Patent Number: 045132046
Section: description

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In FIGS. 1-7, a holder, container or housing containing or carrying a radioactive source 2 is illustrated. The source 2 comprises a radioactive isotope which is used in a diagnostic motion correction scheme. Thus, the housing may be termed a dual isotope motion correction centroid point source holder. In the present case, the source 2 is commercially available for nuclear medicine purposes. In particular, it is a gamma radiation source available from The Radiochemical Centre, Amersham, England. A 2 mm diameter spherical point source 4 is located at one end of a closed-end cylindrical stainless steel housing 6 of 3 mm diameter and 10 mm length. The other end of the source housing 6 is plugged with an approx. 8 mm long stainless steel plug. The point source 4 is a pellet or bead containing the radioactive isotope. For motion correction applications, preferably an americium source is used. The radioactive material americium 241 has a comparatively low energy with regard to the emitted gamma radiation. This energy differs markedly from the energy of gamma radiation emitted by a tracer which is conventionally administered to a patient in nuclear medicine. The half-life of americium is several hundred years. This has the advantage that during patient examination and during the lifetime of a scintillation camera, a replacement of the radiation source 2 is not necessary. An americium point source can also be used as a marker in nuclear imaging by means of a scintillation camera such as the Anger camera. The housing contains a lower or bottom part 8 and an upper or top part 10. Both parts or sections 8 and 10 are made of a shielding material, preferably of a metal. A compound containing tungsten is preferred. A tungsten alloy known as "Mallory 1000" has been found especially useful. The holder sections 8 and 10 are of a material containing tungsten rather than lead because of its durability and its lighter weight. However, also other radiation attenuating materials may be used. The bottom part 8 represents a first radiation shielding body. As can be seen in FIG. 1, it contains at its upper end a protrusion 12. The protrusion 12 and the base portion 14 of the bottom part 8 are both of cylindrical or disk shape. The protrusion 12 contains a first recess or chamber 16 for holding the cylindrical source housing 6 containing the radioactive americium source 4 therein. In particular, the first recess 16 is a channel extending from the periphery of the cylindrical protrusion 12 to its middle section. Here it merges into another channel or chamber 18 which is arranged perpendicularly thereto. The channels 16 and 18 are shaped so that the point source 4 becomes positioned in the center of the disk structure 8. Both channels 16, 18 extend from the upper face end of the protrusion 12 to the upper end of the base portion 14. In operation, the source 2 is kept in the channel 16 by means of a cement. The top part 10 represents a second radiation shielding body. On its lower end it contains a second recess 20 which is illustrated in FIG. 1 in broken lines. The recess 20 as well as the top part 10 have a cylindrical or disk shape. The dimension of the second recess 20 is such that the protrusion 12 of the bottom part 8 fits tightly therein. In the upper surface of the upper part 10 is provided a conical recess 22. The conical angle of this recess 22 is designated by .alpha.. The recess 22 merges into a central aperture 23 connecting the upper recess 22 with the lower recess 20. The diameter d of the central aperture 23 is preferably d=2 mm, see FIGS. 4 and 5. The aperture 23 and the recess 22 are provided for permitting the passage of radiation quanta from the point source 4 at angles between 0.degree. and 60.degree. towards the upper surface. To the lower end of the lower part 8, there may be attached a label 25, see FIG. 3. This label 25 contains information such as radiation identification and a caution note. There are also provided means for connecting the top part 10 to the bottom part 8. These means comprise two openings 24 extending axially through the bottom part 8 and two openings 26 extending axially through the top part 10. These openings 24, 26 are provided at the rim portions of the parts 8 and 10, respectively, and they are aligned with respect to each other. The connecting means may further comprise rivets 28, extending through the openings 24 and 26 as illustrated in FIG. 3. Thus, in the preferred embodiment the parts 8 and 10 are kept together by the rivets 28 running through boxes at diagonally opposite sides of the parts 8 and 10. During assembly of the structure, the radiation source 2 is inserted and cemented into the first recess 16 and subsequently the protrusion 12 is plugged into the second recess 20. Now the lower end face of the upper part 10 joins the upper end face of the bottom portion 14. Then the top part 10 is connected to the bottom part 8 by means of the aforementioned rivets 28. In the closed status of the parts 8 and 10, the radioactive source 2 will emit gamma radiation basically through the conical aperture 22. The centroid source holder may now be attached to the patient. The openings 22, 23 in the center of the upper part 10 serve as a port to pass the emitted radiation from the point source 4 towards the scintillation camera. After assembly, the upper and lower parts 8, 10 both enclose the source 2 in a tight manner. The point source 4 is completely encapsulated with the exception of the area where the aperture 23 and the conical recess 22 are provided. Due to this feature, an optimum shielding of the patient and of the technician or physician performing the examination is achieved. Examinations have proven that a wide range of conical angles .alpha. can be used. However, an angle of approximately .alpha.=120.degree. has proven to be best for certain applications. This angle .alpha. is especially useful if a movable scintillation camera is used. It ensures that the scintillation camera exerts a constant count rate at various positions of the camera with respect to the housing 8, 10. In order that the angle .alpha. can be used optimally, the height b of the protrusion 12 should not markedly exceed the diameter of the source 2. Thus, the 120.degree. angle is empirically chosen. It allows for angular placement of the camera head relative to the source. Yet it is not too wide an angle to prevent shielding of the radiation from the patient and surrounding environment (nurses, etc.). A vertical walled opening would not permit many counts to reach the camera head if the head is placed at an angle because the parallel collimator would not accept rays at angles to the axes of the collimator paths. The size of the container is small so that it can be easily taped, e.g. to the chest of a patient by a surgical tape. It will move with the movement of the patient's chest. In a preferred embodiment, the container dimensions are A=2.5 cm; B=1.9 cm; a=7 mm; b=3 mm; c=4 mm. While the forms of the housing for a radioactive source herein described constitute preferred embodiments of the invention, it is to be understood that the invention is not limited to these precise forms of assembly, and that a variety of changes may be made therein without departing from the scope of the invention.