JP2008000201A - Dispensing and administering apparatus for radioactive chemical - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a dispensing and administering apparatus capable of being made light in weight while maintaining high radiation shielding ability. <P>SOLUTION: The dispensing and administering apparatus 10 for dispensing and administering the required amount of a radioactive chemical comprises: a first radiation shielding box 62 surrounding a radioactive chemical housing container 12 for housing the radioactive chemical, a sucking and discharging device 18 for the chemical for sucking and discharging the radioactive chemical and a chemical carry-away line L1 for connecting them and sending out the radioactive chemical; and a second radiation shielding box 60 surrounding the first radiation shielding box 62, a chemical administering line L2 connected to the chemical carry-away line L1 and a sucking and discharging device 32 for carrying liquid for sucking and discharging the carrying liquid carrying the radioactive chemical and supplying it to the chemical administering line L2, whose shielding ability is lower than that of the first radiation shielding box 62. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a radiopharmaceutical dispensing apparatus.

A nuclear medicine diagnostic method for diagnosing diseases and the like by administering a radiopharmaceutical solution containing a compound labeled with a radionuclide (RI) into the body and imaging the state in which the labeled compound is collected at a specific location in the body with a dedicated device. Has been developed. In this diagnostic method, a relatively short-lived radionuclides (e.g., as a positron-emitting nuclide, ¹⁵ O 2 minutes, ¹¹ C is 20 minutes, ¹⁸ F has a half-life of 110 minutes) labeled with, ¹⁵ O -Water, ¹¹ C-methionine, ¹⁸ F-FDG (fluorodeoxyglucose) or the like is used as the radioactive chemical solution.

For example, Patent Document 1 discloses a dispensing apparatus that accurately dispenses this radioactive drug solution and administers it to a subject. In this dispensing administration device, a predetermined amount of a radioactive drug solution is drawn from a vial using a syringe, and is pushed out and dispensed into a tube connected to a subject. Then, the dispensed radioactive liquid is sent out together with physiological saline and administered to the subject. This dispensing apparatus is entirely covered with a thick radiation shielding partition in order to prevent radiation leakage.
JP 2002-306609 A

  However, in the above-described conventional dispensing apparatus, since the whole is covered with a thick radiation shielding partition, the radiation shielding ability is high, but the weight is heavy and the handling property is poor.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to provide a dispensing apparatus capable of reducing weight while maintaining high radiation shielding ability.

  A dispensing administration device according to the present invention is a dispensing administration device for dispensing and administering a required amount of a radiopharmaceutical solution, and a radiopharmaceutical container for containing a radiopharmaceutical solution, a chemical solution suction for sucking and discharging the radiochemical solution A first radiation shielding box that surrounds a discharger and a chemical solution delivery line that connects these and carries out a radioactive chemical solution, a first radiation shielding box, a chemical solution administration line connected to the chemical solution delivery line, and a carrier that carries the radioactive chemical solution It includes a second radiation shielding box that surrounds the carrier liquid suction / discharge device that sucks and discharges the liquid and supplies it to the drug solution administration line, and has a shielding ability lower than that of the first radiation shielding box.

  According to this dispensing and administration device, the portion having a high radiation emission is surrounded by the first radiation shielding box, and the portion having a low radiation emission is surrounded by the second radiation shielding box having a lower shielding ability. It is no longer necessary to enclose them with a shielding box having a high shielding ability, and it is possible to reduce the weight while maintaining a high radiation shielding ability.

  It is preferable that the dispensing apparatus includes a branch line branched from the drug solution administration line, a valve provided in the branch line, and a drainage container for storing drainage discharged through the branch line. If it does in this way, when the desired radioactive chemical | medical solution is not dispensed etc., it can discharge | emit to a drainage container through a branch line.

  The drainage container is preferably accommodated in the first radiation shielding box. In this way, the amount of radioactivity leaking from the dispensing device can be further reduced.

  It is preferable that the reverse support valve is provided so as to sandwich the suction / discharge point by the chemical liquid suction / discharge device, and the reverse support valve is provided so as to sandwich the suction / discharge point by the carrier liquid suction / discharge device. This eliminates the need for flow path switching means such as a three-way cock, reduces the risk of electrical and mechanical problems, and improves reliability. Moreover, attachment becomes easy.

