Abstract: Nuclear medicine (NM) multi-head imaging system includes a gantry defining a bore and a table positioned within the bore. The system also includes a plurality of detector units coupled to the gantry. Each of the detector units is configured to rotate about a unit axis. The plurality of detector units include first and second detector units. The system also includes at least one processor configured to execute programmed instructions stored in memory, wherein the at least one processor, when executing the programmed instructions, rotates the first and second detector units as the first and second detector units acquire image data and generates a composite persistence image based on the image data. The table is configured to be moved within the bore in response to inputs from a user or commands from the at least one processor.

Abstract: A system includes a detector and a main processing unit having an event processing module. The detector includes pixels to detect an event corresponding to photon absorption. The event processing module is configured to read event information for each event detected by each pixel of the detector in order of receipt from the detector and to compare an energy level value in the event information for each event to a predetermined range of energy level values. An event is counted when the energy level value is within the predetermined range of energy level values. For each event having an energy level below the predetermined range, the energy level value for a next consecutive event in the received event information is read and a combined energy level value of the event and the next consecutive event is determined as well as the pixel locations of the event and the next consecutive event.

Abstract: Methods and systems are provided for multi-window imaging. In one embodiment, a method comprises segmenting an image reconstructed from acquired projection data into segments, converting pixel values based on a mapping for each segment to generate converted segments, and outputting, to a display device, a composite image comprising a combination of the converted segments. The composite image includes a border delineating the converted segments. In this way, multiple windows collectively covering a large dynamic range may be combined into a single image.

Abstract: A customizable and upgradable imaging system is provided. Imaging detector columns are installed in a gantry to receive imaging information about a subject. Imaging detector columns can extend and retract radially as well as be rotated orbitally around the gantry. The gantry can be partially populated with detector columns and the detector columns can be partially populated with detector elements.

Abstract: A radiation detector head assembly is provided that includes a detector housing and a rotor assembly. The detector housing defines a cavity therein. The rotor assembly includes a detector unit, a body, and a sealing member. The body defines an opening oriented in the imaging direction. The body is disposed at a distance from the detector housing within the cavity defining a passageway extending axially along the body. The sealing member includes a body extending across the opening. The sealing member is coupled to at least one of the shielding unit or the collimator, and is mounted within the cavity to provide a gas-tight seal along the imaging direction between the passageway and the detector unit.

Abstract: A method is provided including identifying a target portion of a patient corresponding to a portion of interest of the patient to be scanned with a nuclear medicine scanning technique. The method also includes applying an uptake increasing technique to at least one of the target portion or an application portion of the patient other than the target portion. The uptake increasing technique is configured to increase uptake of a radiopharmaceutical to the target portion of the patient relative to portions of the patient other than the target portion. Also, the method includes administering the radiopharmaceutical to the patient temporally proximate to the applying an uptake increasing technique.

Abstract: Nuclear medicine (NM) multi-head imaging system includes a plurality of detector units coupled to a gantry. The detector units configured to face toward a center of the bore and including a series of first detector units and a second detector unit. The system also includes at least one processor that, when executing programmed instructions, performs the following operations. The at least one processor rotates the first detector units such that the first detector units face in a common first direction that is generally toward the bore. A working gap exists between the detector FOVs of the respective first detector units. The at least one processor rotates the second detector unit such that the second detector unit faces in a second direction that is opposite the first direction. The detector FOV of the second detector unit covers the working gap.

Abstract: Various methods and systems are provided for a detector head for an imaging system. The detector head comprises a detector module comprising at least one detector element for detecting radiation and detector electronics, and a shaft to which the detector module is coupled, the detector module configured to rotate more than 360 degrees about the shaft in at least one direction.

Abstract: A nuclear medicine (NM) multi-head imaging system is provided that includes a gantry, plural detector units, and at least one processor. The gantry defines a bore configured to accept an object to be imaged. The plural detector units are mounted to the gantry. Each detector unit defines a corresponding view oriented toward a center of the bore, and is configured to acquire imaging information over a sweep range. The at least one processor is configured to dynamically determine at least one boundary of an acquisition range corresponding to an uptake value of the object to be imaged for at least one of the detector units. The acquisition range is smaller than sweep range. The at least one processor is also configured to control the at least one detector unit to acquire imaging information over the acquisition range.

Abstract: A medical imaging system is provided. The imaging system provides patient region-of-interest scanning using a step-staggered detector unit arrangement. A region-of-interest may be a brain. This system can be a Nuclear Medicine (NM) imaging system to acquire Single Photon Emission Computed Tomography (SPECT) image information. The imaging system may comprise CZT detector modules.

