Photostimulated luminescence

Last updated March 29, 2024

Photostimulated luminescence (PSL) is the release of stored energy within a phosphor by stimulation with visible light, to produce a luminescent signal. X-rays may induce such an energy storage. A plate based on this mechanism is called a photostimulable phosphor (PSP) plate and is one type of X-ray detector used in projectional radiography. Creating an image requires illuminating the plate twice: the first exposure, to the radiation of interest, "writes" the image, and a later, second illumination (typically by a visible-wavelength laser) "reads" the image. The device to read such a plate is known as a phosphorimager (occasionally spelled phosphoimager, perhaps reflecting its common application in molecular biology for detecting radiolabeled phosphorylated proteins and nucleic acids).

Projectional radiography using a photostimulable phosphor plate as an X-ray detector can be called "phosphor plate radiography"^[1] or "computed radiography"^[2] (not to be confused with computed tomography which uses computer processing to convert multiple projectional radiographies to a 3D image).

Structure and mechanism

Energy storage

On photostimulable phosphor (PSP) plates, the phosphor layer is typically 0.1 to 0.3 mm thick. After the initial exposure by short-wavelength (typically, X-ray) electromagnetic radiation, excited electrons in the phosphor material remain 'trapped' in 'colour centres' ("F-centers") in the crystal lattice until stimulated by the second illumination. For example, Fuji's photostimulable phosphor is deposited on a flexible polyester film support with grain size about 5 micrometers, and is described as "barium fluorobromide containing a trace amount of bivalent europium as a luminescence center".^[3] Europium is a divalent cation that replaces barium to create a solid solution. When Eu²⁺ ions are struck by ionizing radiation, they lose an additional electron to become Eu³⁺ ions. These electrons enter the conduction band of the crystal and become trapped in the bromine ion empty lattice of the crystal, resulting in a metastable state that is higher in energy than the original condition.

Energy release and digitalization

Readout of a PSP plate CrScanningPlate.svg — Readout of a PSP plate

A lower-frequency light source that is insufficient in energy to create more Eu³⁺ ions can return the trapped electrons to the conduction band. As these mobilized electrons encounter Eu³⁺ ions, they release a blue-violet 400 nm luminescence.^[4] This light is produced in proportion to the number of trapped electrons, and thus in proportion to the original X-ray signal. It can be collected often by a photomultiplier tube, which is clocked at a specific resolution or pixel capture frequency. The light is thereby converted to an electronic signal and significantly amplified. The electronic signal is then quantized via an ADC to discrete (digital) values for each pixel and placed into the image processor pixel map.

Reuse

Afterwards, the plates can be "erased," by exposing the plate to room-intensity white light. Thereby, the plate can be used over and over again. Imaging plates can theoretically be re-used thousands of times if they are handled carefully and under certain radiation exposure conditions. PSP plate handling under industrial conditions often results in damage after a few hundred uses. Mechanical damage such as scratches and abrasions are common, as well as radiation fatigue or imprinting due to high energy applications. An image can be erased by simply exposing the plate to a room-level fluorescent light - but more efficient, complete erasure is required to avoid signal carry-over and artifacts. Most laser scanners automatically erase the plate (current technology uses red LED lighting) after laser scanning is complete. The imaging plate can then be re-used.

Reusable phosphor plates are environmentally safe but need to be disposed of according to local regulations due to the composition of the phosphor, which contains the heavy metal Barium.

Uses

Computed radiography is used for both industrial radiography and medical projectional radiography. Image plate detectors have also been used in numerous crystallography studies.^[5]

Medical X-ray Imaging

In phosphor plate radiography, the imaging plate is housed in a special cassette and placed under the body part or object to be examined and the x-ray exposure is made. The imaging plate is then run through a special laser scanner, or CR reader, that reads and converts the image to a digital radiograph. The digital image can then be viewed and enhanced using software that has functions very similar to other conventional digital image-processing software, such as contrast, brightness, filtration and zoom. CR imaging plates (IPs) can be retrofitted to existing exam rooms and used in multiple x-ray sites since IPs are processed through a CR reader (scanner) that can be shared between multiple exam rooms.^[6]

Differences from Direct Radiography

CeReO - PSP plate scanner CRSCanner.png — CeReO - PSP plate scanner

PSP plate radiography is often distinguished from Direct Radiography (DR). Direct radiography usually refers to image capture onto an amorphous silicon or selenium flat panel detector (FPD), the data being directly passed electronically to the processing computer. PSP plate radiography instead uses a cassette containing the imaging plate, which stores the image until it is read out and loaded into the computer. This additional extra step, from exposing the detector to a viewable digital image, is the main difference between the two techniques.^[7]

PSP plates and DR FPDs are typically used for projectional radiography. This should not be confused with fluoroscopy, where there is a continuous beam of radiation and the images appear on the screen in real time, for which PSP plates cannot be used.^[8]

History

Image plates were pioneered for commercial medical use by Fuji in the 1980s.^[9]

Related Research Articles

A cathode-ray tube (CRT) is a vacuum tube containing one or more electron guns, which emit electron beams that are manipulated to display images on a phosphorescent screen. The images may represent electrical waveforms on an oscilloscope, a frame of video on an analog television set (TV), digital raster graphics on a computer monitor, or other phenomena like radar targets. A CRT in a TV is commonly called a picture tube. CRTs have also been used as memory devices, in which case the screen is not intended to be visible to an observer. The term cathode ray was used to describe electron beams when they were first discovered, before it was understood that what was emitted from the cathode was a beam of electrons.