  According to the dispensing apparatus of the present invention, weight reduction can be achieved while maintaining high radiation shielding ability. As a result, it becomes possible to improve the handleability.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same reference numerals are used for the same elements, and duplicate descriptions are omitted.

  FIG. 1 is a diagram showing a configuration of a radioactive liquid dispensing apparatus 10 according to the present embodiment. As shown in FIG. 1, the dispensing apparatus 10 includes a storage portion 14 that stores a vial (radioactive drug solution storage container) 12 that stores a radioactive drug solution. For example, a vial 12 contained in a box 16 made of a material such as lead or tungsten is accommodated and supported in the accommodating portion 14 from an upper opening in a tilted state.

  In addition, the dispensing apparatus 10 has a holding unit 20 that holds a syringe (chemical liquid suction / discharge device) 18 for dispensing a radioactive chemical liquid. The holding unit 20 is, for example, a cylindrical container that holds the syringe 18 inserted from the lower end, and is entirely formed of a material such as lead or tungsten that shields radiation.

  The syringe 18 includes a cylinder 22 and a piston 24 that slides in the cylinder 22. A packing made of an elastic body such as rubber is provided at the tip of the piston 24. The piston 24 is connected to a driving device (not shown) that pushes and pulls the piston 24 such as a stepping motor. Therefore, by pushing and pulling the piston 24 in the cylinder 22, the radioactive chemical liquid can be sucked or discharged from the tip end.

  A quantitative sensor 26 for measuring radioactivity is provided around the syringe 18. With this quantitative sensor 26, the amount of radioactivity of the radiopharmaceutical contained in the syringe 18 can be measured.

  The vial bottle 12 and the syringe 18 described above are communicated with each other via a chemical solution carry-out line L1. A cattellan needle 29 is provided at one end of the chemical solution carry-out line L 1, and the catalan needle 29 is inserted into the vial bottle 12. The other end of the medicinal solution carry-out line L1 extends to a connection point with the medicinal solution administration line L2 and a saline eating line (carrying solution introduction line) L3 for introducing physiological saline (conveying solution). The chemical solution carry-out line L1 branches in the middle, and is connected to the syringe 18 at the branch point.

  A pair of reverse support valves 28 are provided so as to sandwich this branch point (suction / discharge point) on the chemical solution carry-out line L1. The pair of reverse support valves 28 regulates the flow direction of the radioactive chemical liquid in one direction.

  In addition, the dispensing administration device 10 includes a saline feed line L3 for introducing physiological saline from the physiological saline pack 30 to the drug solution administration line L2, and a syringe (carrier liquid suction / discharge device) 32 for sucking and discharging the physiological saline. It has. One end of the raw food introduction line L3 is connected to the physiological saline pack 30. The other end of the raw food introduction line L3 extends to a connection point between the chemical solution administration line L2 and the chemical solution introduction line L1. The raw food introduction line L3 branches on the way, and is connected to the syringe 32 at this branch point.

  A pair of reverse support valves 34 are provided so as to sandwich this branch point (suction / discharge point) on the raw food introduction line L3. The pair of reverse support valves 34 regulates the flow direction of the physiological saline in one direction.

  Moreover, the dispensing administration apparatus 10 is provided with the chemical | medical solution administration line L2 which conveys a radioactive chemical | medical solution toward administration to a test subject. One end of the chemical liquid administration line L2 extends to a connection point between the chemical liquid introduction line L1 and the saline eating introduction line L3. A three-way pipe 36 is provided at this connection point, and a chemical solution administration line L2, a chemical solution introduction line L1, and a saline intake line L3 are connected to the three openings, respectively.

  The other end of the chemical liquid administration line L2 extends to the air vent filter 38. The air vent filter 38 blocks air. A reverse support valve 40 is provided in the front stage of the air vent filter 38 to restrict the back flow of the chemical solution. Note that the reverse valve 40 may be omitted. The drug solution administration line L2 is branched in the middle, and a drainage vial (drainage container) 42 for storing drainage is connected to the end of the branch line L4. A pinch valve 44 is provided on the branch line L4.

