RU2459638C2 - Sluice for injections - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medical equipment, namely to devices which are attached to the user's body for a certain period of time, and then the user may introduce drug preparations into the body by a sluice for injections. The sluice for injections comprises a base portion, a cannula, a gate and a fluid passage. The base portion is attached to the patient's skin when in use. The cannula is coupled with the base portion and introduced into the patient's body when in use. The gate comprises a needle-permeable partition through which the fluid can be injected into the sluice by the needle-based injection device. The gate is placed in the fixed position in relation to the base portion. In the fluid passage, the fluid injected through the gate is connected with the cannula. The sluice additionally comprises a locking mechanism. The locking mechanism has a first position wherein the needle can be introduced in the sluice and can be introduced in the cannula, as well as a second position wherein the needle of the needle-based injection device can be introduced in the sluice to make fluid injection into the patient's body through the cannula, however wherein said needle cannot contact the cannula. The gate is found in the same position in relation to the base portion when the locking mechanism is found in its first position and when the locking mechanism is found in its second position. A kit can additionally comprise said sluice for injections and the needle for introduction found in the cannula of the sluice. A method for using the sluice for injections involves placing the needle of the device for introduction through the cannula of the sluice for injections. The needle of the device for injection and the cannula are introduced subcutaneously. The sluice for injections is attached to the user's body. The needle of the device is removed. The locking mechanism is moved so that to avoid needle penetration into the cannula, and the fluid is injected from the needle-based injection device into the user's body through the sluice for injections without any additional travel of the locking mechanism.

EFFECT: invention allows using standard injection needles with no risk to pierce the cannula or to introduce the needle too deeply into the user's body.

26 cl, 14 dwg

Description

The present invention relates to a gateway for injection, containing a base part, which during use is attached to the patient’s skin, a cannula that is connected to the base part and which is inserted into the patient’s body during use, a valve through which fluid is introduced into the gateway by means of an injection device on the basis of a needle, wherein said shutter is located in a fixed position with respect to the base part, as well as a fluid passage in which a fluid introduced through the shutter communicates with the cannula.

An injection gateway is a device that is attached to the user for a certain period of time, for example, for three days. The user can then inject drugs into his body through an injection gateway. The gateway thus replaces multiple injections with syringes or pencil-type syringes. This injures the patient’s skin less, and the infection does not get to the injection site. In addition, for people who are afraid of injections, it is much easier to use an injection gateway than directly injecting yourself.

Description of the Related Art

Many different types of injection gateways are known. In certain injection gateways, after the gateway is attached to the user's skin, fluid is delivered to the gateway through an adapter attached to the gateway, see, for example, US Pat. No. 4,755,173, Publications WO 2004/101071, WO 02/053220 and US 2004/0158207 . However, these devices require the use of a special adapter and are usually connected to the infusion pump via a hose. They are unsuitable for use with a needle-based injection device, such as an ordinary syringe. In addition, in many cases, in order to be able to work with the infusion pump hose, the mechanisms of the injection gateways become quite complex, having complex flow lines inside the device, which leads to an increased risk of leaks in the device and / or an increase in the cost of the device due to complex seals , which must be included in the device.

Other types of gateways are designed to be used in conjunction with a special pencil-type injector; see, for example, Applicant's disclosure WO 2006/097111. In its most general form, the gateway is designed so that a pencil-type injector needle punctures the gateway wall so that fluid can be introduced through the wall into the user's body via a cannula inserted into the user's body. However, devices of this kind require the use of a special pencil-type injector device, since the needle of the injector device should not be in contact with the cannula. If the needle is in contact with the cannula, there is a risk that the needle will pierce the side of the cannula or scrape small plastic particles that can enter the user's body from the cannula. In addition, it is preferable to use short needles, as the risk of the user accidentally inserting them into the skin too deep is reduced. If the user uses an ordinary syringe with well-known gateways, then he exposes himself to the above risks.

SUMMARY OF THE INVENTION

A first aspect of the present invention is to provide a gateway that a patient could easily position and use for self-administration of active drugs and other drugs.

A second aspect of the present invention is to provide a gateway, where the gateway after being placed on the skin of the patient would be as less noticeable to the patient when the patient does not directly administer the drug.

A third aspect of the present invention is to provide a gateway that allows the user, without endangering, to use an ordinary injection syringe without the risks that are usually associated with this.

A fourth aspect of the present invention is to provide a gateway that will allow the user to use an ordinary syringe without endangering it while not allowing the user to insert the needle too deep into his body.

