JP6301195B2 - Luer connector and drug injection device - Google Patents

Description

  The present invention relates to a luer connector and a drug injection device.

  Patent Document 1 describes a technique related to a radiopharmaceutical injection device. The radiopharmaceutical injection device described in this document is a device for injecting a radiopharmaceutical whose radiation dose has been measured into a living body, and includes a vial container that contains the radiopharmaceutical and a radiopharmaceutical in the vial container. And an injection syringe that pushes out the radiopharmaceutical using the gas as a carrier medium and a filter with an air vent that removes only the gas from the radiopharmaceutical and the gas pushed out of the injection syringe and allows the radiopharmaceutical to pass through.

JP-A-7-213606

  Conventionally, for example, PET measurement using a radiopharmaceutical such as O-15 water has been performed for evaluation of cerebral blood flow in a living body. In such a PET measurement, a radiopharmaceutical may be repeatedly administered, and it is desirable to use an automatic administration device in order to reduce the exposure of the worker. The radiopharmaceutical injection device described in Patent Document 1 is one of automatic administration devices. The radiopharmaceutical injection device described in Patent Document 1 can be used for medium-sized animal experiments such as macaque monkeys in addition to large animals.

  In this radiopharmaceutical injection device, before injecting the radiopharmaceutical, for example, the drug flow path from the filter with an air vent to the indwelling needle needs to be filled with non-radioactive water (for example, physiological saline) in advance. This is to prevent air from being injected into a drug administration target that is a living body when the radiopharmaceutical is injected. Moreover, it is because it will lead to an increase in an operator's exposure if the said chemical | medical agent path | route is satisfy | filled with a radiopharmaceutical. Therefore, when injecting the radiopharmaceutical, the radiopharmaceutical is injected following the pre-filled non-radioactive water.

  This radiopharmaceutical injection device has the following problems when the drug administration target is a small animal such as a marmoset. That is, when the drug administration target is a small animal, it is required to reduce the total liquid volume to be injected (the sum of the liquid volume of non-radioactive water and the liquid volume of the radiopharmaceutical). For example, the amount of liquid that can be injected into monkeys weighing 3 to 5 kg is 2 to 3 ml, whereas the amount of liquid that can be injected into small animals such as marmosets is as small as 0.3 ml. However, it is preferable to inject a sufficient amount of liquid for the radiopharmaceutical necessary for PET measurement. Therefore, it is desirable to reduce the amount of non-radioactive water.

  This invention is made in view of such a problem, and it aims at providing the lure connector and chemical | medical agent injection apparatus which can reduce the liquid quantity of the non-radioactive water inject | poured into the chemical administration object. To do.

  The luer connector according to the present invention is a luer connector used in a drug injection device that injects a radiopharmaceutical into a living body following non-radioactive water. This luer connector is connected to a water container for storing non-radioactive water and a drug container for storing a radiopharmaceutical, and has a cylindrical male luer part having a passage hole through which the non-radioactive water and the radiopharmaceutical pass, and the placement of the drug injection device A needle is provided at the other end of the tube attached to one end, and a male luer part having a male luer part insertion hole that fits into the male luer part. A female luer part has a cylindrical spacer part inserted in the passage hole of a male luer part at the time of a fitting with a male luer part. The outer peripheral surface of the spacer portion has a tapered shape.

  In the drug injection device provided with the above luer connector, at the time of drug administration, the radio drug reaches the indwelling needle through the luer connector from the drug container containing the radio drug, and is injected into the drug administration target. The reason why the luer connector is interposed between the medicine container and the indwelling needle is that the medicine flow path from the filter with the air vent to the indwelling needle can be replaced. The present inventor has found that the amount of non-radioactive water filled in advance can be reduced by reducing the internal space of the male luer part of the conventional luer connector.

