JPH0139779B2 - - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a blood sampler, and more particularly to a blood sampler suitable for use in blood gas analysis.

Prior Art In general, in order to know the lung function and acid-base balance state of the human body, it is necessary to measure the content of oxygen and carbon dioxide in the arterial blood, measure the oxygen saturation level and PH of the arterial blood, and measure HCO ₃ ^- and Na in the blood. Blood gas analysis, including quantitative analysis of electrolyte components such as ⁺ , K ⁺ , and Cl ^-, is performed.

The blood gas analysis described above is performed by collecting blood from a patient using a blood sampler and then transferring the sampled blood from the blood sampler to a blood gas analyzer.

Conventionally, the blood sampler for blood gas analysis described above includes an outer cylinder with a sampling port at its tip, and a pusher that is inserted into the outer cylinder from the proximal opening of the outer cylinder and is movable in the axial direction of the outer cylinder. and a gasket which is attached to the insertion end of the pusher into the outer cylinder so as to be able to slide in close contact with the inner surface of the outer cylinder and to define a blood sampling space within the outer cylinder; The air in the sampling space can be exhausted to the outside during blood sampling, and the air in the sampling space can be vented to the outside to cut off contact between the blood in the sampling space and the outside space after blood sampling. A blood sampling device has been proposed comprising a sphere contained therein and coated with an anticoagulant.

According to the blood sampling device already proposed above,
The presence of the evacuation and isolation means eliminates the possibility of contact and contamination of the collected blood with air, making it possible to obtain accurate blood gas analysis results. In addition, after blood collection, the blood collector is tipped over with one hand, and the anticoagulant-coated sphere is moved up and down in the collected blood, allowing the anticoagulant to be efficiently dissolved in the blood with a simple operation. This makes it possible to more completely anticoagulate the collected blood and prevent malfunctions of the blood gas analyzer due to micro clots and the like.

However, in the case of the blood sampler already proposed above, when transferring the sampled blood from the sampling space to the blood gas analyzer via the sampling port by pushing the pusher into the outer cylinder, the above-mentioned There is a risk that the sphere coated with anticoagulant will sit tightly on the inner surface of the outer cylinder around the sampling port, clogging the sampling port and making it difficult or impossible to smoothly discharge the collected blood to the blood gas analyzer. There is.

OBJECTS OF THE INVENTION The present invention eliminates contact of collected blood with air;
To provide a blood sampling device which enables a more complete anticoagulation state of collected blood to be obtained through simple operation and also enables smooth discharge of the collected blood to a blood gas analyzer, etc. The purpose is to

Structure and operation of the invention The present invention provides an outer cylinder having a collection port at its tip, a pusher that is inserted into the outer cylinder from the proximal opening of the outer cylinder and is movable in the axial direction of the outer cylinder, and a pusher that is movable in the axial direction of the outer cylinder. A gasket is attached to the insertion end into the outer cylinder so that it can slide in close contact with the inner surface of the outer cylinder, and also allows a blood sampling space to be defined within the outer cylinder, and a gasket that defines the blood sampling space as an external space. a partition member provided in a through hole that communicates with the blood collection space to allow air to pass therethrough at least when not in contact with blood and to prevent free passage of blood at least when in contact with blood; and a partition member housed in the collection space and coated with an anticoagulant. In the blood sampling device, the stirring bar is made of a polyhedron having a concave surface.

According to the present invention, there are the following effects.

Due to the presence of a partition member made of a water-swellable filter or a hydrophobic filter, the air in the collection space can be exhausted to the outside during blood collection, and contact between the blood in the collection space and the outside space can be cut off after blood collection. Become. This means that the collected blood is free from contact with air and the possibility of air contamination, making it possible to obtain accurate blood gas analysis results.

Due to the presence of a stirrer coated with an anticoagulant, after blood collection, by moving the stirrer within the collected blood by, for example, tipping over the blood sampler, the anticoagulant can be dissolved and mixed into the blood at the same time. as a result of which it is possible to obtain a more complete anticoagulant status of the blood.

When the stirrer is seated on the inner surface of the sampling port of the outer cylinder when discharging the collected blood to the blood gas analyzer,
The concave surface of the stirring bar reliably forms a blood flow path between the inner surface of the sampling port, which eliminates clogging of the sampling port by the stirring bar, and allows blood to be drained smoothly as a result.

DETAILED DESCRIPTION OF THE INVENTION FIG. 1 shows a blood sampling device 1 according to an embodiment of the present invention.
FIG. 2 is an enlarged cross-sectional view of the main part of FIG. 1.