A fifth aspect of the present invention is to provide a gateway that prevents the user from damaging the cannula with a needle inserted into the gateway after the gateway is attached to the skin of the user.

A sixth aspect of the present invention is to provide a gateway that is simple and inexpensive.

The injection gateway in accordance with the present invention, according to the claims, satisfies these aspects by providing the injection gateway mentioned in the introductory section, which further comprises a closing mechanism having a first position in which the needle can be inserted into the gateway and can be inserted into the cannula, and the second position, in which the needle of the needle-based injection device can be inserted into the gateway for injecting fluid into the patient through the cannula, but the needle cannot be in contact with the cannula. By providing such a closing mechanism, the user is prevented from inserting the needle into the cannula or by inserting the needle too deep into his body. The gateway of the present invention thus reduces the risks that are typically associated with the use of a conventional needle-based injection device.

In one embodiment of such an injection gateway, the gateway may be configured such that in the first position of the closure mechanism, the needle inserted into the gateway and the cannula passes through the shutter. The gateway can also be made in such a way that, in the second position of the closing mechanism, the needle inserted through the shutter is prevented from coming into contact with the cannula. Moreover, the shutter is located in the same position with respect to the base part when the closing mechanism is in its first position and when the closing mechanism is in its second position. Thus, the shutter is an access point for various needles, and through it provides a seal between the environment outside the gateway and the user's body inside the gateway. In a typical embodiment, the shutter may comprise a punctured membrane (septum).

In one embodiment, the fluid passage may be configured to establish fluid communication between the two chambers. Two chambers can be made so that the axis of the cannula passes through the first of the two chambers, but not through the second of the two chambers. In addition, the chambers can be designed so that the needles inserted into the lock when the closing mechanism is in the first position are inserted into the first chamber, and the needles inserted into the lock when the closing mechanism is in the second position are inserted into the second chamber. Thus, the needles inserted into the airlock come into contact with two uniquely defined cameras.

In another embodiment, the closure mechanism may include a cover member having an access port through which the needle can be inserted into the gateway and which is movably connected to the base portion.

The covering element, in addition, can be made so that in the first position of the closing mechanism its access port is located along the axis of the cannula so that the needle of the insertion device can be inserted through the access port and enter the cannula. This position is effective in the process of introducing the cannula into the skin of the user through the needle of the insertion tool, which is located inside the cannula.

In addition, the covering element can be made so that in the second position of the closing mechanism, the access port is not aligned with the axis of the cannula. Thus, an obstacle is created for the needle inserted into the gateway through the access port to come into contact with the cannula.

The covering element can be connected to the base part with the possibility of rotation around the axis. In this case, the access port in the covering element and the cannula can be placed with an offset relative to the rotational axis of the covering element. Thus, by turning the cover member, the access port can be moved from a position in which it is aligned with the axis of the cannula, to a position in which it is not aligned with the axis of the cannula.

Alternatively, or simultaneously with this, the covering element can be connected to the base part so that it can move along a certain path.

In certain embodiments, the closure mechanism may comprise a closure mechanism by which the closure mechanism can be locked in a second position. This ensures that the gateway is used only once. In other words, the gateway cannot be removed from the user's body and once again applied. The user will need to use a new gateway.

In one embodiment, the locking mechanism may comprise a ratchet mechanism. In another embodiment, the locking mechanism may comprise a protruding member with elastic displacement that engages with a corresponding recess when the closing mechanism is placed in a second position of the closing mechanism. In one embodiment, the protruding element is located on the covering element, and the recess is located on the base part. You can imagine the opposite case. Such mechanisms are simple and reliable.

In one embodiment, the cover element may be positioned so as to align with the base element in a second position of the closure mechanism, but not align with the base element in the first position of the closure mechanism. Thus, the user receives a clear visual signal that the device is “safe” or “dangerous”. This allows the user to avoid using the device in its “dangerous” state.

 The closing mechanism may also comprise a blocking element, which in the first position of the closing mechanism is offset from the axis of the cannula, and in the second position of the closing mechanism is moved to the axis of the cannula in order to block the entrance to the cannula.

The blocking element can be biased by an elastic mechanism in the direction of the position in which it covers the opening of the cannula. In such an embodiment, it is possible to avoid covering the cannula opening with the blocking element in the first position of the closure mechanism in that it is held by the needle of the insertion tool. The blocking element, however, can be displaced not only by the elastic mechanism, but also, for example, under the influence of gravity.

