DE1930694A1 - Scintillation camera - Google Patents

Description

PATENT ADVOCATE DiRL-ING.

HELMUT GÖRTZ

8 Frankfurt am Main 70 SAneckenhofstf. 27 - Tel. 61 70 79

June 16, 1969 Gzx / Ra.

Piieker Corporation, White Plains, New York / U.S.A. Illumination camera a

The invention relates to radiation detectors and more particularly on a scintillation camera equipped with a new and improved entrance phosphor structure.

During certain medical examinations that involve gamma rays are used, the patient is supplied with a certain amount of a radioactive isotope. A scintillation detector with an assigned device is used for verification and for temporary display and / or permanent playback information for the radiation emitted by the patient,

Ghamor diagnosis is an example of a medical examination, in which a certain amount of a radioactive isotope is supplied to a patient. Tumor diagnosis with Isotopes is possible because the tumor tissue has an affinity for has such isotopes which differ from the affinity of the surrounding healthy tissue. After the isotope has been absorbed into the patient, an examination of the distribution and concentration of the isotope is made. A «photographic recording or other graphic representation, which shows the spatial distribution of the supplied isotope in

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indicates to the patient provides diagnostic information about the size and location of the tumor »

A known scintillation camera for use in medical Diagnosis, such as the tumor diagnosis mentioned above, has a number of photoelectron tubes that are connected to their Point the front in the direction of a scintillator. The scintillator is arranged in the vicinity of the patient and in the region of the gamma rays of an administered radioactive isotope. The scintillator emits flashes of light upon incidence of gamma rays /. The photoelectron tubes are a short distance away from the scintillator to observe overlapping areas of the scintillator. Every scintillation from the scintillator is through one or more of the IOtoelectron tubes proven.

Signals that are supplied from the photoelectron tubes are fed to a computing circuit which, by determining the relative strength of the emitted signals, the spatial position of each scintillation is calculated.

A scintillator used in this device consists of one thin disc of scintillation material such as a thallium activated sodium odide crystal. The crystal is provided with a cylindrical outer surface. When the scintillations in the crystal are due to the radiation excitation are generated, light is emitted in different directions. Part of the light falls through the pane into Direction of the peripheral surface and is reflected by this in the main part of the disc. This from the TJmfangs-

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light reflected from the surface of the disc causes nonlinearities the display and brings other errors into the visible final rendering of the examined organ. You may find, that this reflected light causes light signals at points that are spatially separated from the entry points of the incident Gamma rays in the crystal that originally generated these shifted signals differ. The photoelectron tubes show and generate these shifted reflected light images incorrect information regarding the spatial distribution of the radiation emitted by the administered isotope.

The invention avoids the mentioned and other problems of the known detection devices. It contains a scintillation camera with an input phosphor or scintillator which has the described Light reflection on the peripheral surfaces is significantly reduced. To achieve this, a special scintillator is used used in the form of a thin plate or disk made of a crystal of sodium iodide. Since sodium iodide is hygroscopic is, the input surface of the disc is covered with an aluminum plate and the output surface is connected to a glass plate. The plates are in turn connected to a surrounding retaining ring to form a hermetic seal around the disc to build.

A peripheral part of the disc contains at least one surface lying in a plane oblique to the planes of the input and output surfaces is trained. The partial peripheral surface is covered with a material which reduces the reflection. This is preferably a coating of black non-reflective material. The orientation of the inclined circumferential surface prevents

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changes reflections back into the main part of the logs. Not that one reflective material increases the absorption of light on the peripheral surface.

In a particular embodiment of the invention, the has

disc

Scintillator / a wedge-shaped peripheral part supported by an annular Perimeter area is limited, which is oblique to the entrance and Starting surfaces lies and extends between them. The wedge-shaped part is made up of this inclined surface and a formed another surface, which is either a peripheral part of the exit or the entrance surface of the disc. These two annular peripheral surfaces that form the wedge-shaped peripheral part are covered with non-reflective material.

In a second embodiment of the invention, the wedge-shaped Peripheral part bounded by two annular, peripheral, inclined surfaces. These two circumferential surfaces that limit the wedge-shaped peripheral part, have a seam connection which is midway between the entrance and exit surfaces, and are made of non-reflective material covered.