The outer cylinder 11 of the blood sampling device 10 has a substantially straight cylindrical shape. The distal end of the outer cylinder 11 is tapered and has a tapered part 13 having a conical inner surface 12 and a nozzle part 15 forming a sampling port 14 . Further, a handle 16 is provided at the base end of the outer cylinder 11, and an opening 17 is formed in the center thereof.

A fixing collar 19 is provided at the tip of the outer cylinder 11 so as to protrude around the nozzle portion 15 and has a spiral rib 18 on its inner surface. Above outer cylinder 1
A hub 21 of a blood collection needle 20 is fitted into the nozzle part 15 of the blood collection needle 20, and the hub 21 of the blood collection needle 20 has a flange part 22 attached to the helical rib 18 of the fixing collar 19.
By screwing into the nozzle part 15, the connection with the nozzle part 15 is made tighter.

A pusher 23 can be inserted into the base end opening 17 of the outer cylinder 11 . The pusher 23 is movable in the axial direction of the outer cylinder 11. A gasket 24 is attached to the insertion end of the pusher 23 into the outer cylinder 11.
That is, the pusher 23 and the gasket 24 are arranged such that the engagement protrusion 25 formed at the insertion end of the pusher 23 into the outer cylinder 11 is connected to the engagement recess formed at the end of the gasket 24 on the pusher 23 side. 26 to achieve mutual connection. Here, the gasket 24 is slidable with the ring-shaped portion 27 on the side of the pusher 23 and the skirt portion 28 on the side opposite to the pusher 23 in a state in which the entire circumferential surface thereof is in close contact with the inner surface of the outer cylinder 11.
A blood sampling space 29 of arbitrary volume can be defined by the end surface on the opposite side of the pusher 23 and the inner surface of the outer cylinder 11.

A through hole 30 is formed in the center of the gasket 24, and a water-swellable filter 31, which serves as a partition member in the present invention, is attached to the through hole 30. Here, the pusher 23 is provided with an exhaust hollow part 32 that penetrates the entire length in the axial direction and communicates with the through hole 30. That is, the blood collection space 29
can be communicated with the outside via a through hole 30, a filter 31, and a hollow part 32 for exhaust. Therefore, when blood is collected, the filter 31, which is not in contact with the blood, allows air to pass through the blood collection space 2.
Air that previously existed in the blood collection space 29 is discharged to the outside through the through hole 30, the filter 31, and the exhaust hollow part 32, and after blood collection, the filter 31 is swollen by the blood filling the blood collection space 29. Since it prevents the free passage of blood, contact between the collected blood and the outside air is easily cut off. Note that the filter 31
is made of a sintered body of thermoplastic plastic such as polyethylene or polypropylene due to its moldability.
The water-swellable material contained in this material is known as a super-absorbent resin that swells hundreds of times when it comes in contact with water and prevents blood from permeating. Resin is contained inside the filter 31 in a normal state. Examples include starch graft compounds such as starch-acrylonitrile, acrylic polymers, and the like. Further, as the filter 31, a filter generally known as a hydrophobic filter that allows air to pass through but not liquid can be used, and in this case, it is not necessary to contain a water-swellable material.

A stirrer 33 made of glass, styrene resin, stainless steel, etc. and coated with a freeze-dried blood anticoagulant is accommodated in the blood collection space 29. The stirrer 33 is the third
As shown in the figure, the sampling port 1 is connected to the blood sampling space 29.
It is constituted by a spherical body having an outer diameter larger than the diameter of 4 and having a large number of concave surfaces 34 on its surface.
Further, the surface of the stirring bar 33 is preferably satin-like. This is because more blood anticoagulant can be coated. That is, when the collected blood in the blood collection space 29 is discharged to a blood gas analyzer or the like through the collection port 14, the stirring bar 33 moves the conical shape of the tapered portion 13 of the outer cylinder 11 as shown in FIG. When seated on the inner surface 12, the presence of the concave surface 34 reliably forms a flow path for blood between the conical inner surface 12 and the concave surface 34, making it possible for the blood to flow out smoothly. In addition, the stirrer in the present invention is
Any shape that forms a flow path for blood between the inner surface of the outer cylinder and the surface of the stirring element when the stirring element is seated on the inner surface of the outer cylinder around the sampling port may be used, such as an ellipsoid with a concave surface or other shapes. It may be made of polyhedron.

Here, the anticoagulant coated on the stirring bar 33 includes heparin salts such as heparin sodium, heparin potassium, and heparin lithium;
EDTA salts such as EDTA-2Na and EDTA-2K, other citrates, fluoride salts, oxalates, double oxalates, etc. can be used. However, since heparin salt itself is harmless to the human body, it is suitable for use, and when measuring Na ⁺ and K ⁺ in blood, anticoagulants such as sodium and potassium salts are used. And, after dissolving in blood, those Na and K are
Salts other than these, such as heparin lithium salt, are more suitable since they act as Na ⁺ and K ⁺ and affect the test results.

