Abstract: A system and method for a lidar guided patient positioning are described. An example imaging system includes a gantry having a bore, a table to move a subject relative to the bore, a radiation source mounted on the gantry and to emit an X-ray beam, and a detector to detect the X-ray beam. The system further includes a light detection and ranging (LiDAR) scanning system to acquire data of the subject. The system further includes processing circuitry to process the LiDAR data to generate a 3D point cloud representing a topography of the subject, estimate a center of a region of interest of the subject, calculate an offset of the center of the region of interest relative to an isocenter of the gantry, and adjust a height of the table based on the offset to align the center of the region of interest with the isocenter of the gantry.

Abstract: A system and a method for maintaining an X-ray focal spot position at a desired location on an X-ray detector of an X-ray imaging system include obtaining, via processing circuitry, a scan protocol for performing an X-ray scan with the X-ray imaging system. The system and the method also include determining, via the processing circuitry, a bending magnet current value to utilize to maintain the X-ray focal spot position of an X-ray beam emitted from an X-ray tube of the X-ray imaging system at the desired location on the X-ray detector based on a plurality of acquisition parameters of the X-ray scan. The system and the method further include utilizing, via the processing circuitry, the bending magnet current value during the X-ray scan to maintain the X-ray focal spot position at the desired location on the X-ray detector.

Abstract: A method includes receiving data acquired with a light detection and ranging (LiDAR) scanning system physically coupled to a computed tomography (CT) imaging system of a subject to be imaged disposed on a cradle of a table, wherein the table is configured to move the subject into and out of a bore of a gantry of the CT imaging system. The method also includes generating a multi-dimensional avatar of the subject representing a topography of the subject. The method further includes causing display of the multi-dimensional avatar positioned on the cradle that represents a current position of the subject on the display, wherein the display is disposed adjacent the table within view of the subject. The method even further includes providing instructions on the display to enable the subject to guide themselves to a target position on the cradle for a CT scan with the CT imaging system.

Abstract: A method includes receiving data acquired with a light detection and ranging (LiDAR) scanning system physically coupled to a computed tomography (CT) imaging system of a subject to be imaged disposed on a cradle of a table, wherein the table is configured to move the subject into and out of a bore of a gantry of the CT imaging system. The method also includes generating a multi-dimensional avatar of the subject representing a topography of the subject. The method further includes causing display of the multi-dimensional avatar positioned on the cradle that represents a current position of the subject on the display, wherein the display is disposed adjacent the table within view of the subject. The method even further includes providing instructions on the display to enable the subject to guide themselves to a target position on the cradle for a CT scan with the CT imaging system.

Abstract: A system and a method for maintaining an X-ray focal spot position at a desired location on an X-ray detector of an X-ray imaging system include obtaining, via processing circuitry, a scan protocol for performing an X-ray scan with the X-ray imaging system. The system and the method also include determining, via the processing circuitry, a bending magnet current value to utilize to maintain the X-ray focal spot position of an X-ray beam emitted from an X-ray tube of the X-ray imaging system at the desired location on the X-ray detector based on a plurality of acquisition parameters of the X-ray scan. The system and the method further include utilizing, via the processing circuitry, the bending magnet current value during the X-ray scan to maintain the X-ray focal spot position at the desired location on the X-ray detector.

Abstract: A computer-implemented method includes obtaining, at a processor, a tomographic image of a phantom, wherein the phantom includes heterogeneous regions having a plurality of materials with varying attenuation coefficients. The method also includes automatically segmenting, via the processor, the heterogeneous regions from the tomographic image to generate a segmented image. The method further includes automatically identifying, via the processor, a plurality of regions of interest having varying attenuation coefficients within the tomographic image based on the segmented image. The method still further includes automatically labeling, via the processor, each region of interest of the plurality of regions of interest as representing a particular material of the plurality of materials. The method even further includes outputting, via the processor, a labeled image of the tomographic image. The method may be utilized in quality assurance testing and calibration.

Abstract: A computer-implemented method includes generating an image from scan data acquired during a non-diagnostic scan utilizing a computed tomography scanner. The computer-implemented method also includes performing object segmentation based on pixel connectivity on the image to generate segmented regions. The computer-implemented method further includes characterizing pixel connectivity properties of the segmented regions. The computer-implemented method still further includes obtaining respective bounding shape coordinates and area for bounding shapes of the segmented regions.

Abstract: A method for verifying aperture positions of a pre-patient collimator of a computed tomography (CT) imaging system includes obtaining data collected by an X-ray measurement device having detector elements subjected to X-rays emitted from an X-ray source of the CT imaging system with the pre-patient collimator at an expected aperture position. The method also includes calculating a measured collimator aperture position for the pre-patient collimator based on the obtained data. The method further includes comparing the measured collimator aperture position to a system specification for the expected aperture position for the CT imaging system. The method even further includes generating an output based on the comparison of the measured collimator aperture position to the system specification.