X-ray is a high-energy electromagnetic radiation. In many languages, it is referred to as Röntgen radiation, after the German scientist Wilhelm Conrad Röntgen, who discovered it in 1895 and named it X-radiation to signify an unknown type of radiation.

A phosphor is a substance that exhibits the phenomenon of luminescence; it emits light when exposed to some type of radiant energy. The term is used both for fluorescent or phosphorescent substances which glow on exposure to ultraviolet or visible light, and cathodoluminescent substances which glow when struck by an electron beam in a cathode-ray tube.

<span class="mw-page-title-main">Radiography</span> Imaging technique using ionizing and non-ionizing radiation

Radiography is an imaging technique using X-rays, gamma rays, or similar ionizing radiation and non-ionizing radiation to view the internal form of an object. Applications of radiography include medical and industrial radiography. Similar techniques are used in airport security,. To create an image in conventional radiography, a beam of X-rays is produced by an X-ray generator and it is projected towards the object. A certain amount of the X-rays or other radiation are absorbed by the object, dependent on the object's density and structural composition. The X-rays that pass through the object are captured behind the object by a detector. The generation of flat two-dimensional images by this technique is called projectional radiography. In computed tomography, an X-ray source and its associated detectors rotate around the subject, which itself moves through the conical X-ray beam produced. Any given point within the subject is crossed from many directions by many different beams at different times. Information regarding the attenuation of these beams is collated and subjected to computation to generate two-dimensional images on three planes which can be further processed to produce a three-dimensional image.

Medical imaging is the technique and process of imaging the interior of a body for clinical analysis and medical intervention, as well as visual representation of the function of some organs or tissues (physiology). Medical imaging seeks to reveal internal structures hidden by the skin and bones, as well as to diagnose and treat disease. Medical imaging also establishes a database of normal anatomy and physiology to make it possible to identify abnormalities. Although imaging of removed organs and tissues can be performed for medical reasons, such procedures are usually considered part of pathology instead of medical imaging.

An X-ray machine is a device that uses X-rays for a variety of applications including medicine, X-ray fluorescence, electronic assembly inspection, and measurement of material thickness in manufacturing operations. In medical applications, X-ray machines are used by radiographers to acquire x-ray images of the internal structures of living organisms, and also in sterilization.

<span class="mw-page-title-main">Fluoroscopy</span> Production of an image when X-rays strike a fluorescent screen

Fluoroscopy, informally referred to as "fluoro", is an imaging technique that uses X-rays to obtain real-time moving images of the interior of an object. In its primary application of medical imaging, a fluoroscope allows a surgeon to see the internal structure and function of a patient, so that the pumping action of the heart or the motion of swallowing, for example, can be watched. This is useful for both diagnosis and therapy and occurs in general radiology, interventional radiology, and image-guided surgery.

Radiocontrast agents are substances used to enhance the visibility of internal structures in X-ray-based imaging techniques such as computed tomography, projectional radiography, and fluoroscopy. Radiocontrast agents are typically iodine, or more rarely barium sulfate. The contrast agents absorb external X-rays, resulting in decreased exposure on the X-ray detector. This is different from radiopharmaceuticals used in nuclear medicine which emit radiation.

Yttrium aluminium garnet (YAG, Y₃Al₅O₁₂) is a synthetic crystalline material of the garnet group. It is a cubic yttrium aluminium oxide phase, with other examples being YAlO₃ (YAP) in a hexagonal or an orthorhombic, perovskite-like form, and the monoclinic Y₄Al₂O₉ (YAM).

An X-ray image intensifier (XRII) is an image intensifier that converts X-rays into visible light at higher intensity than the more traditional fluorescent screens can. Such intensifiers are used in X-ray imaging systems to allow low-intensity X-rays to be converted to a conveniently bright visible light output. The device contains a low absorbency/scatter input window, typically aluminum, input fluorescent screen, photocathode, electron optics, output fluorescent screen and output window. These parts are all mounted in a high vacuum environment within glass or, more recently, metal/ceramic. By its intensifying effect, It allows the viewer to more easily see the structure of the object being imaged than fluorescent screens alone, whose images are dim. The XRII requires lower absorbed doses due to more efficient conversion of X-ray quanta to visible light. This device was originally introduced in 1948.

Digital radiography is a form of radiography that uses x-ray–sensitive plates to directly capture data during the patient examination, immediately transferring it to a computer system without the use of an intermediate cassette. Advantages include time efficiency through bypassing chemical processing and the ability to digitally transfer and enhance images. Also, less radiation can be used to produce an image of similar contrast to conventional radiography.