In addition, in the case of the blood sampling device 10, the outer cylinder 1
When the pusher 23 is pulled out or pushed into the pusher 1, the engagement protrusion 25 of the pusher 23 and the gasket 24
The engagement abutment surfaces of the engagement recess 26 in the pulling direction or pushing direction can be brought into close contact with each other, and the blood collection space 29 is connected to the inner surface of the outer cylinder 11 via the through hole 30 and the filter 31. There is no communication with the gap formed by the outer surface of the child 23. Therefore, when collecting blood from a patient with low blood pressure such as a child or the elderly, the opening 3 of the hollow part 32 for exhaust of the pusher 23
By gradually pulling out the pusher from the outer cylinder 11 while the pusher 5 is closed with a thumb or the like, a negative pressure is created in the blood collection space 29, thereby making it possible to smoothly collect blood. becomes. In addition, when the blood sampling space 29 is to discharge the collected blood to a blood gas analyzer or the like, the opening 35 of the hollow part 32 for exhaust is used.
By pushing the pusher 23 into the outer cylinder 11 while closing it with the thumb or the like as described above, blood can be smoothly discharged. Here, a grip portion 36 is integrally formed on the outer end of the pusher 23, making it possible to easily move the pusher 23. The opening 35 of the exhaust hollow part 32 is formed in the center of the grip part 36, and the peripheral edge of the opening 35 is a ring-shaped protrusion 37 that protrudes outward in the axial direction by a predetermined height. The aim is to ensure pressure closure using the thumb, etc.

Further, in this embodiment, the outer cylinder 11 and the pusher 23 are made of transparent plastic such as polyethylene or polypropylene, and the gasket 24 is made of an elastic body made of various elastomers such as rubber or polyurethane.

Specific Effects of the Invention Next, the effects of the blood sampling device 10 will be explained.

First, the blood collection needle 20 is attached to the nozzle part 15 of the outer cylinder 11, and the gasket 24 is slid inside the outer cylinder 11 by moving the pusher 23 with respect to the outer cylinder 11.
A blood collection space 29 with a required volume is secured inside the outer cylinder 11. Next, the blood collection needle 20 is punctured into the patient's artery,
The blood pressure of the arterial blood causes the blood to be squirted into the sampling space 29. As this blood flows in, the air in the blood collection space 29 is discharged to the outside through the through hole 30, the filter 31, and the exhaust hollow part 32. In addition,
When this blood flows in, the jet of blood due to blood pressure is
First, it hits the stirrer 33 and its force is weakened,
The blood flows into the blood collection space 29 . Therefore, the jet of blood does not generate bubbles in the corners of the outer cylinder 11, the flow path of the sampling port 14, etc., and the blood wets the filter 31 before the air in the blood sampling space 29 is completely removed. The exhaust action by the filter 31 is not interrupted.

As the blood collection progresses in this way, the blood level in the blood collection space 29 gradually rises as shown in FIGS. 4 and 5, and when the blood comes into contact with the filter 31, the filter 31 is swollen. Contact between the collected blood and the outside air is interrupted. Under this condition,
While removing the blood collection needle 20 from the patient's artery,
Attach a rubber cap or urethane protector to the tip and complete blood collection.

Here, if the patient's blood pressure is insufficient, the required amount of blood will not flow into the blood collection space 29. In such a case, the blood collection space 29 can be closed by gradually pulling out the pusher 23 from the outer cylinder 11 while pressing and closing the opening 35 of the exhaust hollow 32 formed in the pusher 23 with your thumb or the like. A negative pressure is created inside the body, and the patient's low blood pressure is sucked out by this negative pressure.
Enables blood collection of a predetermined volume.

After a predetermined volume of blood has been collected in this way,
By tipping the blood collector 10 with one hand, the stirring bar 33 in the blood sampling space 29 is moved up and down in the collected blood, dissolving the anticoagulant coated on the surface of the stirring bar 33, and dissolving the anticoagulant in the blood. to achieve a more complete anticoagulation state of the blood.

The sampled blood collected as described above and mixed with an anticoagulant is then transferred to a blood gas analyzer. That is, in this case, if the pusher 23 is pushed into the outer cylinder 11 while the opening 35 of the exhaust hollow 32 formed in the pusher 23 is closed with a thumb or the like, the collected blood will be removed. As shown in FIG. 2, the conical inner surface 12 of the outer cylinder 11 and the concave surface 34 of the stirrer 33
The blood can be smoothly discharged from the sampling port 14 to the blood gas analyzer side through the blood flow path formed between the two.