When using any form of the invention there will be flashes of light generated in a central or main part of the disk at points that affect the spatial distribution of the incident radiation correspond. The light output from such a central part of the improved disc represents much more accurately than known devices represent the spatial distribution of the gamma radiation. This increased accuracy was achieved because because most of the light is coming from the main part of the disc falls in the direction of the wedge-shaped peripheral part, between the

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Surfaces of this circumference are captured and finally, by the non-reflective material is absorbed. Light emitted in sighting the annular peripheral surfaces of the disc is subjected to one or more levels of absorption toid reflection, so that the light returning to the main part is substantially weakened. The end result is an indication of improved linearity properties with a decreased number of error-generating signals.

The main aim of the invention is therefore to provide a new and improved scintillation phosphor for a scintillation camera

Further features, advantages and possible uses of the Invention emerge from the accompanying illustrations of exemplary embodiments and from the following description,

Show it: .

Figure 1 is a fragmentary vertical section of part a scintillation camera showing a collimator, a scintillator and photoelectron tubes and

Pig ,, 2 and 3 similar views showing alternative scintillators demonstrate.

Various components of a scintillation camera are shown in FIG shown. A lead collimator 10 lies between a radiation source (not shown) and the entrance side of a scintillator

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arrangement 13. The collimator 10 allows the passage of radiation to, which run essentially parallel to the axes of the openings 11 and thereby prevent the passage of radiation, which falls in random directions, which would distort the final visible reproduction of an examination object. A series of photosensitive photo electron tubes 15 are attached to an output side of the assembly 13.

The scintillation assembly 13 includes a scintillator 17 between a circular aluminum plate 19 on its Entrance side and a circular transparent glass plate 20 is located on its exit side. The scintillator 17 is with the glass plate 20 connected. The plates 19, 20 are each arranged on a surrounding metal ring 22. The plates 19, 20 and the ring 22 form a hermetically sealed chamber for the scintillator 17.

The scintillator 17 is a plate of photofluorescent material, preferably in the form of a thin circular disk made of sodium iodine, idkr is all. The scintillator 17 includes a central or main part 28 and a wedge-shaped, peripheral light absorber part 30 around the main part 28. The scintillator 17 also contains an input surface 32 which is in contact with the aluminum plate 19 and a parallel output surface 34 which is in contact with the glass plate 20. The dimensions of the disc can be, for example, on the order of 34 _f 3 cm (13 »5 inches) in diameter and 1.3 cm (0.5 inch) in thickness.

Every time a scintillation appears in the scintillator 17, this is made by a variety of loto electron tubes 15 observed. The size of the output signals which each

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Photoelectron tube 15 generated depends on the distance and

observed

the intensity of the temporal / scintillations ah. The resulting Pulses from the photoelectron tubes 15 are given by a computer (not shown), which the spatial Location of each scintillation according to the relative strength of the multitude of electrical impulses from the photoelectron tubes 15 determined. An output signal from the computer is given to a display device such as an oscilloscope, which displays a graphical display showing the spatial distribution of the radioactive material being examined.

The light absorber 30 of the scintillator has an annular shape TJmfangsflache 36, which is inclined to the input and output surfaces 32, 34 lies and extends between them. An annular peripheral portion 38 of the exit surface 34 meets on the peripheral surface 36 at a seam line 40, so that the Light absorber 30 has the shape of a wedge which is formed by the peripheral surface 36 and the peripheral part 38. It can be seen that in this form of the invention, the connecting line 40 with the exit surface 34 is coplanar.

The surface 36 and the portion 38 are coated with a non-reflective Material B * covered, which for example consists of a thin soot coating can exist. Other forms of light absorbing material and reflection preventing devices will be used considered, such as material having an appropriate index of refraction relative to the index of refraction of the scintillator material, so that a substantial percentage of the light falling in the direction of the peripheral surface of the scintillator falls off or is absorbed by the material.

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The size of the angle between the peripheral surface 36 and the peripheral part 38 is formed is not critical, at least not in a sodium;) odidkr is all, however, should corresponding to a compromise between light trapping efficiency of the wedge and unusable display "forming area of the Scintillator 17 can be determined. For example, it is preferred that the angle between surface 36 and part 38 be somewhat smaller made than 45 ° and the peripheral portion 38 of the exit surface at least about 1.3 cm (0.5 inch) inward of the join line 4-0 made of coated so that a substantial amount · of the generally parallel to the entrance and exit surfaces 32, 34 and 'light falling on the peripheral surface 36 at least two reflections on the surface 36 and the part 38 is subjected.