Abstract: A computer-implemented method includes obtaining, at a processor, a tomographic image of a phantom, wherein the phantom includes heterogeneous regions having a plurality of materials with varying attenuation coefficients. The method also includes automatically segmenting, via the processor, the heterogeneous regions from the tomographic image to generate a segmented image. The method further includes automatically identifying, via the processor, a plurality of regions of interest having varying attenuation coefficients within the tomographic image based on the segmented image. The method still further includes automatically labeling, via the processor, each region of interest of the plurality of regions of interest as representing a particular material of the plurality of materials. The method even further includes outputting, via the processor, a labeled image of the tomographic image. The method may be utilized in quality assurance testing and calibration.

Abstract: A method for verifying aperture positions of a pre-patient collimator of a computed tomography (CT) imaging system includes obtaining data collected by an X-ray measurement device having detector elements subjected to X-rays emitted from an X-ray source of the CT imaging system with the pre-patient collimator at an expected aperture position. The method also includes calculating a measured collimator aperture position for the pre-patient collimator based on the obtained data. The method further includes comparing the measured collimator aperture position to a system specification for the expected aperture position for the CT imaging system. The method even further includes generating an output based on the comparison of the measured collimator aperture position to the system specification.

Abstract: Methods and systems are provided for improving image quality with three-dimensional (3D) scout scans for computed tomography (CT) imaging. In one embodiment, a method comprises reconstructing an image from projection data acquired during a diagnostic scan of a patient with corrections based on scout projection data acquired during a 3D scout scan of the patient. In this way, the image quality of a diagnostic image can be improved by using 3D scout data to correct projection data or image data.

Abstract: Methods and systems are provided for indirectly measuring a current of a radiation source. In one embodiment, a method comprises generating a scan dataset by transmitting a radiation from a radiation source directly to a detector; calculating a signal to noise ratio of the scan dataset; and determining a current that was used to generate the scan dataset based on the calculated signal to noise ratio. In this way, current of the radiation source may be evaluated without connecting extra equipment to the radiation source.

Abstract: A patient support system includes a support beam that may translocate along an axial axis of a medical imaging system. At least a portion of the support beam may be disposed within a central bore of the medical imaging system. The patient support system also includes a patient support removably coupled to the support beam and including a backing that may support a patient during an imaging procedure and a restraint extending a longitudinal length of the backing. The restraint includes a first end coupled to the backing and a second end that may be removably coupled to the support beam, and the restraint may secure the patient support to the support beam and to restrain the patient within the patient support.

Abstract: The present approach relates to detection of image artifacts symptomatic of needed calibration and/or failing hardware with no or limited human intervention, such as using machine learning. Detection of image artifacts can occur as part of normal imaging system operation and/or as part of a quality assessment of a newly manufactured or already installed system. Detection of image artifacts can adapt or learn as new scans are acquired using supervised or semi-supervised learning. Assessment of system imaging performance in the recently manufactured as well as the installed base can be performed reliably and automatically.

Abstract: Methods and systems are provided for improving image quality with three-dimensional (3D) scout scans for computed tomography (CT) imaging. In one embodiment, a method comprises reconstructing an image from projection data acquired during a diagnostic scan of a patient with corrections based on scout projection data acquired during a 3D scout scan of the patient. In this way, the image quality of a diagnostic image can be improved by using 3D scout data to correct projection data or image data.

Abstract: Methods and systems are provided for indirectly measuring a current of a radiation source. In one embodiment, a method comprises generating a scan dataset by transmitting a radiation from a radiation source directly to a detector; calculating a signal to noise ratio of the scan dataset; and determining a current that was used to generate the scan dataset based on the calculated signal to noise ratio. In this way, current of the radiation source may be evaluated without connecting extra equipment to the radiation source.

Abstract: A patient support system includes a support beam that may translocate along an axial axis of a medical imaging system. At least a portion of the support beam may be disposed within a central bore of the medical imaging system. The patient support system also includes a patient support removably coupled to the support beam and including a backing that may support a patient during an imaging procedure and a restraint extending a longitudinal length of the backing. The restraint includes a first end coupled to the backing and a second end that may be removably coupled to the support beam, and the restraint may secure the patient support to the support beam and to restrain the patient within the patient support.

Abstract: A tilting head support for use in medical imaging is described. The tilting head support allows a patient to receive the equivalent of a tilted gantry exam study even when using a scanner gantry that does not tilt. In certain embodiments, the tilted head support assembly has metallic or sharp edge components, if present, positioned outside the imaging area when in use. In addition, in certain embodiments, the tilted head support assembly allows for user selection of a tilt angle from among a continuous range of available angles.

Abstract: A tilting head support for use in medical imaging is described. The tilting head support allows a patient to receive the equivalent of a tilted gantry exam study even when using a scanner gantry that does not tilt. In certain embodiments, the tilted head support assembly has metallic or sharp edge components, if present, positioned outside the imaging area when in use. In addition, in certain embodiments, the tilted head support assembly allows for user selection of a tilt angle from among a continuous range of available angles.

Abstract: An apparatus and method for calibrating an x-ray tube include a computer programmed to acquire a starter voltage/current value corresponding to a width, a length, or a position of a target focal spot capable of being generated by the x-ray tube. The computer is programmed to generate an electron beam and to steer the electron beam based on the starter voltage/current value. The computer is also programmed to steer the electron beam based on a value adjusted from the starter voltage/current value. The computer is programmed to calculate a final voltage/current value that is configured to generate the width, length, or position of the target focal spot based on the starter voltage/current value and the adjusted starter voltage/current value.