Specific Effects of the Invention As described above, the present invention provides an outer cylinder having a collection port at its tip, and a pusher that is inserted into the outer cylinder from the proximal opening of the outer cylinder and is movable in the axial direction of the outer cylinder. a gasket attached to the insertion end of the pusher into the outer cylinder so as to be able to slide in close contact with the inner surface of the outer cylinder, and to define a blood sampling space within the outer cylinder;
a partition member provided in a through hole that communicates the sampling space with the external space, allowing air to pass through at least when not in contact with blood, and preventing free passage of blood at least when in contact with blood; A blood sampling device comprising a stirring bar coated with an anticoagulant, wherein the stirring bar is made of a polyhedron with a concave surface.
Therefore, according to the present invention, it is possible to eliminate the contact of the collected blood with air, to obtain a more complete anticoagulation state of the collected blood with a simple operation, and to reduce the blood gas in the collected blood. This allows for smooth discharge to an analyzer or the like.

Furthermore, in the blood sampling device according to the present invention, the anticoagulant is freeze-dried heparin salt, and since heparin salt is harmless to the body, the collected blood in which heparin salt has been dissolved is difficult to handle. Even if it flows back into the body due to a defect, it will not have any adverse effects on the human body.

Further, in the blood collector according to the present invention, the freeze-dried heparin salt is freeze-dried lithium heparin, so that Na ⁺ in the collected blood,
It does not affect the measurement of K ⁺ in any way.

Further, in the blood sampling device according to the present invention, the partition member is made of a water-swellable filter, so that after the blood sampling space is filled with blood, the filter is swollen by the blood, making it easy to It becomes possible to eliminate contact between the collected blood and external air. Further, in the blood sampler according to the present invention, by making the partition member a hydrophobic filter, it is possible to easily eliminate contact between the collected blood and external air.

Further, in the blood sampling device according to the present invention, the pusher is provided with a hollow part for exhaust that communicates with the through hole of the gasket, so that during normal blood collection, the pusher is provided with a hollow part for exhaust that communicates with the through hole of the gasket. The air in the blood sampling space can be exhausted to the outside, and when collecting blood from a patient with low blood pressure such as a child or the elderly, the pusher is moved from inside the outer cylinder while the opening of the hollow opening for exhaust is closed with a thumb or the like. By gradually withdrawing the blood, a negative pressure is created in the blood collection space, allowing for smooth blood collection.When discharging the collected blood to a blood gas analyzer, etc., the opening of the hollow part for exhaust is opened with your thumb, etc. By pushing the pusher into the outer cylinder under the closed condition, blood can be smoothly discharged.

Further, in the blood sampling device according to the present invention, by making the surface of the stirring bar satin-like, it becomes possible to coat a larger amount of anticoagulant.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional view showing a blood sampling device according to an embodiment of the present invention, FIG. 2 is a cross-sectional view showing an enlarged main part of FIG. 1, and FIG. 3 is a stirring bar in the same embodiment. 4 is a cross-sectional view showing the state when blood is collected by the blood sampler according to the same embodiment, and FIG. 5 is a cross-sectional view showing the state when blood collection is completed by the blood sampler according to the same embodiment. be. 10...Blood sampling device, 11...Outer tube, 14...
Collection port, 17... Opening, 23... Pusher, 24...
Gasket, 29...Blood collection space, 30...Through hole, 31...Filter, 32...Hollow part for exhaust,
33... Stirring bar, 34... Concave surface.

Claims (1)

[Claims] 1. An outer cylinder having a collection port at its tip, a pusher that is inserted into the outer cylinder from the proximal opening of the outer cylinder and is movable in the axial direction of the outer cylinder, and an outer cylinder of the pusher. A gasket is attached to the insertion end into the cylinder and is slidable in close contact with the inner surface of the outer cylinder, and also allows defining a blood sampling space within the outer cylinder, and communicating the sampling space with the external space. a partition member provided in the through hole that allows air to pass through at least when not in contact with blood and prevents free passage of blood at least when in contact with blood; 1. A blood sampling device comprising a stirring bar, wherein the stirring bar is made of a polyhedron with a concave surface. 2. The blood collector according to claim 1, wherein the anticoagulant is lyophilized heparin salt. 3. The blood collector according to claim 2, wherein the freeze-dried heparin salt is freeze-dried lithium heparin. 4. The blood collector according to any one of claims 1 to 3, wherein the partition member is a water-swellable filter. 5. The blood collector according to any one of claims 1 to 3, wherein the partition member is a hydrophobic filter. 6. The blood collector according to claim 4 or 5, wherein the pusher is provided with a hollow part for exhaust that communicates with the through hole of the gasket. 7. The blood collector according to any one of claims 1 to 6, wherein the stirrer is made of styrene resin or glass. 8. The blood collector according to any one of claims 1 to 7, wherein the stirring bar has a matte surface.