoms, porcine muscle tissues, ex vivo mouse organs (liver and spleen), and in vivo mice. Multiplex USF imaging was also achieved, which is useful to simultaneously image multiple targets and observe their interactions. This work opens the door for future studies of center-deep tissue fluorescence microscopic imaging.
Author: Bingbing Cheng Publisher: ISBN: Category : Diagnostic imaging Languages : en Pages : 135
Book Description
Fluorescence microscopic imaging in centimeter-deep tissue has been highly sought-after for many years because much interesting in vivo micro-information--such as microcirculation, tumor angiogenesis, and cancer metastasis--may deeply locate in tissue. However, it is very challenging because of strong tissue light scattering. This includes: how to confine the fluorescence emission into a small volume to achieve high spatial resolution; how to increase fluorescence emission efficiency to compensate the signal attenuation caused by small emission volume and tissue scattering/absorption; and how to reduce background fluorescence noise and exclusively differentiate signal photons from background photons to increase signal-to-noise ratio (SNR) and sensitivity. Ultrasonic scattering is two to three orders of magnitude less than light scattering in opaque biological tissue. Therefore, light focusing has been replaced by ultrasonic focusing to achieve high spatial resolution in deep tissue. In addition, high intensity focused ultrasound (HIFU) can noninvasively heat a small region deep within the body (hundreds of microns in lateral). If one can develop a contrast agent whose fluorescence emission is sensitive to this HIFU-induced temperature change and a sensitive imaging system which can detect the ultrasound-controlled photons that have been scattered many times, centimeter-deep tissue fluorescence microscopic imaging can be achievable. This study is focused on developing a fundamentally different imaging technology: ultrasound-switchable fluorescence (USF), including the contrast agent development and the imaging system development. Basically, the USF contrast agent developed in this work is thermosensitive and its fluorescence emission has a switch-like relationship with temperature. Its fluorescence emission can be switched on or off by a focused ultrasound beam generated from a HIFU transducer within its focal volume. Then the diffused USF photons propagate out and are detected by a sensitive USF imaging system. First, the excellent USF imaging contrast agents were developed by using the environment-sensitive fluorophores and thermosensitive polymers. We started investigating environment-sensitive fluorophores from visible light range up to near infrared (NIR) range since only NIR light can penetrate centimeter-deep in opaque biological tissues. Two basic thermosensitive polymers and their co-polymers were used, including: poly (N-isopropylacrylamide) (PNIPAM) and pluronic. Both linear polymer and nanoparticle based USF contrast agents were explored. Second, a sensitive frequency domain (FD) USF imaging system and an effective signal identification algorithm were developed. The lock-in amplifier adopted in the FD-USF imaging system and the correlation algorithm significantly improved the SNR and detection sensitivity. Third, the feasibility of USF imaging in centimeter-deep tissue with high resolution was demonstrated in both tissue-mimicking phantoms and ex vivo biological tissues. Multi-color high-resolution USF imaging in centimeter-deep tissue with high SNR and picomole sensitivity were also achieved. Fourth, the feasibility of in vivo USF imaging was demonstrated in living mice by using different types of USF contrast agents via both intravenous and local injections. In summary, the results provided in this work demonstrated for the first time the feasibility of centimeter-deep tissue fluorescence microscopic imaging with high SNR and picomole sensitivity via USF in tissue-mimicking phantoms, porcine muscle tissues, ex vivo mouse organs (liver and spleen), and in vivo mice. Multiplex USF imaging was also achieved, which is useful to simultaneously image multiple targets and observe their interactions. This work opens the door for future studies of center-deep tissue fluorescence microscopic imaging.