  That is, the luer connector includes a cylindrical male luer part and a female luer part having a male luer part insertion hole that fits into the male luer part. The female luer part is a passage hole of the male luer part when fitted with the male luer part. A cylindrical spacer portion to be inserted into the housing. Thus, the volume of the internal space of the passage hole of a male luer part can be reduced by arrange | positioning a cylindrical spacer part in the passage hole of a male luer part. Therefore, according to the luer connector, the amount of non-radioactive water prefilled in the luer connector can be reduced, thereby reducing the amount of non-radioactive water injected into the drug administration target. Therefore, it becomes possible to inject more radiopharmaceuticals into the living body. Further, since the outer peripheral surface of the spacer portion has a tapered shape, the spacer portion can be easily inserted into the passage hole of the male luer portion.

  Moreover, in the said luer connector, a part of outer peripheral surface of a spacer part may have a taper shape. Even in such a case, the spacer portion can be easily inserted into the passage hole of the male luer portion.

  Moreover, in the said luer connector, the spacer part may also contain the material which swells by touching a liquid. Thereby, the liquid amount of the non-radioactive water inject | poured into the chemical administration object can further be reduced.

  In the luer connector, the tube extends between the male luer part insertion hole and the male luer part insertion hole on one side of the female luer part opposite to the male luer part insertion hole. , And may be disposed between the tube and the inner surface of the passage hole. Thereby, a spacer part can be easily attached to a female luer part.

  The drug injection device according to the present invention is a drug injection device for injecting a radioactive drug into a living body following non-radioactive water. The drug injection device includes a drug container that contains a radiopharmaceutical, a water container that contains non-radioactive water, a drug delivery syringe that pushes out the radiopharmaceutical after aspirating the radiopharmaceutical in the drug container, and a non-radioactive substance in the water container. A water delivery syringe that sucks out water and pushes out non-radioactive water, a cylindrical male luer part having a passage hole through which non-radioactive water and a radiopharmaceutical pass, and an male luer having an inner peripheral surface that fits with the outer peripheral surface of the male luer part The female luer part which has a part insertion hole, the tube which connects the indwelling needle and female luer part of a chemical | medical agent injection apparatus, and a non-radioactive water and a radioactive chemical | medical agent pass are provided. A female luer part has a cylindrical spacer part inserted in the passage hole of a male luer part at the time of a fitting with a male luer part. The outer peripheral surface of the spacer portion has a tapered shape.

  In the above-described drug injection device, during drug administration, the radiopharmaceutical from the drug container reaches the indwelling needle through the male luer part and the female luer part, and is injected into the drug administration target. The reason why the male luer part and the female luer part are interposed between the drug container and the indwelling needle is to replace the drug flow path from the filter with the air vent to the indwelling needle for each experiment. The present inventor has found that the amount of non-radioactive water filled in advance can be reduced by reducing the internal space of the conventional male luer part.

  That is, the above-mentioned medicine injection device is provided with a cylindrical male luer part and a female luer part having a male luer part insertion hole that fits into the male luer part, and the female luer part of the male luer part is fitted with the male luer part. A cylindrical spacer portion is inserted into the passage hole. Thus, the volume of the internal space of the passage hole of a male luer part can be reduced by arrange | positioning a cylindrical spacer part in the passage hole of a male luer part. Therefore, according to said chemical | medical agent injection apparatus, the liquid quantity of the non-radioactive water previously satisfy | filled in a lure connector can be reduced, and the liquid quantity of the non-radioactive water inject | poured into a chemical | medical agent administration object by this can be reduced. Therefore, it becomes possible to inject more radiopharmaceuticals into the living body. Further, since the outer peripheral surface of the spacer portion has a tapered shape, the spacer portion can be easily inserted into the passage hole of the male luer portion.

  According to the luer connector and drug injection device of the present invention, the amount of non-radioactive water injected into the drug administration target can be reduced.

