Patent application number | Description | Published |
20080281192 | METHOD AND APPARATUS FOR REAL-TIME TARGET POSITION ESTIMATION BY COMBINING X-RAY AND EXTERNAL RESPIRATORY SIGNALS - A method and system are disclosed for estimating internal position information of a target in real-time based on a single gantry-mounted x-ray imager and a respiratory signal. The x-ray imaging is done periodically to limit radiation dosage. Initial parameters for the estimation model are determined in a pre-treatment session using four dimensional computed tomography (4D CT) in combination with a respiratory signal acquired from the patient. The model parameters are updated during treatment based on the periodic x-ray image data and the respiratory signal. | 11-13-2008 |
20090208074 | 3D real-time tracking of human anatomy using combined kV and MV imaging - A medical imaging-based system and method uses both kV and MV images captured during a treatment period for organ motion tracking. 3D geometric locations of internal features are computationally tracked as a function of time from internal features, such as natural biological features or implanted fiducials, which are computationally extracted from the captured kV and MV images. A partial information method allows 3D tracking to be maintained in the event that imaging information is temporarily not available. | 08-20-2009 |
20100239066 | Configurations for integrated MRI-linear accelerators - The present invention provides a radiotherapy treatment apparatus that includes a treatment beam, a magnetic field disposed parallel collinear to the treatment beam, and a target that is disposed along the treatment beam. The treatment beam can be a charged particle beam, a proton beam, an electron beam, or a linear accelerator (Linac) beam. The magnetic field is from a magnetic resonance imager (MRI), a megavolt x-ray imager, or a kilovolt x-ray imager and is disposed to operate in coordination with operation of the treatment beam and to narrow the beam. The tumor is disposed to rotate with respect to the treatment beam and the magnetic field, or the treatment beam and the magnetic field are disposed to rotate up to 360° with respect to the target when mounted to a ring gantry. The apparatus can include a rotation angle dependent shim disposed to account for Earth's magnetic field. | 09-23-2010 |
20100316259 | Using a moving imaging system to monitor anatomical position as a function of time - Real-time 3D tracking of anatomical positions during radiation therapy uses acquired image data from an MV treatment beam as it is rotated around the patient during arc radiotherapy treatment. The acquired image data and associated angular positions are computationally combined during the arc radiotherapy treatment to estimate in real time 3D positions of anatomical features of the patient, e.g., combining present image data and prior image data at earlier times. Supplementary image data from a kV imaging system may be acquired on an as-needed basis if MV position estimates indicate movement exceeding a predetermined threshold, and the supplementary kV image data combined with the acquired MV image data to improve an accuracy of the estimated 3D positions. | 12-16-2010 |
20110075807 | Intrafraction motion management using a rough to accurate monitoring strategy - An adaptive imaging method of monitoring intrafraction target motion during radiation therapy is provided that includes using a simultaneous Mega-Voltage (MV) imaging process and Kilo-Voltage (KV) imaging process to determine an initial 3D target position. 2D target position is monitored using the MV imaging process during a radiation therapy treatment delivery, and is in combination with an online-updated characterization of target motion that are disposed to estimate if the target has moved beyond a 3D threshold distance. The simultaneous MV imaging and KV imaging processes are for accurately determining a new 3D target position for intrafraction motion compensation and for further 2D imaging by the MV imaging process, where another simultaneous MV and KV imaging process is initiated when the target has potentially moved beyond the threshold distance as measured by the MV imaging process. The intrafraction target motion monitoring is achieved at the cost of ultralow patient imaging dose. | 03-31-2011 |
20110075911 | Accurate determination of the shape and localization of metallic object(s) in X-ray CT imaging - A binary image reconstruction method is provided to identify metal objects in a computer tomography (CT) image. The method includes providing a suitably programmed computer, providing a CT image, where the CT image includes intensity data, and the suitably programmed computer is used to determine a first range of attenuation coefficient values and a second range of attenuation coefficient values in the intensity data, where when a difference between the first range of attenuation coefficient values and the second range of attenuation coefficient values is less than a pre-determined gradient threshold value, a boundary of a metal object in the CT image is determined. | 03-31-2011 |
20110085643 | Radiation therapy inverse treatment planning using a regularization of sparse segments - A method of reducing a total number of beam segments in a dose distribution for a radiation therapy field is provided. The method includes providing a multiobjective radiation therapy treatment plan using a suitably programmed computer, where the multiobjective radiation therapy treatment plan includes a radiation beam dose performance objective and a fluence map sparsity objective in a given fluence function domain, and providing a Pareto frontier of tradeoff criteria between the beam dose performance and a total number of radiation segments (or sub-fields) of the multiobjective radiation therapy treatment plan using the suitably programmed computer, where an achieved set of radiation beam dose distributions associated with efficiency points of the Pareto frontier are evaluated using a clinical acceptance criteria, where a clinically acceptable radiation beam dose distribution having a smallest number of the multileaf collimator segments is a final solution for the multiobjective radiation therapy treatment plan. | 04-14-2011 |