In one embodiment, the blocking element may be a ball that is released when the needle of the insertion device is removed and rolled into the opening of the cannula to block the entrance to the cannula.

In another embodiment, the blocking element may be moved by virtue of a drive element responsive to heat and / or humidity when the gateway is removed from the package and secured to the user. This allows you to get a closing mechanism, which is to some extent “automatic” and ensures that the gateway is brought to its safe state without user intervention.

You can further imagine that the gateway described above can be part of a kit that contains an injection gateway and an injection tool needle, which is already installed in the gateway cannula. The kit may further comprise an insertion tool to allow a user to easily insert a cannula into his body.

Such a kit may also include a lid that covers the gateway at a time when the gateway is mounted on the user, but is not actively used as a gateway for injection.

The gateway of the kind described above can be used according to a method that includes the steps of placing the needle of the injection device through the cannula of the injection gateway, inserting the needle of the injection tool and cannula under the skin of the user, securing the injection gateway to the user, removing the needle of the injection tool, moving the locking mechanism so as to avoid access of the needle into the cannula, as well as injection of fluid from the needle-based injection device to the user through the injection gateway without additional movement beyond covering mechanism.

With one such method, the step of moving the closure mechanism can be carried out automatically after removing the needle of the injection tool from the injection gateway.

In another embodiment of such a method, the step of moving the closure mechanism may comprise the step of the user turning the cover element relative to the base element of the gateway.

It should be noted that the term "contains / containing" when used in the present description is used to determine the presence of the claimed features, certain whole parts, steps or components, but does not exclude the presence or addition of one or more features, certain whole parts, steps, components parts or their groups. For example, the description shows a closing mechanism having two positions. However, it should be clear to a person skilled in the art that the closing mechanism may have more than two positions, even if only two positions are explicitly mentioned in the claims and in the description.

Brief Description of the Drawings

The invention is further described in more detail with reference to the embodiments shown in the accompanying drawings. It should be noted that the shown embodiments are used only as examples and should not be used to limit the scope of the invention.

Figure 1 shows a cross-sectional view of a first embodiment of an injection gateway installed in an injector device that comprises an injector needle.

Figure 2 shows a cross-sectional view of a first embodiment of an injection gateway fixed to a user's skin, where the closing mechanism is in its first position.

Figure 3 shows a cross-sectional view of a first embodiment of an injection gateway fixed to the skin of a user, where the closing mechanism is in its second position.

Figure 4 shows a perspective view of a first embodiment of an injection gateway, where the closing mechanism is in its first position.

5 is a perspective view of a first embodiment of an injection gateway, where the closing mechanism is in its second position.

Figure 6 shows a perspective sectional view of a first embodiment of an injection gateway, where the closing mechanism is in its first position. The partition is removed in Fig.6 so that you can more clearly see the internal details.

7 shows a perspective sectional view of a first embodiment of an injection gateway, where the closing mechanism is in its second position. The partition is removed in Fig.7 so that you can more clearly see the internal details.

FIG. 8 is a schematic sectional view of a second embodiment of an injection gateway, where the closing mechanism is in its first position.

Figure 9 shows a schematic sectional view of a second embodiment of an injection gateway, where the closing mechanism is in its second position.

Figure 10 shows a schematic sectional view of a third embodiment of an injection gateway, where the closing mechanism is in its first position.

11 shows a schematic sectional view of a third embodiment of an injection gateway, where the closing mechanism is in its second position.

12 is a schematic perspective sectional view of a fourth embodiment of an injection gateway, where the closing mechanism is in its first position.

13 is a schematic perspective sectional view of a fourth embodiment of an injection gateway, where the closing mechanism is in its second position.

FIGS. 14a-14d show a different approach to minimizing the risks associated with using a conventional needle-based injection device in universally accessible injection gateways.

Detailed Description of Embodiments

Figures 1-7 show various views of a first embodiment 1 of an injection gateway according to the invention. The gateway 1 contains a base part 2, which is attached to the skin 3 of the user by means of an adhesive layer 4 attached to the bottom of the base part 2.

The covering element 5 is connected to the base part 2 with the possibility of rotation around axis A. The covering element 5 has an access port 6 through which the needle can be inserted so that the needle can access the inside of the gateway. The access port 6 is located with an offset relative to the axis A. Thus, when the cover is rotated around the axis, the access port 6 simultaneously rotates and moves along a circular path.