Industrial radiography is a modality of non-destructive testing that uses ionizing radiation to inspect materials and components with the objective of locating and quantifying defects and degradation in material properties that would lead to the failure of engineering structures. It plays an important role in the science and technology needed to ensure product quality and reliability. In Australia, industrial radiographic non-destructive testing is colloquially referred to as "bombing" a component with a "bomb".

Computed radiography may refer to:

<span class="mw-page-title-main">Dental radiography</span> X-ray imaging in dentistry

Dental radiographs, commonly known as X-rays, are radiographs used to diagnose hidden dental structures, malignant or benign masses, bone loss, and cavities.

Projectional radiography, also known as conventional radiography, is a form of radiography and medical imaging that produces two-dimensional images by X-ray radiation. The image acquisition is generally performed by radiographers, and the images are often examined by radiologists. Both the procedure and any resultant images are often simply called 'X-ray'. Plain radiography or roentgenography generally refers to projectional radiography. Plain radiography can also refer to radiography without a radiocontrast agent or radiography that generates single static images, as contrasted to fluoroscopy, which are technically also projectional.

<span class="mw-page-title-main">Automatic exposure control</span>

Automatic Exposure Control (AEC) is an X-ray exposure termination device. A medical radiographic exposure is always initiated by a human operator but an AEC detector system may be used to terminate the exposure when a predetermined amount of radiation has been received. The intention of AEC is to provide consistent x-ray image exposure, whether to film, a digital detector or a CT scanner. AEC systems may also automatically set exposure factors such as the X-ray tube current and voltage in a CT.

Flat-panel detectors are a class of solid-state x-ray digital radiography devices similar in principle to the image sensors used in digital photography and video. They are used in both projectional radiography and as an alternative to x-ray image intensifiers (IIs) in fluoroscopy equipment.

Neutron imaging is the process of making an image with neutrons. The resulting image is based on the neutron attenuation properties of the imaged object. The resulting images have much in common with industrial X-ray images, but since the image is based on neutron attenuating properties instead of X-ray attenuation properties, some things easily visible with neutron imaging may be very challenging or impossible to see with X-ray imaging techniques.

X-ray detectors are devices used to measure the flux, spatial distribution, spectrum, and/or other properties of X-rays.

<span class="mw-page-title-main">Operation of computed tomography</span>

X-ray computed tomography operates by using an X-ray generator that rotates around the object; X-ray detectors are positioned on the opposite side of the circle from the X-ray source.

References

↑ Benjamin S (2010). "Phosphor plate radiography: an integral component of the filmless practice". Dent Today. 29 (11): 89. PMID 21133024.
↑ Rowlands JA (2002). "The physics of computed radiography". Phys Med Biol. 47 (23): R123–66. doi:10.1088/0031-9155/47/23/201. PMID 12502037. S2CID 250801018.
↑ "Principle of Imaging Plate Methodology". Fujifilm. Archived from the original on 19 March 2006. Retrieved 27 June 2017.
↑ "Imaging plate". Fujifilm.
↑ Gruner, S. M.; Eikenberry, E. F.; Tate, M. W. (2006). "Comparison of X-ray detectors". International Tables for Crystallography. F (7.1): 143–147. doi:10.1107/97809553602060000667.
↑ "Computed radiography (CR) systems" (PDF). World Health Organization. 2012. Retrieved 27 June 2017.
↑ "Computed radiography and digital radiography". IAEA Human Health Campus. Retrieved 27 June 2017.
↑ "Fluoroscopy". World Health Organization. Archived from the original on October 19, 2014. Retrieved 27 June 2017.
↑ Dreyer, Keith J.; Mehta, Amit; Thrall, James H. (2013). PACS: A Guide to the Digital Revolution. Springer. p. 161. ISBN 9781475736519.

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[1] Benjamin S (2010). "Phosphor plate radiography: an integral component of the filmless practice". Dent Today. 29 (11): 89. PMID 21133024.

[2] Rowlands JA (2002). "The physics of computed radiography". Phys Med Biol. 47 (23): R123–66. doi:10.1088/0031-9155/47/23/201. PMID 12502037. S2CID 250801018.

[3] "Principle of Imaging Plate Methodology". Fujifilm. Archived from the original on 19 March 2006. Retrieved 27 June 2017.

[4] "Imaging plate". Fujifilm.

[5] Gruner, S. M.; Eikenberry, E. F.; Tate, M. W. (2006). "Comparison of X-ray detectors". International Tables for Crystallography. F (7.1): 143–147. doi:10.1107/97809553602060000667.

[6] "Computed radiography (CR) systems" (PDF). World Health Organization. 2012. Retrieved 27 June 2017.

[7] "Computed radiography and digital radiography". IAEA Human Health Campus. Retrieved 27 June 2017.

[8] "Fluoroscopy". World Health Organization. Archived from the original on October 19, 2014. Retrieved 27 June 2017.

[9] Dreyer, Keith J.; Mehta, Amit; Thrall, James H. (2013). PACS: A Guide to the Digital Revolution. Springer. p. 161. ISBN 9781475736519.

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