It is a figure showing composition of a medicine injection device concerning one embodiment of the present invention. It is a flowchart explaining operation | movement of a chemical | medical agent injection apparatus. It is a side view which shows the structure of a luer connector. (A) It is a figure which shows the cross section along the flow path of a luer connector. (B) It is a figure which shows the cross section along the IV-IV line of (a). (A) It is a figure which shows the cross section along the flow path of the lure connector as a comparative example. (B) It is a figure which shows the cross section along the VV line of (a). (A) It is sectional drawing which shows the shape of the lure connector which concerns on a 1st modification, Comprising: The cross section along the flow direction is shown. (B) It is a figure which shows the cross section along the VI-VI line of (a). It is sectional drawing which shows the shape of the spacer part which concerns on a 2nd modification, Comprising: The cross section along a flow direction is shown.

  Embodiments of a luer connector and a drug injection device according to the present invention will be described below in detail with reference to the accompanying drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted.

  FIG. 1 is a diagram showing a configuration of a pharmaceutical injection device 1A according to an embodiment of the present invention. This drug injection device 1A is a device for injecting a radiopharmaceutical 412 labeled with a radioisotope (RI) into a living body in order to perform a physiological examination of the living body, and the injected RI uses a radiation detector. Measured.

  The RI vial 411 is a drug container that houses the radioactive drug 412. The RI vial 411 is a glass container having an opening, and the opening is sealed with a rubber cap. In addition, injection needles 311, 321, 31 pass through this cap. Tubes 310, 320, and 30 are connected to the injection needles 311, 321, and 31, respectively, to ensure liquid and gas flow paths that flow through the tubes. The RI vial 411 is disposed in the RI counter unit 410. The RI counter unit 410 is provided with a radiation counter 410 a and measures the radiation dose in the RI vial 411.

  The tube 30 is connected to one end of the medicine delivery syringe 230a and the tube 40 via the composite check valve C2. The composite check valve C2 has check valves C2a and C2b, and the radiopharmaceutical 412 from the RI vial 411 flows from the tube 30 through the check valve C2a to the drug delivery syringe 230a. The drug delivery syringe 230 a sucks the radiopharmaceutical 412 in the RI vial 411 and then pushes out the radiopharmaceutical 412. The radioactive medicine 412 delivered from the medicine delivery syringe 230a passes through the check valve C2b and flows to the tube 40.

  The other end of the tube 40 is connected to the composite check valve C3. The composite check valve C3 includes a check valve C3a and a check valve C3b. The check valve C3a is connected to one end of the tube 50. The check valve C3a allows passage of the medium from the tube 50 to the filter 70 with the air vent, but does not allow passage in the opposite direction. The check valve C3b is connected to the tube 60 via the filter 70 with air vent and the luer connector 10. The check valve C3b allows passage of the medium from the composite check valve C2 to the air vented filter 70, but does not allow passage in the opposite direction.

  The other end of the tube 50 is connected to one end of the water delivery syringe 240a and the tube 80 via the composite check valve C1. The other end of the tube 80 is connected to a water container 250 that contains non-radioactive water (for example, physiological saline) 251. The composite check valve C1 includes a check valve C1a and a check valve C1b. The check valve C1a allows the medium to flow from the tube 80 to the composite check valve C1, but does not allow the passage in the opposite direction. The check valve C1b allows the medium to flow out of the tube 80 and the water delivery syringe 240a into the tube 50, but does not allow passage in the opposite direction. Therefore, the non-radioactive water 251 from the water container 250 flows from the tube 30 to the water delivery syringe 240a through the check valve C1a. The water delivery syringe 240a sucks the non-radioactive water 251 in the water container 250 and then pushes out the non-radioactive water 251. The non-radioactive water 251 delivered from the water delivery syringe 240a passes through the check valve C1b and flows to the tube 50.

