DE69209667T2 - Pierceable closure for evacuated test tubes - Google Patents

Abstract

In a test tube (P10) for taking blood samples by vacuum suction through a double-needle device having an external needle for insertion into the vein while the other needle is internal, coaxial with and opposed to the first and fitted with a protective sheath forming a slidable elastic cap, and able to perforate a diaphragm of the stopper (T10), said stopper has an external extension (T22), with axial cavity (T24), which projects from inside the test tube (P10) to end in the perforable diaphragm (T26) at the extremity of the extension (T22); said extension (T22) can be inserted into the recess of the internal needle of said sampling device, without the need for bayonet-type connection and disconnection. <IMAGE>

Description

Blood sampling systems which are well known and widely used comprise (see Fig. 1) a device 1 with a cylindrical guide body 1A to whose base 1B are attached an outer needle 3 for insertion into the vein and an inner needle 5 for piercing the rubber stopper T0 of an evacuated test tube P0; the rubber stopper T0 has a transverse wall which can be pierced by the needle 5 and a flange-like extension (which projects beyond the circumference of the test tube P0) to guide it in the hollow tube space of the cylinder 1A towards the needle 5. The needle 5 is encased in a sliding, pierceable, elastic protective sheath 7 which forms a sealing valve for the needle 5 and is designed to be pushed back by the transverse wall of the stopper P0 when the test tube with said stopper is inserted in the direction of the arrow f0 into the cavity of the cylinder 1A in order to take a sample; a predetermined negative pressure is created in the test tube P0, as a result of which - with the insertion of the test tube P0 and the piercing of the transverse wall of the stopper T0 by the needle 5 after the sheath 7 has been pushed back - blood is brought from the vein through the needles 3 and 7 into the test tube P0 in order to obtain the sample of a desired amount of blood which depends on the venous pressure, the capacity of the test tube P0 and the level of the negative pressure prevailing in the latter. These sampling systems make it possible to take several samples while the device 1 with the needle 3 is kept in the vein and without any danger to the patient, since the only operation to take a sample consists in inserting the evacuated test tube into the cavity of the cylinder 1A with a slight axial pressure to break the transverse wall and a slight axial pull to extract it.

This procedure can be repeated many times with new test tubes, while needle 3 remains in the vein.

A sampling system different from the above is also known, shown in Figures 2 and 3, using test tubes into which the sample is drawn by suction from a piston which slides along the test tube. As can be seen from Figures 2 and 3, the two-needle device 11 has an outer needle 13 for insertion into the vein and an inner needle which is located inside the cavity 11A formed by the body of the device 11; here too, the needle 15 has a sliding elastic protective cover 17 which is retracted after perforation and which advances again to close the channel formed by the two needles 13 and 15 after the sample has been taken. For taking a sample, a test tube P1 is provided which forms a cylinder-piston unit in which the piston P2 is moved by means of a rod P3 to suck in the liquid (blood) after the head T1 of the test tube P1 has been inserted into the cavity 11A so that the transverse wall T6 is pierced by the needle 5 and the protective cover 17 has been elastically pushed back over the needle 15; in order to exert a suction effect with the cylinder-piston unit, the head T1 is provided with projections T3 and the body 11 forming the cavity 11A is provided with L-shaped recesses 11B which extend inwards from the edge to enable a bayonet connection of the head T1 after its insertion into the cavity 11A by means of an angular rotation, whereby the projections P3 engage behind the inner end regions of the L-shaped recesses 11B; an opposite angular rotation must be carried out to extract the head T1 of the test tube P1 from the cavity 11A, whereupon the protective cover 17 advances again. This arrangement has a number of disadvantages, mainly because repeated operations must be carried out - which require a great deal of experience - to establish and release the functions of the bayonet lock by rotating the successive test tubes within the cavity 11A while the device 11 with the needle 13 is in the vein. In particular, there is a risk that the needle 13 may slip out of the vein or that the vein itself may be injured by sudden movements when changing the test tubes.

DE-A-18 18 046 discloses a stopper made of rubber for test tubes for taking blood samples by means of negative pressure; this stopper has an external extension with an axial cavity which starts from the interior of the test tube and ends with a pierceable transverse wall at the extreme end of the extension; said extension is insertable into the recess of an internal needle of the sampling device without the need for bayonet-like connection and release, but with a screw connection system which in any case requires an angular rotation to maintain the connection.

The above-mentioned disadvantages of DE-A-18 18 046 and the system shown in Figures 2 and 3 can be overcome with the invention, whereby an evacuated test tube analogous to the test tube P0, T0 is used to work with the unchanged device 11 and to replace the piston test tubes P1, T1.

The invention therefore relates to a stopper made of rubber - or a similar material - for test tubes intended for taking blood samples by means of negative pressure through a double needle device 11 comprising an external needle 13 for insertion into the vein, while the other or internal needle 15 is arranged coaxially with and opposite the first and is provided with a protective sheath forming a sliding elastic cap 17 and is able to pierce the transverse wall of said stopper; the stopper has an external extension, with an axial cavity which starts from the interior of the test tube and ends in the pierceable transverse wall at the external end of the extension; this external extension can be inserted into the recess of the internal needle 15 of the sample collection device 11.

According to the invention, said external extension is more or less cylindrical, preferably frustoconical with a slight, gradual taper. No angular rotations are required for connection.

The tip of the extension, which forms the external pierceable transverse wall, is preferably concave to capture any microdrop of blood that may form when withdrawn from the inner needle after sampling.