With the one in Pig. 1 arrangement shown and when using a Wedge angle, which is slightly lower than 45 °, can be seen that at least the light rays that are approximately parallel to the Entrance and exit surfaces 32, 34 from the main part 28 in the direction of the light absorber 30 either first on the circumferential surface 3'6 or the peripheral part 38 and subsequently partially absorbed by the black material B. and are partially reflected in the direction of the respective other part of the surface 36 and the part 38. After a or several reflections and / or absorptions of the light incident on the surface 36 and the part 38 is the light, that would otherwise be reflected by the circumferential surfaces and in the direction of of the main part 28 of the scintillator or photoelectron tubes 15 would be thrown back, has essentially completely disappeared to a negligible level.

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BATH

In a second embodiment of the invention, which is shown in FIG As shown, the collimator 10a, the photoelectron tubes 15a, the plates 19a, 20a and the ring 22a are the same as that corresponding elements in Fig. 1. In this second embodiment a scintillator 46 has a central part 48 and a modified wedge-shaped light absorber part 50. Parallel input and output surfaces 52, 54 of the scintillator 46 are connected to plates 19a, 20a. The light absorber 50 is formed by inclined, annular circumferential surfaces 56, 58. The surfaces 56, 58 intersect one another in a connecting line 60. Surfaces 56, 58 intersect at an acute angle to form a wedge. The peripheral surfaces 56, 58 are made with carbon black B or other light absorbing materials covered.

As shown, there is the connecting line 60 of the circumferential surfaces 56, 58 at a distance from the plates 19a, 20a and midway between the planes of the input and output surfaces 52, 54. Again, it is preferred to make the angle between the circumferential surfaces 42, 44 smaller than 45 ° in order to be able to do so of multiple reflections and increases in absorptions of the light that enters the light absorber 50 from the main body 48 falls.

In the structure shown in Fig. 3, the collimator 10b, the photoelectron tubes 15b, the glass plates 19b, 20b, and the metal ring 22b the same as the corresponding elements in Fig. 1. The orientation of the wedge-shaped light absorber part is reversed with respect to the position shown in FIG. In this embodiment, the scintillator 66 a main part 68 and a surrounding wedge-shaped light

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absorber part 70 on. The scintillator 66 also includes parallel input and output surfaces 72, 74. The light absorber 70 has a peripheral surface 76 which is inclined to the Entrance and exit surfaces 72, 74 extends and extends therebetween. A peripheral portion 78 of the entrance surface 72 forms part of the light absorber 70. The Surface 76 and part 78 form an acute angle with one another and meet at a connecting line 80 which at a distance from the glass plate 20b and coplanar with the input surface 72 lies. The surface 76 and the part 78 which form the wedge are covered with carbon black B.

The present invention can be used with a variety of beam imaging devices can be used and is not limited to a collimator photoelectron tube assembly.

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Claims (6)

P at ent claims \ 1. jStrahlenabbildungsvorriehtung with a scintillator with an input and an output surface for the generation of a light output on radiation excitation through the input surface and with a light-sensitive device for generating an output signal on the light output from the output surface of the scintillator, characterized in that the Scintillator (17, 46, 66) includes a peripheral light absorber (30, 50, 70) to prevent light reflection from the scintillator periphery. 2. Apparatus according to claim 1, characterized in that the peripheral light absorber (30, 50, 70) contains a wedge-shaped peripheral part of the scintillator, which peripheral vision (36 * 38; 56, 58; 76, 78) which is in a Ya binding line (40, 60, 80) meet. 3. Apparatus according to claim 2, characterized in that the connecting line (80) is coplanar with the input surface (72) of the scintillator (66) lies. 4. Apparatus according to claim 2, characterized in that the connecting line (40) is coplanar with the output surface (34) of the scintillator (17) is located. 5. Apparatus according to claim 2, characterized in that the connecting line (60) lies in the middle between the input and output surfaces (52, 54) of the scintillator (46). 009824/1 163 6. Device according to claims 2, 3, 4 or 5> characterized in that the light absorber (30, 50, 70) is a reflection contains preventive material (B) covering at least one of the peripheral surfaces (36, 38; 56, 58; 76, 78). 00-9824 / 1 1 63