  A tube 60 is connected to the emission port of the filter 70 with the air vent via the luer connector 10, and an indwelling needle 245 is provided at the tip of the tube 60. The radiopharmaceutical 412 delivered from the medicine delivery syringe 230a reaches the indwelling needle 245 through the tube 60 and is injected into the living body from the indwelling needle 245. Further, in order to prevent the injection of air into the living body, the non-radioactive water 251 is delivered from the water delivery syringe 240a before being injected with the radiopharmaceutical 412 and is left in the luer connector 10 and the tube 60. Further, after the injection of the radiopharmaceutical 412, in order to inject all the radiopharmaceutical 412 remaining in the filter 70 with the air vent, the tube 60 and the indwelling needle 245, non-radioactive water 251 is delivered from the water delivery syringe 240a, and the tube 60 is passed through. It passes through the indwelling needle 245 and is injected from the indwelling needle 245 into the living body. The reason why the luer connector 10 is interposed between the RI vial 411 and the indwelling needle 245 is that the indwelling needle 245 can be replaced.

  Here, operation | movement of 1 A of chemical | medical agent injection apparatuses of this embodiment is demonstrated using the flowchart of FIG. First, the radiopharmaceutical 412 and nitrogen are transported from the automatic synthesizer into the RI vial 411 through the tube 310 (step S1). The transported radiopharmaceutical 412 accumulates in the RI vial 411, and the injected nitrogen is released to the outside through the tube 320. Next, the radiation dose of the radiopharmaceutical 412 accumulated in the RI vial 411 is measured using the RI counter unit 410 (step S2).

  Subsequently, the water delivery syringe 240a sucks the non-radioactive water 251 in the water container 250 (step S3). Then, the water delivery syringe 240a pushes out the non-radioactive water 251 (Step S4). At this time, the non-radioactive water 251 reaches the luer connector 10, the tube 60, and the indwelling needle 245 through the composite check valve C1 and the composite check valve C3. The non-radioactive water 251 is placed inside the luer connector 10, the tube 60 and the indwelling needle 245.

  Subsequently, the drug delivery syringe 230a sucks the radiopharmaceutical 412 in the RI vial 411 (step S5). At this time, not only the radiopharmaceutical 412 but also nitrogen is aspirated before and after the radiopharmaceutical 412 is aspirated. Therefore, the radioactive medicine 412 and nitrogen are accommodated in the medicine delivery syringe 230a. At this time, the radioactive drug 412 that is a liquid accumulates in the lower part of the drug delivery syringe 230a, and nitrogen accumulates in the upper part. Thereafter, the medicine delivery syringe 230a pushes out the radioactive medicine 412 using nitrogen as a carrier medium (step S6). At this time, the radiopharmaceutical 412 reaches the indwelling needle 245 through the composite check valve C2, the composite check valve C3, the luer connector 10, and the tube 60. The radiopharmaceutical 412 is injected into the living body from the indwelling needle 245. At this time, the non-radioactive water 251 previously placed is also pushed out and injected into the living body. In addition, since the nitrogen which carried the radiopharmaceutical 412 is discharge | released outside from the filter 70 with an air vent, it is not inject | poured into a biological body.

  Subsequently, the water delivery syringe 240a sucks the non-radioactive water 251 in the water container 250 again (step S7). Then, the water delivery syringe 240a pushes out the non-radioactive water 251 (Step S8). At this time, the non-radioactive water 251 reaches the luer connector 10, the tube 60, and the indwelling needle 245 through the composite check valve C1 and the composite check valve C3. The non-radioactive water 251 is injected into the living body together with the radiopharmaceutical 412 remaining inside the filter 70 with the air vent, the luer connector 10, the tube 60, and the indwelling needle 245. Thereby, the whole amount of the predetermined amount of the radiopharmaceutical 412 is injected into the living body.

  Here, the luer connector 10 of the present embodiment will be described in detail. FIG. 3 is a side view showing the configuration of the luer connector 10 of the present embodiment. The luer connector 10 includes a male luer part 11 and a female luer part 12. The male luer part 11 is a cylindrical member, and is made of, for example, an elastic resin. The male luer part 11 is connected to the water container 250 and the RI vial 411 shown in FIG. In this embodiment, the male luer part 11 is fixed to the filter 70 with an air vent and integrated with the filter 70 with an air vent.

