Abstract: Disclosed embodiments are directed to reducing the likelihood of intra-operative shedding. Specifically, disclosed embodiments utilize injected magnetic nanoparticles and magnets to confine tumor cells to the surgical bed in order to prevent the cells from being released into the general circulation and/or lymphatics.

Abstract: An electromagnetic structure is fabricated by additive manufacturing having at least one channel traversing the structure. In one embodiment, at least one form contains apertures and/or holes forming the channel and a liquid metal traverses the structure by the channel. Electrodes are provided to apply or extract electrical voltage or power to and/or from the liquid metal as well as a mechanism for propelling a portion of the liquid metal through the form. In an alternative embodiment, both the electrically insulating and the electrically conductive materials are solid and the channel is used for conducting a coolant instead of the liquid metal.

Abstract: Silicon drift detectors are produced for location and energy measurement as well as spectroscopic applications by depositing a single high quality dielectric film followed by deposition of at least one low quality dielectric film.

Abstract: A method and apparatus for performing computed tomography in medical imaging through reconstruction of a data set containing projections obtained during relative motions a container or body of interest with respect to an x-ray source and/or x-ray detector panel. Strobing of the data is implemented through one or more methods to include pulsing of the x-ray source, intermittent blanking of the x-ray detector panel, or intermittent processing of data collected from the detector panel to simulate blanking. The invention is utilized to significantly improve contrast by taking advantage of the pulsed nature of the source to implement three-dimensional reconstruction.

Abstract: A magnetic field generator includes a power source and a segmented or un-segmented coil connected to the power source to generate a time-varying magnetic field. Energy is applied to the coil so that the coil generates a time-varying magnetic field gradient with a magnitude of at least 1 milliTesla per meter and a rise-time of less than 10 microseconds. The coil may be comprised of overlapping, non-overlapping or partially overlapping coil segments that may individually energized to further improve the operating characteristics of the coil to further decrease bio-effects in magnetic resonance imaging through the use of reduced pulse lengths and multi-phasic magnetic gradient pulses.

Abstract: A method and apparatus for closing a gap between tissues, comprising introducing a device head into the gap, applying a force to a portion of one tissue with the device head, applying a force to a portion of the other tissue with the device head, moving, via the device head, the first tissue into close proximity to the second tissue, maintaining, for a predetermined period of time via the device head, the one tissue and the other tissue in close proximity until the portion of the one tissue and the portion of the other tissue become cellularly adhered to one another, thereby forming a cellular aggregate connecting the tissues, and releasing from the device head the portion of the one tissue, the portion of the other tissue, and the cellular aggregate after a predetermined period of time of less than about one minute.

Abstract: A fluorometer includes a light source to generate excitatory light toward a tissue, the tissue generating fluorescent light in response to the excitatory light. The fluorometer also includes a light sensor to receive the fluorescent light and generate a digital signal. A processor is connected to the light sensor to receive the digital signal and generate a digital image, and a display displays the digital image. The tissue generates fluorescent light as a result of excitation of at least one intrinsic tissue metabolic product. A method for distinguishing between viable and non-viable tissue using the fluorometer also is described.