The disclosure relates to a system and method for evaluating and calibrating detector in a scanner, further evaluating and calibrating time information detected by at least one time-to-digital convertor.

A method and apparatus are provided for positron emission imaging to correct a position at which a gamma ray was detected, when the gamma ray is scattered during detection. When Compton scattering occurs during detection of a gamma ray, the energy of the gamma ray deposited in multiple crystals in an array of detector elements. The corrected position is determined as a weighted sum of the position of the multiple crystals, each weighted by an inverse of the energy measured at the respective crystal. Further, the inverse-energy weight can be raised to a power p. A minimum energy threshold can be applied to determine the multiple crystals at which the gamma ray energy is deposited. The corrected position can be a floating position or can be rounded to a nearest crystal or to a nearest virtual sub-crystal.

A method for determining a correction profile of an imaging device may include obtaining first data relating to the imaging device; comparing the first data and a first condition; obtaining, based on the comparison, a first correction profile relating to the imaging device; and calibrating, based on the first correction profile, the imaging device.

A method for generating a nuclear image includes obtaining, via a camera, a surface image of a patient. A synthetic computed-tomography (CT) image of the patient is generated based on the surface image. First time-of-flight (TOF) data for the patient is obtained via a nuclear imaging modality. Attenuation correction is applied to the first TOF data. The synthetic image is applied as a density map during the attenuation correction. A nuclear image is generated from the attenuation corrected first TOF data.

In some embodiments, an apparatus and a system, as well as a method and an article, may operate to receive photons at inner surfaces of an array of tubes forming a columnar structure, the tubes including a material with substantially high density, wherein longitudinal axes of the tubes are substantially parallel. Further activities include directing the photons within the columnar structure to a position-sensitive detector to measure the photons, wherein the position-sensitive detector is divided into an array of pixels, and wherein individual ones of the tubes in the array of tubes maintain a fixed mechanical arrangement with individual ones of the array of pixels, to provide collimation of the photons from a first end of the tubes to a second end of the tubes coupled to the position-sensitive detector. Additional apparatus, systems, and methods are described.

This nuclear medical diagnosis apparatus acquires a normalization factor based on reference data of a reference object to be measured, acquires a mutual calibration factor using at least a part of the reference data, and calculates radioactive concentration of the reference object to be measured.

In some embodiments, an apparatus and a system, as well as a method, may operate to transform photons received at a scintillator into scintillation energy at a light yield efficiency of at least 30% at temperatures above 150 C. Further activities may include converting the scintillation energy to electron-hole pairs within a pixelated array of a position-sensitive detector having a bandgap of at least 2 eV. Additional apparatus, systems, and methods are described.

The disclosure relates to a system and method for reconstructing a PET image. The method may include: obtaining PET data relating to an object collected by a plurality of detector units; determining functional status of the plurality of detector units; generating reconstruction data based on the functional status of the respective detector units and the PET data; and reconstructing a PET image based on the reconstruction data.

This invention presents a new device to produce images of the gamma field, specially designed for circumstances requiring high efficiency and fast response imaging, by applying the concept of image extraction within a given field of view, through the combination of efficient gamma radiation detectors. Each detector is located inside a shielding, with an area of the detector with no shielding to enter the incident gamma radiation detector with a plurality of angles in relation to the normal outgoing central axis to the surface of the detector through the unshielded area, where that central axis is divergent in relation to the outgoing central axes of neighboring detectors.

A patient imaging system for creating visual representations for analysis includes an imaging source and a patient support disposed proximate the imaging source configured to receive and support the patient. An imaging device is disposed adjacent to the patient support and incorporates at least one detector, one or more slats cooperating with the at least one detector and a collimator disposed between the one or more slats and patient support having a plurality of links adjustably positionable on the collimator. The plurality of links receive and support imaging plates that may be adjusted to provide a variety of image settings such that the imaging device and imaging source define a pre-determined imaging volume in an imaging region for the patient positioned in the imaging system.