  A pinch valve 48 is provided in the middle of the drug solution administration line L2 and after the branch point of the branch line L4, and a radiation passage sensor 46 that detects the passage of the radioactive drug solution is provided in the subsequent stage of the pinch valve 48. Is provided.

  In addition, the dispensing administration device 10 includes a final administration line L5. One end of the final administration line L5 is connected to the air vent filter 38. On the other hand, the other end of the final administration line L5 is connected to the winged needle 50. The dispensing apparatus 10 further includes a drainage introduction line L6 that extends from the outside of the outer radiation shielding box 62 to the drainage vial 42 in the inner radiation shielding box 60. A sealing plug 52 made of rubber or the like is provided at the outer end of the drainage introduction line L6. The sealing plug 52 can accommodate unnecessary drainage discharged from the winged needle 50 into the drainage vial 42 through the drainage introduction line L6 by piercing the winged needle 50.

  The above-described members are accommodated in the outer radiation shielding box (second radiation shielding box) 60 with a part of the final administration line L5 connected to the winged needle 50 being exposed. In particular, the vial 12 accommodated in the box 16, the syringe 18, the chemical solution introduction line L1 connecting them, and the first drainage vial 42 are accommodated in the inner radiation shielding box (first radiation shielding box) 62. Yes. These inner and outer radiation shielding boxes 60 and 62 are made of a material such as lead or tungsten that shields radiation. The radiation shielding ability of the inner radiation shielding box 62 is configured to be greater than the radiation shielding ability of the outer radiation shielding box 60. For example, the inner radiation shielding box 62 is made of lead with a thickness of 30 mm to 50 mm, while the outer radiation shielding box 60 is made of lead with a thickness of 5 mm to 10 mm. Comparing the shielding ability per unit area, the radiation shielding ability of the inner radiation shielding box 62 is configured to be about 22 to 1064 times larger than the radiation shielding ability of the outer radiation shielding box 60.

  The final administration line L5 from the physiological saline pack 30 and the air vent filter 38 is configured to be able to be taken in and out from the outer radiation shielding box 60.

  The pair of reverse support valves 28 and the reverse support valve 34 are preferably provided integrally with each other, and the integrated reverse support valve 28, the reverse support valve 34, and the three-way pipe 36 are preferably connected in series. In this way, connection work becomes easy.

  Next, a method for dispensing and administering a radioactive drug solution by the dispensing apparatus 10 according to the present embodiment will be described.

First, the vial 12 that stores the radioactive drug solution is accommodated in the accommodating portion 14, and the cattellan needle 29 is inserted into the vial 12. As the radioactive chemical solution, for example, ¹⁸ F-FDG (fluorodeoxyglucose), ¹⁵ O-water, or ¹¹ C-methionine can be used.

  Next, a certain amount of the physiological saline contained in the physiological saline pack 30 is drawn into the syringe 32 via the saline intake line L3. Next, the piston of the syringe 32 is pushed back by a predetermined amount, and physiological saline is introduced into the drug solution administration line L2. At this time, the pinch valves 44 and 48 are opened, and the drug solution administration line L2, the branch line L4, and the final administration line L5 are filled with physiological saline. Then, the pinch valve 48 is closed.

  Next, a certain amount of the radioactive chemical liquid contained in the vial 12 is drawn into the syringe 18 via the chemical liquid carry-out line L1. Next, the piston 24 of the syringe 18 is pushed back by a predetermined amount, and a part of the radioactive drug solution is carried out to the drug solution administration line L2. Then, the piston of the syringe 32 is pushed back by a predetermined amount, and physiological saline is introduced into the drug solution administration line L2. At this time, since the pinch valve 44 is opened, excess radioactive chemical solution carried on the chemical solution administration line L2 is discharged from the branch line L4 to the drainage vial 42 together with physiological saline.

  In this state, the piston of the syringe 18 is pushed back, and a radioactive chemical solution having a volume necessary for administration to the subject is carried out to the chemical solution administration line L2. Since the quantitative sensor 26 is provided around the syringe 18, the radioactivity amount of the radiopharmaceutical solution in the syringe 18 can be measured, and based on this, the capacity required for administration to the subject from the required radioactivity amount can be measured. Calculated. When a necessary amount of the radioactive drug solution is carried out to the drug solution administration line L2, the physiological saline is sent from the branch line L4 to the drainage vial 42 by the amount of the radioactive liquid dispensed. Then, the pinch valve 44 is closed.

