Systems for providing oncological services to animals are provided. The system includes a transportation vehicle configured to be driven under its own power. The transportation vehicle includes an outer frame housing a plurality of rooms. The plurality of rooms includes an examination room configured to enable a medical professional to medically examine and perform medical diagnostic testing one or more animals, a chemotherapy treatment room configured to enable the medical professional to perform one or more oncological treatments on the one or more animals, and a changing room configured to enable the medical professional to don or doff personal protective equipment.

An embodiment in accordance with the present invention provides a device and method for a quantitatively calibrated computed tomography scanner. The device includes a gantry configured for receiving a patient or part of a patient. The gantry includes an X-ray source and a detector positioned opposite said X-ray source, such that said detector receives the X-rays emitted from the X-ray source. Calibration phantoms are integrated with the gantry and/or a device within the scanner so as to allow for calibration in quantitative CT measurements of Hounsfield units and/or bone mineral density.

Systems and process are provided to make X-ray radiographs sufficiently quantitative and standardized for bone and other biological material or non-biologic material density evaluations. The X-ray radiograph methodology and system provide a cost effective diagnostic tool that may be used with existing X-ray radiography sources already present in many clinics and hospitals to ultimately produce large volumes of scientifically valid data and useful diagnostic and prognostic information. A calibration bar is added to a conventional X-ray film cartridge and images thereof subsequently incorporated into radiographs for interpretation or a cartridge is designed to integrate a calibration function. The calibration standard affords a standard against which material density is measured. A software program is provided to interpret tissue densities (including bone) to ultimately identify values compared to preselected thresholds.

In certain embodiments, a method includes accessing, in response to a first user input and via an equine records storage system, digital equine records for equines that include equine data for the equines. The equine data includes equine inventory data, certification data, and health data. The method includes generating, according to the equine inventory data and health data, an equine inventory user interface that includes identifying information of a first equine and health information for the first equine. The method includes accessing, in response to a second user input and via the storage system, the equine certification data, and generating, according to the equine certification data, an equine certifications user interface that includes certifications of the first equine. The method includes receiving, via the equine inventory user interface, equine inventory update data, and, in response, transmitting an equine inventory update to the storage system for updating the equine inventory data.

A mobile diagnostic imaging system includes a battery system and charging system. The battery system is located in the rotating portion of the imaging system, and includes one or more battery packs, comprising electrochemical cells. Each battery pack includes a control circuit that controls the state of charge of each electrochemical cell, and implements a control scheme that causes the electrochemical cells to have a similar charge state. The battery system communicates with a charging system on the non-rotating portion to terminate charge when one or more of the electrochemical cells reach a full state of charge. The imaging system also includes a docking system that electrically connects the charging system to the battery system during charging and temporarily electrically disconnects the rotating and non-rotating portions during imaging, and a drive mechanism for rotating the rotating portion relative to the non-rotating portion.

The present invention is directed towards isolated antibodies that bind to GRP78 and TIP-1.

The invention is a tomographic apparatus, in particular for examining a brain or a limb of a human and/or a primate animal, the apparatus (10) comprising an examination space (16) adapted for receiving a subject of a tomographic examination, and a PET ring (12) and a second imaging arrangement, being arranged around the examination space (16) in a substantially coaxial manner. The tomographic apparatus according to the invention comprises a PET ring (12) being displaceable between a PET operational state and a PET non-operational state, and comprises a second imaging arrangement adapted for being brought from a second imaging non-operational state to a second imaging operational state in the PET non-operational state of the PET ring (12).

A radiological imaging device configured to analyze a limb includes a first module that includes a source configured to emit radiation, a second module that includes a detector configured to receive radiation from the source that has passed through the limb, a control station connected to the first and second modules for controlling movement of the first and second modules and acquiring images from the second module, and a platform having an outer support surface to support the first and second modules. The control station includes a casing and a connecting member that is connected to the casing to attach the platform. The platform is suitable to rotate around an axis approximately parallel to the outer surface.

A method and system for processing imaging data of a tissue in an individual following a change in oxygenation or blood flow in tissue, for assessing tissue function. Test images are registered with a baseline image, providing registered images. The registered images may be compared to assess variations in the change in the tissue in response to changes in oxygenation or blood flow of the tissue shown in the images. The change in oxygenation or blood flow in the tissue may be quantified and plotted in a parametric plot or displayed in a parametric map to assess whether the change in oxygenation or blood flow, corresponding to a change in signal intensity, is abnormal following a stress event or under other conditions, to assess microvascular or macrovascular function.

An integrated microtomography and optical imaging system includes a rotating table that supports an imaging object, an optical stage, and separate optical and microtomography imaging systems. The table rotates the imaging object about a vertical axis running therethrough to a plurality of different rotational positions during a combined microtomography and optical imaging process. The optical stage can be a trans-illumination, epi-illumination or bioluminescent stage. The optical imaging system includes a camera positioned vertically above the imaging object. The microtomography system includes an x-ray source positioned horizontally with respect to the imaging object. Optical and x-ray images are both obtained while the imaging object remains in place on the rotating table. The stage and table are included within an imaging chamber, and all components are included within a portable cabinet. Multiple imaging objects can be imaged simultaneously, and side mirrors can provide side views of the object to the overhead camera.