Abstract: A radiation detector head assembly is provided that includes a detector housing and a detector unit. The detector housing defines a cavity therein. The detector housing includes a shell and a shielding body. The shell defines at least a portion of a perimeter surrounding the shielding body, and includes an extrusion defining the at least a portion of a perimeter. The extrusion is formed from a first material that is configured for rigidity. The shielding body includes a second material configured to shield radiation. The detector unit is disposed within the cavity, and includes an absorption member and associated processing circuitry.

Abstract: A radiation detector head assembly is provided that includes a detector housing and a detector unit The detector housing defines a cavity therein. The detector housing includes a shell and a shielding body. The shell defines at least a portion of a perimeter surrounding the shielding body, and includes an extrusion defining the at least a portion of a perimeter. The extrusion is formed from a first material that is configured for rigidity. The shielding body includes a second material configured to shield radiation. The detector unit is disposed within the cavity, and includes an absorption member and associated processing circuitry.

Abstract: A radiation detector head assembly is provided that includes a detector housing and a rotor assembly. The detector housing defines a cavity therein. The rotor assembly includes a detector unit, a body, and a sealing member. The body defines an opening oriented in the imaging direction. The body is disposed at a distance from the detector housing within the cavity defining a passageway extending axially along the body. The sealing member includes a body extending across the opening. The sealing member is coupled to at least one of the shielding unit or the collimator, and is mounted within the cavity to provide a gas-tight seal along the imaging direction between the passageway and the detector unit.

Abstract: A medical imaging system is provided. The imaging system provides patient region-of-interest scanning using a step-staggered detector unit arrangement. A region-of-interest may be a brain. This system can be a Nuclear Medicine (NM) imaging system to acquire Single Photon Emission Computed Tomography (SPECT) image information. The imaging system may comprise CZT detector modules.

Abstract: A detector arm assembly is provided that includes a stator, a detector head, a radial motion motor, and a detector head belt. The stator is configured to be fixedly coupled to a gantry having a bore. The detector head includes a carrier section that is slidably coupled to the stator and configured to be movable in a radial direction in the bore relative to the stator. The radial motion motor is operably coupled to at least one of the detector head or the stator. The detector head belt is operably coupled to the radial motion motor and the carrier section. Rotation of the radial motion motor causes movement of the detector head in the radial direction.

Abstract: Apparatus and methods for computed tomography (CT) imaging are provided. One method includes providing a patient table to move along an examination axis of a rotating gantry of a CT imaging system having at least one imaging detector. The imaging detector includes a pixelated detector array. The method further includes configuring the CT imaging system to perform an overlapping helical CT scan by controlling a speed of the moving patient table along the examination axis through a field of view (FOV) of the at least one imaging detector of the rotating gantry.

Abstract: An imaging system is provided including a plurality of detector units and a controller. The plurality of detector units are distributed about a bore. The bore is configured to accept an object to be imaged, and the detector units are radially articulable within the bore. The controller is operably coupled to the plurality of detector units and configured to control the positioning of the detector units. The controller is configured to position an external group of the plurality of detector units at a predetermined intermediate position corresponding to a ring having a radius corresponding to a total number of detector units, and to position an internal group of the plurality of detector units radially inside the ring.

Abstract: Methods and apparatus for imaging with detectors having moving heads are provided. One apparatus includes a gantry and a plurality of detector units mounted to the gantry. At least some of the plurality of detector units are movable relative to the gantry to position one or more of the detector units with respect to a subject. The detector units are movable along parallel axes with respect to each other.

Abstract: A system includes a detector and a main processing unit having an event processing module. The detector includes pixels to detect an event corresponding to photon absorption. The event processing module is configured to read event information for each event detected by each pixel of the detector in order of receipt from the detector and to compare an energy level value in the event information for each event to a predetermined range of energy level values. An event is counted when the energy level value is within the predetermined range of energy level values. For each event having an energy level below the predetermined range, the energy level value for a next consecutive event in the received event information is read and a combined energy level value of the event and the next consecutive event is determined as well as the pixel locations of the event and the next consecutive event.

Abstract: A method and apparatus for defining a volume of interest in a physiological image based upon an anatomical image. The method and system acquires an anatomical image of a volume of interest using a first imaging modality. A physiological image is acquired using a second imaging, modality different from the first imaging modality. An outline of the volume of interest is defined on the anatomical image and applied to the physiological image to define the volume of interest m the physiological image, Based upon the outline, the system and method assigns binary values to voxels within the outline to more accurately define the volume of interest.