ABSTRACT
Synchrotron-based micro-CT was utilized to image the embedded biological soft-tissue of a small animal shell. Micro-CT images of the biological soft-tissue were acquired using 20, 25, and 27 keV synchrotron X-rays with contrast agents, such as water, physiological saline and iodine. Visualized the complex features of the animal at the above energies with water, physiological saline and iodine. The choice of the optimum energy was chosen based on the contrast mechanisms to know more about soft-matter and the associated internal complex biological features of the small animal shell. This way, the images at 27 keV (optimum energy) was reasonably acceptable for better visualization of the interior micro-architecture, such as soft-anatomy, physiology and internal organs of the animal with better visibility. The introduction of water, physiological, or iodine as contrast agents is shown to enhance minute image features in synchrotron-based tomographic imaging.
Subject(s)
Animal Shells/diagnostic imaging , Snails/anatomy & histology , Synchrotrons , X-Ray Microtomography/instrumentation , X-Ray Microtomography/methods , Animals , Contrast Media/chemistry , Imaging, Three-Dimensional , Iodine/chemistry , Sodium Chloride/chemistry , Water/chemistryABSTRACT
Synchrotron-based scattered radiation form low-contrast phantom materials prepared from polyethylene, polystyrene, nylon, and Plexiglas is used as test objects in X-ray CT was examined with 8, 10 and 12 keV X-rays. These phantom materials of medical interest will contains varying proportions of low atomic number elements. The assessment will allowed us to estimate the fluorescence to total scattered radiation. Detected the fluorescence spectra and the associated scattered radiation from calcium hydroxyapatite phantom with 8, 10 and 12 keV synchrotron X-rays. Samples with Bonefil (60% and 70% of calcium hydroxyapatite) and Bone cream (35 approximately 45% of calcium hydroxyapatite), were used. Utilized the X-ray micro-spectroscopy beamline facility, X27A, available at NSLS, BNL, USA. The primary beam with a spot size of the order of approximately 10 mum, has been used for focusing. With this spatial resolution and high flux throuput, the synchrotron-based scattered radiation from the phantom materials were measured using a liquid-nitrogen-cooled 13-element energy-dispersive high-purity germanium detector.
Subject(s)
Phantoms, Imaging , Scattering, Radiation , Synchrotrons , Tomography, X-Ray Computed/instrumentation , Durapatite/chemistry , Humans , Nylons/chemistry , Polyethylene/chemistry , Polymethyl Methacrylate/chemistry , Polystyrenes/chemistry , Spectrometry, Fluorescence , X-RaysABSTRACT
The introduction of water, physiological, or iodine as contrast agents is shown to enhance minute image features in synchrotron-based X-ray diffraction radiographic and tomographic imaging. Anatomical features of rat kidney, such as papillary ducts, ureter, renal artery and renal vein are clearly distinguishable. Olfactory bulb, olfactory tact, and descending bundles of the rat brain are visible with improved contrast.
Subject(s)
Contrast Media , Diagnostic Imaging/methods , Phantoms, Imaging , Synchrotrons , Animals , Diagnostic Imaging/instrumentation , RatsABSTRACT
Images of terrestrial and marine invertebrates (snails and bivalves) have been obtained by using an X-ray phase-contrast imaging technique, namely, synchrotron-based diffraction-enhanced imaging. Synchrotron X-rays of 20, 30 and 40keV were used, which penetrate deep enough into animal soft tissues. The phase of X-ray photons shifts slightly as they traverse an object, such as animal soft tissue, and interact with its atoms. Biological features, such as shell morphology and animal physiology, have been visualized. The contrast of the images obtained at 40keV is the best. This optimum energy provided a clear view of the internal structural organization of the soft tissue with better contrast. The contrast is higher at edges of internal soft-tissue structures. The image improvements achieved with the diffraction-enhanced imaging technique are due to extinction, i.e., elimination of ultra-small-angle scattering. They enabled us to identify a few embedded internal shell features, such as the origin of the apex, which is the firmly attached region of the soft tissue connecting the umbilicus to the external morphology. Diffraction-enhanced imaging can provide high-quality images of soft tissues valuable for biology.
Subject(s)
Connective Tissue/diagnostic imaging , Radiographic Image Interpretation, Computer-Assisted/instrumentation , Synchrotrons/instrumentation , X-Ray Diffraction/instrumentation , Animals , Bivalvia , Equipment Design , Equipment Failure Analysis , SnailsABSTRACT
Phase-contrast x-ray imaging with x-ray interferometer can depict the minute difference within the biological object, and its sensitivity is about 1000 times higher than that of absorption-contrast method. For biomedical use of this technique, a large monolithic x-ray interferometer and 2 crystal interferometer having a field of view with 25 mm x 25 mm is being developed. Phase-contrast x-ray CT could reveal detail structures within tumor and surrounded tissue, and the vessel imaging of rat liver is also possible using physiological saline at 17.7 keV x-ray energy. Recently, human breast tissues were imaged at 35 keV and the contrast of image was much better than usual absorption contrast x-ray image obtained at 17.7 keV energy.