In one possible embodiment, the rubber stopper of the invention comprises a base part that can penetrate into the test tube to close it; said base part may or may not have one or more external recesses to allow the negative pressure to be built up when the base part of the stopper is partially inserted into the test tube; a flange-like stop must also be provided that remains outside the test tube.

The invention will be better understood by following the description and the attached drawing, the latter showing a practical, non-limiting embodiment of the invention. In the drawing:

Fig. 1 the known solution discussed above for the use of low pressure test tubes that are evacuated;

Fig. 2 and Fig. 3 the solution discussed above for the use of test tubes T1, which have a cylinder-piston system for suction;

Fig. 4 and Fig. 5 a test tube designed to work under negative pressure and using the device according to Fig. 2 and a view of a partial section of the separately shown stopper of the said test tube.

As shown in the accompanying drawing with reference to Fig. 4 and Fig. 5, a test tube P10 - in which a depression of a certain magnitude can be previously created - is equipped with a stopper T10 made of rubber or an equivalent material. This stopper T10 has a base T12 suitable for penetrating the well of the test tube and for closing the test tube (also with the aid of the depression prevailing in the test tube), and a flange T14 with which it bears against the edge of the test tube. The base T12 has a slightly frustoconical part T16 to ensure that it presses with a certain force against the wall of the test tube, and an end portion T18 to enable its insertion into the opening of the test tube P10; Recesses T20 may be formed in said portion T18 to allow a vacuum to be created inside the test tube during manufacture, with the portion T18 of the stopper T10 only slightly inserted into the opening of the test tube. The final insertion of the portion 16 of the stopper 10 under pressure into the test tube seals it and maintains the vacuum previously created in the cavity of the test tube. The stopper T10 extends beyond the flange T14 with an extension T22 which is typically frustoconical or more or less slightly tapered to allow its insertion into the cavity 11A in the same way as the extension T1 of the conventional test tube B1, T1. The extension T22 does not have any projections like those of T3, the bayonet connection of the test tube to the device 11 is avoided because the test tube T10 contains a vacuum and therefore does not require an axial movement of a piston, which would make it necessary to provide an axial connection between the part 11 and the test tube P1 of the conventional system according to figures 2 and 3. An axial cavity 24 extends from the inner end of the base part T12, which forms the effective stopper, into the extension T22 and up to its end where there is a pierceable transverse wall T26, analogous to the transverse wall T6 of the test tube P1, T1. The outer end of the extension T22 is concave, T28, to hold any microdrop of blood which may form during Removing the test tube P10, T10 from the needle 15 of the device 11.

With the test tube P10, T10, it is possible - as described - to use the device 11 - already known for use with piston test tubes P1 - with a test tube containing a precisely adjusted level of negative pressure in order to suck a predetermined quantity of blood; such a test tube P10, T10 only requires an extension T22 in order to be inserted into the cavity 11A, without the need for rotational movements to achieve a bayonet closure or suction operations with the rod of a piston. All that is required is the operation of inserting and perforating the transverse wall T26 by means of the needle 15, with the retraction and temporary compression of the elastic protective sheath 17, which closes the needle 15 again because it slides forward again when the test tube is removed. The sampling procedure is therefore reduced - even with the device 11 according to Fig. 2 - to a simple axial insertion and withdrawal of the test tube P10, T10 as in the known solution shown in Fig. 1, and the disadvantages mentioned above, as well as others known in systems according to Figs. 2 and 3, are avoided.

A further advantage of the test tube P10, T10 equipped with the extension T22 is that it can also be used with the device 1 of the known type already described with reference to Fig. 1.

It is understood that the drawing shows a non-limiting, pictorial embodiment which serves only as a practical representation of the invention, it being possible to modify it within the scope of the invention in terms of shapes and arrangements without thereby departing from the scope of the concept underlying the invention. All reference numerals appearing in the appended claims are intended to facilitate the readability of the claims by reference to the description and drawing and do not limit the scope of protection given by the claims.

Claims (4)

1. Stopper (T10) made entirely of rubber or of another similar material for a sample tube (P10) intended for taking blood samples by means of suction under vacuum through a double-needle device (11) comprising an external needle (13) for piercing the vein, while the other or internal needle (15) is arranged coaxially and opposite to the first and is provided with a sliding and elastic sheath (17), the stopper comprising, at the extreme end of an external extension (T22), a transverse wall (T26) comprising an axial cavity (T24) starting from the interior of the sample tube (P10) to end at said transverse wall (T26) which can be pierced by the internal needle, and said extension (T22) being inserted in a recess (11a) of the sample collection device. (11) in which the inner needle (15) is arranged, characterized in that said outer extension (T22) is frustoconical. 2. Stopper as claimed in the preceding claim, characterized in that the tip of the extension (T22) which forms the end of the pierceable transverse wall (T26) is concave (T28) in order to retain any microdrop of blood which might form after withdrawal from the inner needle (15). 3. Stopper as claimed in the preceding claims, characterized in that it comprises: a base part (T12) suitable for penetrating into the sample tube (P10) and closing it, at least one recess (T20) in the base part (T12) which is preferably at the end so that sample tubes, a negative pressure can be built up when the base part of the stopper is partially inserted, a stopper flange (T14) which remains outside the sample tube, said tapered outer extension (T22) and said axial cavity (T24) which forms the pierceable transverse wall (T26) at the outermost end of the outer extension. 4. A sample tube for taking blood samples by means of vacuum suction, equipped with a pierceable stopper as claimed in the preceding claims, and suitable for use with a double needle sampling device having an outer needle for piercing the vein and an inner needle for insertion into said vacuum sample tube after piercing the stopper, such that the blood is transported from the vein into the sample tube solely by the effect of the vacuum prevailing in said sample tube.