Anger camera: Difference between revisions
imported>Howard C. Berkowitz (New page: {{subpages}} Developed by electronic engineer Hal O. Anger, the '''Anger camera''' is really a series of evolving implementations to form images from gamma rays. Anger's first approac...) |
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Developed by electronic engineer Hal O. Anger, the '''Anger camera''' is really a series of evolving implementations to form images from [[gamma ray]]s. Anger's first approach used lead pinholes to direct gammas directly onto photographic film, but this was extremely slow and unsafe in the clinical applications involved. His major advance came when he placed an array of lead | Developed by electronic engineer Hal O. Anger, the '''Anger camera''' is really a series of evolving implementations to form images from [[gamma ray]]s. Anger's first approach used lead pinholes to direct gammas directly onto photographic film, but this was extremely slow and unsafe in the clinical applications involved. His major advance came when he placed an array of lead [[collimator]]s in front of large single scintillating crystal -- a material, such as [[sodium iodide]], that emitted light when struck by gammas -- and put an array of [[photomultiplier tube]]s on the back of the crystal. | ||
The intensity of the light was proportional to the energy of the gamma photons striking the crystal. In generating the image from the scintillation patterns, the photomultiplier pulses were integrated and formed into a false-color image; the collimator and filters could exclude light from photons of energy levels not of interest. | The intensity of the light was proportional to the energy of the gamma photons striking the crystal. In generating the image from the scintillation patterns, the photomultiplier pulses were integrated and formed into a false-color image; the collimator and filters could exclude light from photons of energy levels not of interest. | ||
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Anger cameras are the basic image-forming devices in a wide range of instruments in [[nuclear medicine]], especially the [[Single-Photon Emission-Computed Tomography]] (SPECT) and [[Positron-Emission Computed Tomography]] (PET). | Anger cameras are the basic image-forming devices in a wide range of instruments in [[nuclear medicine]], especially the [[Single-Photon Emission-Computed Tomography]] (SPECT) and [[Positron-Emission Computed Tomography]] (PET). | ||
Evolving versions use multiple scintillating crystals, which may be integrated into a solid-state light amplifier. | Evolving versions use multiple scintillating crystals, which may be integrated into a solid-state light amplifier.[[Category:Suggestion Bot Tag]] |
Latest revision as of 17:00, 10 July 2024
Developed by electronic engineer Hal O. Anger, the Anger camera is really a series of evolving implementations to form images from gamma rays. Anger's first approach used lead pinholes to direct gammas directly onto photographic film, but this was extremely slow and unsafe in the clinical applications involved. His major advance came when he placed an array of lead collimators in front of large single scintillating crystal -- a material, such as sodium iodide, that emitted light when struck by gammas -- and put an array of photomultiplier tubes on the back of the crystal.
The intensity of the light was proportional to the energy of the gamma photons striking the crystal. In generating the image from the scintillation patterns, the photomultiplier pulses were integrated and formed into a false-color image; the collimator and filters could exclude light from photons of energy levels not of interest.
Anger cameras are the basic image-forming devices in a wide range of instruments in nuclear medicine, especially the Single-Photon Emission-Computed Tomography (SPECT) and Positron-Emission Computed Tomography (PET).
Evolving versions use multiple scintillating crystals, which may be integrated into a solid-state light amplifier.