20110250128 | Method for tissue characterization based on beta radiation and coincident Cherenkov radiation of a radiotracer - A method of characterizing a tissue sample is provided that includes injecting a tissue sample with radiotracers, where the radiotracers include beta-emitter radio tracers, the beta-emitter radio tracers emit beta particles according to a decay of the beta-emitter radio tracers, and measuring the beta particles or Cherenkov radiation from the beta particles in the tissue sample, and determining a condition of the radio tracers in the tissue sample according to the measured beta particles or the measured Cherenkov radiation, where the determined condition includes a depth and/or a concentration of the radiotracers in the tissue sample. | 10-13-2011 |
20110251484 | Molecular imaging using radioluminescent nanoparticles - Molecular imaging of radioluminescent nanoparticle probes injected into biological tissue is performed by irradiated the tissue with ionizing radiation to induce radioluminescence at optical wavelengths, preferably at predetermined near infrared wavelengths. The optical light is detected and processed to determine a spatial distribution of the probes. The radioluminescent nanoparticles may be inorganic or organic phosphors, scintillators, or quantum dots. Imaging systems realizing this technique include tomographic systems using an x-ray beam to sequentially irradiate selected regions, systems with a radioactive source producing the ionizing radiation from outside the tissue, such as with a beam, or inside the tissue, such as with an endoscope or injected radiopharmaceutical. The optical signals may be detected by a photodetector array external to the tissue, a photodetector integrated with an endoscope or mammographic paddle, integrated into a capsule endoscope, or an array positioned near the biological tissue. | 10-13-2011 |
20120207370 | Systems and Methods for Simultaneous Acquisition of Scatter and Image Projection Data in Computed Tomography - A method of acquiring scatter data and image projection data in computed tomography is provided that includes attenuating a radiation source using a pattern of blockers arranged to provide blocked and unblocked regions of the radiation source, and acquiring image data and scatter data of a target using an imaging device. A scatter map in the projection image can be estimated by interpolation and/or extrapolation of the projection image using an appropriately programmed computer, subtracting the estimated scatter map from the projection image to obtain scatter-corrected projections, reconstructing a CBCT volume using a total variation regularization algorithm, and applying an iterative regularization process to suppress the noise level on the reconstructed CBCT volume. Reconstructing a CBCT volume can include using a total variation regularization algorithm and applying an iterative regularization process to suppress the noise level on the reconstructed CBCT volume, where scatter-induced artifacts are corrected in the projection image. | 08-16-2012 |
20120292534 | Multi-phase Gating for Radiation Treatment Delivery and Imaging - A multi-phase radiation therapy treatment method is provided that includes computational software to simultaneously optimize radiation plans for each phase of delivery. A specific realization of multi-phase therapy, dual gating, is described where the first radiation therapy treatment plan provides treatment during an inhale phase of a patient breathing cycle and the second radiation therapy treatment plan provides treatment during an exhale phase of the patient breathing cycle. Using a radiation therapy machine, the first radiation therapy treatment plan is delivered during the inhale phase and the second radiation therapy treatment plan is delivered during the exhale phase of the patient breathing cycle. An associated imaging method is provided for gated volumetric image guidance at multiple different phases in a single imaging acquisition. | 11-22-2012 |
20130142310 | DYNAMIC MULTI-AXES TRAJECTORY OPTIMIZATION AND DELIVERY METHOD FOR RADIATION TREATMENT - Embodiments of the present invention provide methods for improved radiation treatment and imaging of solid cancers utilizing radiation beam trajectory optimization techniques to obtain conformal radiation coverage of tissue that is targeted to receive radiation, while minimizing exposure of healthy tissue and organs to harmful, unnecessary radiation. | 06-06-2013 |
20140242600 | IMAGING THE HETEROGENEOUS UPTAKE OF RADIOLABELED MOLECULES IN SINGLE LIVING CELLS - A radioluminescence microscopy system and method for imaging the distribution of radiolabeled molecules in live cell cultures and tissue sections. Cells are grown and incubated with radiolabeled molecules on a scintillator plate or a scintillator plate is placed adjacent to the cells after incubation. Scintillation light produced by decay of radiolabeled molecules inside, bound to, or surrounding the cells, is recorded on an imaging device. Fluorescence microscopy of the same cells with other types of molecules of interest that are labeled with different fluorophores can be conducted concurrently and the biological activity of the labeled molecules can be correlated. | 08-28-2014 |
20140330064 | Station parameter optimized radiation therapy (SPORT): a novel scheme for treatment planning and delivery in radiation therapy - A method of radiation therapy planning and delivery is provided that includes introducing a demand metric, using a volumetric modulation arc therapy system, to select a spatially optimized and non-uniform set of station or control points to be used for intensity modulation, where the set of station or control points are uniform or non-uniform, and selecting a set of control points at different gantry angles, using the volumetric modulated arc therapy system, and using the demand metric to prioritize which station or control point receives intensity modulation, where the volumetric modulated arc therapy system is differentially boosted at selected angles by inserting additional segments to the station, where the inserted additional apertures dosimetrically boost desired regions in a planning target volume to improve planning target volume coverage in a single arc rotation while sparing sensitive structures. | 11-06-2014 |