  The male luer portion 12 is provided at the other end of the tube 60 to which the indwelling needle 245 shown in FIG. 1 is attached. The male luer portion 12 communicates with the male luer portion 11 by fitting with the male luer portion 11, so that the radiopharmaceutical 412 flows. Keep the road airtight. The female luer part 12 of the present embodiment has a spacer part 13. The spacer portion 13 is inserted into the male luer portion 11 when fitted with the male luer portion 11.

  FIG. 4A is a diagram showing a cross section along the flow path of the luer connector 10. FIG. 4B is a view showing a cross section taken along line IV-IV in FIG. 4A, and shows a cross section perpendicular to the flow path of the luer connector 10. These drawings show a state in which the male luer part 11 and the female luer part 12 are fitted to each other.

  As shown in FIG. 4, the male luer portion 11 includes a disk-shaped base portion 11a that extends in a plane direction intersecting the flow direction (arrow A1 in the drawing), and a flow direction A1 from the center of the base portion 11a. And a cylindrical tubular portion 11b extending along the axis. The cylindrical portion 11 b is a portion that is fitted into the female luer portion 12. In order to facilitate the insertion of the cylindrical portion 11b into the female luer portion 12, the outer peripheral surface 11d of the cylindrical portion 11b is tapered, and the distal end portion of the cylindrical portion 11b (on the side opposite to the base portion 11a). The outer diameter of the cylindrical portion 11b is smaller as the end portion is closer.

  The cylindrical portion 11b has a passage hole 11c extending along the flow direction A1. The passage hole 11c is a hole for allowing the non-radioactive water 251 and the radiopharmaceutical 412 to pass therethrough, and a cross section perpendicular to the flow direction A1 is circular.

  The male luer part 12 is made of, for example, an elastic resin, and has a male luer part insertion hole 12a that fits into the cylindrical part 11b of the male luer part 11. The male luer portion insertion hole 12 a extends along the flow direction A <b> 1 and opens toward the male luer portion 11. A cross section of the male luer fitting hole 12a perpendicular to the flow direction A1 is circular. Further, the inner surface of the male luer portion insertion hole 12a is tapered in accordance with the outer peripheral surface 11d of the cylindrical portion 11b, and the inner diameter of the male luer portion insertion hole 12a increases as the opening of the male luer portion insertion hole 12a is closer. ing.

  The spacer portion 13 is a cylindrical member extending from the bottom surface 12 b of the male luer portion insertion hole 12 a toward the base portion 11 a of the male luer portion 11, and is fitted into the passage hole 11 c of the male luer portion 11 when fitted with the male luer portion 11. Inserted. In one example, the length of the spacer portion 13 in the flow direction A1 is equal to the length of the cylindrical portion 11b in the same direction. In order to facilitate the insertion of the male luer part 11 into the cylindrical part 11b, the outer peripheral surface 13a of the spacer part 13 has a tapered shape, and the tip part of the spacer part 13 (the bottom surface 12b of the male luer part fitting hole 12a) The closer to the opposite end), the smaller the outer diameter of the spacer portion 13. The inner surface of the passage hole 11 c is also tapered to match the spacer portion 13. The spacer portion 13 may include a material that swells when touched with a liquid such as non-radioactive water 251.

  The tube 60 that connects the indwelling needle 245 and the female luer part 12 passes between the male luer part insertion hole 12a opposite to the male luer part insertion hole 12a of the female luer part 12 and the male luer part insertion hole 12a. Extends inside. And the spacer part 13 has covered the tube 60, and is arrange | positioned between the tube 60 and the inner surface of the passage hole 11c at the time of insertion.