Author: Ammasi Periasamy Publisher: Springer ISBN: 1461475139 Category : Science Languages : en Pages : 473
Book Description
Advances in technology have revolutionized the development of light microscopy techniques in biomedical research, thus improving visualization of the microstructure of cells and tissues under physiological conditions. Fluorescence microscopy methods are non-contact and non-invasive and provide high spatial and temporal resolution that other laboratory techniques cannot. This well-illustrated book targets graduate students and scientists who are new to the state-of-the-art fluorescence microscopy techniques used in biological and clinical imaging. It explains basic concepts and imaging procedures for wide-field, confocal, multiphoton excitation, fluorescence resonance energy transfer (FRET), lifetime imaging (FLIM), spectral imaging, fluorescence recovery after photobleaching (FRAP), optical tweezers, total internal reflection, high spatial resolution atomic force microscopy (AFM), and bioluminescence imaging for gene expression. The usage of these techniques in various biological applications, including calcium, pH, membrane potential, mitochondrial signaling, protein-protein interactions under various physiological conditions, and deep tissue imaging, is clearly presented. The authors describe the approaches to selecting epifluorescence microscopy, the detectors, and the image acquisition and processing software for different biological applications. Step-by-step directions on preparing different digital formats for light microscopy images on websites are also provided.
Author: C. Y. Dong Publisher: ISBN: Category : Languages : en Pages : 10
Book Description
Based on non-linear excitation of fluorescence molecules, two-photon fluorescence microscopy has become a significant new too! for biological imaging. The point-like excitation characteristic of this technique enhances image quality by the virtual elimination of off-focal fluorescence. Furthermore, sample photodamage is greatly reduced because fluorescence excitation is limited to the focal region. For deep tissue imaging, two-photon microscopy has the additional benefit in the greatly improved imaging depth penetration. Since the near-infrared laser sources used in two-photon microscopy scatter less than their UV/glue-green counterparts, in-depth imaging of highly scattering specimen can be greatly improved. In this work, we will present data characterizing both the imaging characteristics (point-spread- functions) and tissue samples (skin) images using this novel technology. In particular, we will demonstrate how blind deconvolution can be used further improve two-photon image quality and how this technique can be used to study mechanisms of chemically-enhanced, transdermal drug delivery.
Author: Guy Cox Publisher: CRC Press ISBN: 1351129392 Category : Science Languages : en Pages : 458
Book Description
Fluorescence imaging, at macro, micro, and submicro scales, has revolutionized biological science in the past 30 years. Immunolabelling has provided precise targeting of molecules in fixed tissue, while fluorescent proteins have enabled localization in living tissues. Fluorescent indicators enable imaging of dynamic changes in cell metabolism. This book covers, for the first time, imaging at all scales from macro to submicro (superresolution). Its authors include Robert Clegg, legendary teacher and researcher (who, sadly, passed away during the editing); Jim Pawley, editor of several editions of the Handbook of Biological Confocal Microscopy; the famous and now dispersed New Zealand team of Mark Cannell, Christian Soeller, and David Baddeley; Robert Hoffman, pioneer of whole-animal imaging in cancer research; Andreas Schoenle and Christian Eggeling on STED nanoscopy, and many more famous participants in this field. All the contributors are at the cutting edge of their field.
Author: Alberto Diaspro Publisher: Springer Science & Business Media ISBN: 3642151752 Category : Science Languages : en Pages : 252
Book Description
In the last decade, fluorescence microscopy has evolved from a classical “retrospective” microscopy approach into an advanced imaging technique that allows the observation of cellular activities in living cells with increased resolution and dimensions. A bright new future has arrived as the nano era has placed a whole new array of tools in the hands of biophysicists who are keen to go deeper into the intricacies of how biological systems work. Following an introduction to the complex world of optical microscopy, this book covers topics such as the concept of white confocal, nonlinear optical microscopy, fluctuation spectroscopies, site-specific labeling of proteins in living cells, imaging molecular physiology using nanosensors, measuring molecular dynamics, muscle braking and stem cell differentiation.
Author: Michael Ming-Yuan Wei Publisher: Frontiers Media SA ISBN: 288966113X Category : Science Languages : en Pages : 223
Book Description
Dr Ming-Yuan Wei currently holds a pending U.S. Patent Application entitled “Systems and Methods for High-Resolution Imaging”. All other Guest Editors have no other competing interests to declare with regards to the Topic subject.
