49 research outputs found
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Photoacoustic image guidance and tissue characterization in cardiovascular applications
Collectively, cardiovascular diseases continue to be the leading cause of death, across nations and across decades. Improved diagnostic imaging methods offer promise to alleviate the morbidity associated with these diseases. Photoacoustic (PA) imaging is one such method, poised to make a significant impact on cardiovascular imaging, both as a research tool, as well as a clinical imaging modality. Offering the potential of molecular imaging in real-time, PA methods have been demonstrated in proof-of-concept studies tracking myocyte calcium dynamics. These results open the door to non-invasive longitudinal assessment of cardiac electrophysiological function, with implications for drug and contrast agent development. PA image guidance has also been extended to the characterization of cardiac radiofrequency ablation lesions. This method has been demonstrated to utilize endogenous chromophore changes resulting from ablation for the generation of depth-resolved tissue characterization maps, capable of assessing lesion extent. The technique has been subsequently validated by assessing high-intensity focused ultrasound ablation lesions in myocardium, with the hope for offering thermographic capabilities as well. While PA imaging offers such promise in cardiac ablation procedures, it is also in the process of clinical translation for image guidance and characterization in coronary artery disease applications. Research has shown, using Monte Carlo optical modeling, that using a simple dual-wavelength PA imaging technique has great potential for successful visualization of atherosclerotic plaques across multiple tissue types and at clinically relevant multiple millimeters of depth. Collectively these results offer a suite of PA imaging tools with the potential for molecular and thermographic imaging across a broad range of cardiovascular applications.Biomedical Engineerin
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Intravascular photoacoustics as a theranostic platform for atherosclerosis
textThe persistence of high global mortality rates directly attributable to cardiovascular disease drives ongoing research into novel approaches for improved diagnosis and treatment of its primary underlying cause, atherosclerosis. Combined intravascular ultrasound and photoacoustic (IVUS/IVPA) imaging is one such modality, actively being developed as a tool for improved characterization of high-risk atherosclerotic plaques. The pathophysiology associated with progression and destabilization of atherosclerotic plaques leads to characteristic changes in arterial morphology and composition. IVUS/IVPA imaging seeks to expand upon the ability of clinically utilized intravascular ultrasound (IVUS) imaging to assess vessel anatomy by adding improved sensitivity to image the underlying cellular and molecular composition through intravascular photoacoustic (IVPA) imaging of either endogenous chromophores (e.g. lipid) or exogenously delivered contrast agents. This dissertation focuses on the expansion of IVUS/IVPA imaging using exogenous contrast agents to enable the detection and subsequent optically-triggered therapy of atherosclerotic plaques. The passive extravasation and aggregation of systemically injected plasmonic gold nanorods absorbing within the near infrared tissue optical window within plaques of atherosclerotic rabbit models is first demonstrated, along with the ability to localize the contrast agents using ex vivo IVUS/IVPA imaging. The motivation for nanoparticle labeling of atherosclerosis is then expanded from that of purely image contrast agents to vehicles for image-guided, dual-modality phototherapy. The integrated IVUS/IVPA imaging catheter is utilized for photothermal delivery with simultaneous IVPA temperature monitoring using the high optical absorption of gold nanorod contrast agents to enable localized heating. Subsequently, the potential role for IVUS/IVPA-guided phototherapy is further expanded through the characterization and in vitro assessment of novel multifunctional theranostic nanoparticles comprised of a gold nanorod core with a degradable, photosensitizer-doped silica shell. Together, the results presented within this dissertation provide a framework for ongoing research into the expansion of IVUS/IVPA imaging as a platform for complimentary diagnosis and local treatment of atherosclerotic plaques using multifunctional theranostic nanoparticle contrast agents.Biomedical Engineerin
Molecular Imaging
The present book gives an exceptional overview of molecular imaging. Practical approach represents the red thread through the whole book, covering at the same time detailed background information that goes very deep into molecular as well as cellular level. Ideas how molecular imaging will develop in the near future present a special delicacy. This should be of special interest as the contributors are members of leading research groups from all over the world
Magnetic resonance imaging of colonic function
The overall aim of this work was to develop MRI methods and techniques to study the physiology and the pathology of the gastrointestinal tract, with particular attention to the colon. Besides, the development of new methods was aimed in order to perform quantitative analysis using proton and fluorine MRI. In particular the first experimental chapter describes the development and the optimisation of imaging protocols for studying colonic function in undisturbed physiologically relevant conditions. In addition a texture analysis method based on Gabor filters is developed and used for the objective assessment of colonic content characteristics. The mechanisms of action of common anti-diarrhoeal and anti-constipation agents are also investigated. The last experimental chapter describes the development of methods for using markers to measure GI transit. Transit time, i.e. the time it takes for a marker to pass through the entire gut, is often affected by functional gastrointestinal disorders, therefore it is of primary importance to develop a non-invasive and effective technique for the diagnosis of such gastrointestinal diseases. The use of fluorinated agents and its many advantages compared to other techniques is outlined and the first in vivo studies at high field are presented. The use of gadolinium based compounds as an additional marker is also discussed
Radiobiology Textbook:Space Radiobiology
The study of the biologic effects of space radiation is considered a “hot topic,” with increased interest in the past years. In this chapter, the unique characteristics of the space radiation environment will be covered, from their history, characterization, and biological effects to the research that has been and is being conducted in the field.
After a short introduction, you will learn the origin and characterization of the different types of space radiation and the use of mathematical models for the prediction of the radiation doses during different mission scenarios and estimate the biological risks due to this exposure. Following this, the acute, chronic, and late effects of radiation exposure in the human body are discussed before going into the detailed biomolecular changes affecting cells and tissues, and in which ways they differ from other types of radiation exposure.
The next sections of this chapter are dedicated to the vast research that has been developed through the years concerning space radiation biology, from small animals to plant models and 3D cell cultures, the use of extremophiles in the study of radiation resistance mechanisms to the importance of ground-based irradiation facilities to simulate and study the space environment