  The effects obtained by the luer connector 10 and the pharmaceutical injection device 1A of the present embodiment described above will be described. In the drug injection device 1A, during drug administration, the radiopharmaceutical 412 reaches from the RI vial 411 containing the radiopharmaceutical 412 through the luer connector 10 to the indwelling needle 245 and is injected into the living body. The inventor has found that by reducing the internal space of the male luer portion 11 of the luer connector 10, the amount of the non-radioactive water 251 filled in advance in step S <b> 4 of FIG. 2 can be reduced.

  Fig.5 (a) is a figure which shows the cross section along the flow path of the luer connector 100 as a comparative example. FIG. 5B is a view showing a cross section taken along the line VV in FIG. 5A, and shows a cross section perpendicular to the flow path of the luer connector 100. Usually, like the luer connector 100, the inner diameter of the passage hole 110 a of the cylindrical portion 112 of the male luer portion 110 fitted into the female luer portion 120 is relatively larger than the inner diameter of the tube 114. The volume of the internal space of the passage hole 110a is, for example, 0.1 ml. And in step S4 of FIG. 2, the non-radioactive water 251 will be beforehand filled with the internal space of this passage hole 110a. Therefore, there is a problem that the total amount of liquid injected into the living body increases.

  In contrast, in the luer connector 10 and the pharmaceutical injection device 1A of the present embodiment, the female luer portion 12 has a cylindrical spacer portion 13 that is inserted into the passage hole 11c of the male luer portion 11 when fitted to the male luer portion 11. . Thus, by arranging the cylindrical spacer portion 13 in the passage hole 11c of the male luer portion 11, the volume of the internal space of the passage hole 11c of the male luer portion 11 can be reduced. Therefore, according to the luer connector 10 and the medicine injection device 1A, the amount of the non-radioactive water 251 filled in the luer connector 10 in advance in step S4 of FIG. 2 is reduced, and thereby the non-radioactive water 251 injected into the living body. The amount of liquid can be reduced. Therefore, it becomes possible to inject more radiopharmaceuticals 412 into the living body. Moreover, since the outer peripheral surface 13a of the spacer part 13 has a taper shape, the spacer part 13 can be easily inserted into the passage hole 11c of the male luer part 11, and the spacer part 13 does not leak into the male luer part 11. Can be installed.

  Further, as described above, the spacer portion 13 may include a material that swells when touched by a liquid such as non-radioactive water 251. Thereby, the liquid quantity of the non-radioactive water 251 inject | poured into a biological body can further be reduced.

  Further, as in this embodiment, the tube 60 extends between the one end 12c of the female luer part 12 and the male luer part fitting hole 12a and extends into the male luer part fitting hole 12a, and the spacer part 13 is formed of the tube. 60 and the inner surface of the passage hole 11c. Thereby, the spacer part 13 can be easily attached to the female luer part 12. Specifically, first, the tube 60 may be penetrated from the one end 12 c of the female luer portion 12 to the bottom surface 12 b, and then the spacer portion 13 may be fitted into the tube 60.

  In addition, when synthesizing the radiopharmaceutical 412, it is filtered using a filter to remove dust, etc., but when the radiopharmaceutical 412 (which has been dissolved in physiological saline) is collected with a gas by pushing it with a gas, The radiopharmaceutical 412 could not be recovered by a volume that could not be pushed. By using the luer connector 10 of this embodiment, the volume can be reduced and the collection amount of the radiopharmaceutical 412 can be increased.

(First modification)
Fig.6 (a) is sectional drawing which shows the shape of 10 A of luer connectors which concern on the 1st modification of the said embodiment, Comprising: The cross section along the flow direction A1 is shown. FIG. 6B is a view showing a cross section taken along the line VI-VI in FIG. 6A and showing a cross section perpendicular to the flow path of the luer connector 10A. The luer connector 10 of the above embodiment may be replaced with the luer connector 10A shown in this figure.