Author: Robert Juson Barretto Publisher: Stanford University ISBN: Category : Languages : en Pages : 149
Book Description
Optical microendoscopy is an emerging modality for imaging in live subjects. Using gradient refractive index (GRIN) microlenses, microendoscopy enables subcellular-resolution imaging in deep tissues that are inaccessible by traditional imaging techniques. We present a platform of methods and technologies that build upon GRIN microendoscopy: 1) miniaturized microscopes for imaging in awake, behaving animals, 2) methods for imaging contractile dynamics in the muscles of animal and human subjects, 3) chronic brain preparations that allow for longitudinal examinations of subcellular neuronal features and disease progression, and 4) novel microendoscope probes whose imaging capabilities approach that of standard water-immersion microscope objectives. When combined with the broad sets of available fluorescent reporters, and minimally invasive surgical preparations, the work described in this dissertation enables sophisticated experimental designs for probing how cellular char- acteristics may underlie or explain behavior, in models of both healthy and diseased states.
Author: Bahar Saremi Publisher: ISBN: Category : Diagnostic imaging Languages : en Pages : 74
Book Description
Fluorescence imaging has attracted much attention due to high sensitivity, spatial and temporal resolution, and fast acquisition time, for imaging biomolecular processes and for diagnosis of diseases such as cancer in early stages. Fluorescence imaging in centimeter-deep tissue suffers from low spatial resolution because of the strong scattering of light. On the other hand ultrasound imaging benefits from 1000 times less scattering in the tissue and deep penetration. Ultrasound switchable fluorescence imaging is a relatively new imaging modality that combines the sensitivity of optical imaging with the depth of penetration of ultrasound imaging while preserving the resolution by only eliciting the fluorescence signal from the small focal volume of the high intensity focused ultrasound (HIFU). As such unprecedented depths can be penetrated while resolution and sensitivity of fluorescence imaging are relatively conserved. USF imaging contrast agents directly or indirectly respond to the elevated temperatures caused by HIFU. As such thermo-sensitive USF imaging probes switch "ON" over a narrow range of elevated temperatures instantly. In this work, several different strategies for developing thermo-sensitive probes for potential use in USF imaging are studied a pH-sensitive USF contrast agent developed.
Author: Min Gu Publisher: Springer ISBN: 3662463970 Category : Science Languages : en Pages : 192
Book Description
This book provides a systematic introduction to the principles of microscopic imaging through tissue-like turbid media in terms of Monte-Carlo simulation. It describes various gating mechanisms based on the physical differences between the un scattered and scattered photons and method for microscopic image reconstruction, using the concept of the effective point spread function. Imaging an object embedded in a turbid medium is a challenging problem in physics as well as in bio photonics. A turbid medium surrounding an object under inspection causes multiple scattering, which degrades the contrast, resolution and signal-to-noise ratio. Biological tissues are typically turbid media. Microscopic imaging through a tissue-like turbid medium can provide higher resolution than transillumination imaging in which no objective is used. This book serves as a valuable reference for engineers and scientists working on microscopy of tissue turbid media.
Author: James Pawley Publisher: Springer Science & Business Media ISBN: 1475753489 Category : Science Languages : en Pages : 639
Book Description
This third edition of a classic text in biological microscopy includes detailed descriptions and in-depth comparisons of parts of the microscope itself, digital aspects of data acquisition and properties of fluorescent dyes, the techniques of 3D specimen preparation and the fundamental limitations, and practical complexities of quantitative confocal fluorescence imaging. Coverage includes practical multiphoton, photodamage and phototoxicity, 3D FRET, 3D microscopy correlated with micro-MNR, CARS, second and third harmonic signals, ion imaging in 3D, scanning RAMAN, plant specimens, practical 3D microscopy and correlated optical tomography.
Author: Bingbing Cheng
Author: Bingbing Cheng
Author: Ammasi Periasamy
Author: C. Y. Dong
Author: Guy Cox
Author: Alberto Diaspro
Author: Michael Ming-Yuan Wei
Author: Robert Juson Barretto
Author: Bahar Saremi
Author: Min Gu
Author: James Pawley