  After preparing for administration in this way, the pinch valve 48 is opened, the piston of the syringe 32 is pushed back, physiological saline is introduced into the drug solution administration line L2, and the necessary amount carried out to the drug solution administration line L2 is reached. The radiopharmaceutical solution is swept away and administered to the subject through the final administration line L5.

  It should be noted that the radiopharmaceutical solution was dispensed to the medicinal solution administration line L2. However, when the time has elapsed and the radiopharmaceutical solution has become unusable, or when an unnecessary amount of the radiopharmaceutical solution has been dispensed, When it is not suitable, the physiological saline is introduced into the drug solution administration line L2 by the syringe 32 with the pinch valve 48 closed and the pinch valve 44 opened, thereby sending unnecessary waste liquid to the drainage vial 42 through the branch line L4.

  As described above, in the dispensing apparatus 10 according to the present embodiment, the portion that emits a large amount of radiation is surrounded by the inner radiation shielding box 62, and the portion that emits less radiation is surrounded by an outer radiation shielding box having a lower shielding ability. Since it is surrounded by 60, it becomes unnecessary to surround the whole with a shielding box having a high shielding ability, and it is possible to reduce the weight while maintaining a high radiation shielding ability.

  In addition, the dispensing administration device 10 includes a branch line L4 branched from the drug solution administration line L2, a pinch valve 44 provided in the branch line L4, and a drainage vial 42 for storing drainage discharged through the branch line L4. Therefore, when the desired radiopharmaceutical solution is not dispensed, it can be discharged to the drainage vial 42 through the branch line L4.

  And since this drainage vial 42 is also accommodated in the inner radiation shielding box 62, the amount of radioactivity leaking from the dispensing apparatus 10 can be further reduced.

  Further, since the reverse support valve 28 is provided so as to sandwich the suction / discharge point by the syringe 18 and the reverse support valve 34 is provided so as to sandwich the suction / discharge point by the syringe 32, the flow path switching like a three-way stopcock is performed. Means are no longer required, the possibility of electrical and mechanical problems being reduced, and reliability is improved. Moreover, attachment becomes easy.

It is a figure which shows typically the structure of the dispensing administration apparatus of the radiopharmaceutical solution which concerns on this embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Dispensing device, 12 ... Vial bottle, 18 ... Syringe, 28, 34 ... Check valve, 32 ... Syringe, 42 ... Drainage vial, 44, 48 ... Relief valve, 60 ... Outer radiation shielding box, 62 ... Inner radiation shielding box, L1 ... chemical solution carry-out line, L2 ... chemical solution administration line, L3 ... saline introduction line, L4 ... branch line, L5 ... final administration line.

Claims (4)

A dispensing administration device for dispensing and administering a required amount of a radiopharmaceutical solution,
A radioactive chemical solution storage container for containing a radioactive chemical solution, a suction / discharge device for a chemical solution for sucking and discharging the radioactive chemical solution, and a first radiation shielding box that surrounds the chemical solution carry-out line that connects them and carries out the radioactive chemical solution;
Surrounding the first radiation shielding box, a chemical liquid administration line connected to the chemical liquid carry-out line, and a carrier liquid suction / discharge device for sucking and discharging a carrier liquid carrying the radioactive chemical liquid and supplying it to the chemical liquid administration line, A second radiation shielding box having a shielding ability lower than that of the first radiation shielding box;
A dispensing administration device comprising: A branch line that branches off from the drug solution administration line;
A valve provided in the branch line;
A drainage container containing drainage discharged through the branch line;
The dispensing administration device according to claim 1, comprising:   The dispensing apparatus according to claim 2, wherein the drainage container is accommodated in the first radiation shielding box.   A reverse support valve is provided so as to sandwich the suction / discharge point by the chemical liquid suction / discharge device, and a reverse support valve is provided so as to sandwich the suction / discharge point by the carrier liquid suction / discharge device. The dispensing administration device according to any one of claims 1 to 3.

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