  In the example shown in FIG. 6, unlike the above embodiment, the tube 60 that connects the indwelling needle 245 (see FIG. 1) and the female luer part 12 has one end 12 c on the opposite side of the male luer part insertion hole 12 a of the female luer part 12. And one end of the tube 60 is attached to one end 12c of the female luer portion 12. Therefore, the spacer portion 23 does not cover the tube 60, and one end thereof is fixed to the bottom surface 12b of the male luer portion insertion hole 12a. Even if it is such a form, the effect of the said embodiment can be show | played suitably. The spacer portion 23 may be integrally formed with the female luer portion 12.

(Second modification)
FIG. 7 is a cross-sectional view showing the shape of the spacer portion according to the second modification of the embodiment, and shows a cross section along the flow direction A1. In addition, in this figure, illustration of the male luer part 11 and the female luer part 12 is abbreviate | omitted. The spacer portion 13 of the above embodiment may be replaced with the spacer portion shown in this figure.

  In the example shown in FIG. 7, unlike the above embodiment, a part 33b of the outer peripheral surface 33a of the spacer part 33 has a tapered shape, and a part 33b of the outer peripheral surface 33a has a tip part of the spacer part 33. The outer diameter of the spacer portion 33 is smaller as the distance from the second is closer. Even if it is such a form, the effect of the said embodiment can be show | played suitably, and the spacer part 33 can be easily inserted in the passage hole 11c of the male luer part 11. FIG.

  DESCRIPTION OF SYMBOLS 1A ... Drug injection device, 10, 10A ... Luer connector, 11 ... Male luer part, 11a ... Base part, 11b ... Cylindrical part, 11c ... Pass-through hole, 11d ... Outer peripheral surface, 12 ... Female luer part, 12a ... Male luer part insertion Hole, 12b ... bottom surface, 13 ... spacer part, 13a ... outer peripheral surface, 30, 40, 50, 60, 80 ... tube, 70 ... filter with air vent, 230a ... drug delivery syringe, 240a ... water delivery syringe, 245 ... indwelling needle , 250 ... Water container, 251 ... Non-radioactive water, 411 ... RI vial, 412 ... Radiopharmaceutical, C1-C3 ... Composite check valve.

Claims (5)

A luer connector used in a drug injection device for injecting a radiopharmaceutical into a living body following non-radioactive water,
A cylindrical male luer part connected to a water container containing the non-radioactive water and a drug container containing the radiopharmaceutical, and having a passage hole through which the non-radioactive water and the radiopharmaceutical pass.
A female luer part having a male luer part insertion hole that is provided at the other end of the tube attached to one end of the indwelling needle of the drug injection device,
With
The female luer part has a cylindrical spacer part that is inserted into the passage hole of the male luer part when fitted with the male luer part,
A luer connector, wherein an outer peripheral surface of the spacer portion has a tapered shape.   The luer connector according to claim 1, wherein a part of the outer peripheral surface of the spacer portion has a tapered shape.   The luer connector according to claim 1, wherein the spacer portion includes a material that swells when touched by a liquid. The tube extends between the male luer part insertion hole and one end of the female luer part opposite to the male luer part insertion hole and the male luer part insertion hole.
The said spacer part is arrange | positioned between the said tube and the inner surface of the said passage hole, The lure connector as described in any one of Claims 1-3 characterized by the above-mentioned. A drug injection device for injecting a radiopharmaceutical into a living body following non-radioactive water,
A drug container containing a radiopharmaceutical;
A water container containing non-radioactive water;
A drug delivery syringe that sucks out the radiopharmaceutical in the drug container and then pushes out the radiopharmaceutical;
A water delivery syringe that sucks out the non-radioactive water in the water container and then pushes out the non-radioactive water;
A cylindrical male luer part having a passage hole through which the non-radioactive water and the radiopharmaceutical pass,
A female luer part having a male luer part insertion hole to be fitted to the male luer part,
A tube through which the non-radioactive water and the radiopharmaceutical pass, connecting the indwelling needle of the drug injection device and the female luer part,
With
The female luer part has a cylindrical spacer part that is inserted into the passage hole of the male luer part when fitted with the male luer part,
An outer peripheral surface of the spacer portion has a taper shape.

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