The base element 2 contains a cannula 7, which is inserted into the body of the user when the gateway is in operation. Thus, the cannula is in fluid communication with the inside of the user's body during operation. In the present embodiment, the cannula is made of soft plastic material, as is well known to a person skilled in the art. A soft plastic cannula can remain in the user's body without causing user discomfort.

The cannula 7 is connected to the base part 2 via a sleeve 8. The sleeve is usually made of plastic, which fuses the base part and the cannula with each other. In some cases, however, one can imagine that the sleeve is made of metal. This will avoid damaging the gateway with a needle. In other cases, the cannula can be fused directly into the base, thereby eliminating the need for a sleeve.

The base part further comprises two chambers 9, 10. The first chamber 9 is in direct fluid communication with the cannula 7 and is positioned so that the axis of the cannula passes through the first chamber 9. This allows the needle 11 of the insertion tool to be inserted through the cannula during insertion cannulas into the user's body, go through the first camera. The second chamber 10 is located offset from the axis of the cannula. However, the second chamber 10 is in fluid communication with the cannula through the fluid passage 12. Thus, the fluid introduced into the second chamber reaches the cannula and, for this reason, also enters the user's body. It should be noted that in the present embodiment, a fluid passage is installed between the first chamber and the second chamber, however, it can be imagined that the second chamber can also be directly connected to the cannula.

The base part 2 also contains a shutter 13 in the form of a punctible septum. The function of the shutter 13 is to allow the needle to pass through the septum for injecting fluid into the lock, but to prevent bacteria and other unwanted objects from entering the lock. The use of a shutter such as a partition for this purpose is well known to a person skilled in the art and will not be discussed further.

As can be seen in the figures, two chambers 9, 10 are also located with an offset relative to the axis of rotation of the covering element. In the present embodiment, these two chambers are located separately at an angle of 180 degrees relative to the axis of rotation of the covering element. In addition, these two cameras are located with an offset from the axis of rotation A by the same distance as the access port on the covering element. Thus, when the cover is rotated around axis A, the access port 6 can provide access to the needle either in the first chamber 9 (Figs. 1,2,4 and 6), or in the second chamber 10 (Figs. 3,5 and 7). Thus, the covering element operates as a type of closing mechanism having at least two positions. In one position (first position), the access port is on the same line with the first camera, and in another position (second position), the access port is on the same line with the second camera. When the cover element is in the first position, the needle can be inserted through the access port, through the septum, through the first chamber and through the cannula. This position is used in the process of introducing the device. One can imagine that the gateway is delivered to the user with the covering element in the first position and with the needle of the insertion tool that has already been inserted through the cannula. Thus, the user does not risk damaging the cannula by self-inserting the needle of the insertion tool into the gateway.

When the gateway is fixed to the user and the cannula is inserted into the body of the user, then the inserted needle can be removed and the cover element is rotated to the second position. In the second position, the needle can be inserted through the access port in the lid, through the partition into the second chamber 10. However, the needle cannot enter the cannula. The user can thus use a conventional needle-based injection device without exposing himself to the risks that are usually associated with this.

1 shows a gateway 1 connected to an “insertion device” 14. The insertion devices are well known to one skilled in the art and may take various forms. The insertion device 14 is usually used so that the gateway is loaded into the insertion device, the device is prepared for operation and is located above the injection site on the user's body. Then the device is unlocked and the gateway is inserted into the user's body. This allows the implementation process to be simple and comfortable enough for the user. After the gateway is fixed to the user's body, the insertion device together with the needle of the insertion tool can be removed.

It should also be mentioned that the cover element is provided with an elastically displaceable hook, which is fixed in the groove in the base element when the cover element is rotated to the second position. Thus, the hook locks the covering element, eliminating additional rotation. This provides only a one-time use of the device with a needle tool for insertion. After the cover element is rotated to the second position, the cover element is fixed, and the needles inserted into the device will not come into contact with the cannula.

It should also be mentioned that the first embodiment comprises an outer covering element that is located on the outside of the base portion. However, in another embodiment (not shown), the covering element may be located inside the base portion. In this case, the covering element can be moved by means of a drive element, to which the user has access through an opening in the base part. For example, a cover member may be attached to a protrusion that is located in a groove in the base portion. Thus, the user can move the covering element by moving the protrusion into the groove.

Figures 4 and 5 show a gateway in perspective from the upper side of the device. As you can see, the shape of the covering element 5 is not round, but resembles a triangle. The base part repeats the same form. Thus, when turning the covering element, there will be no position in which the contour of the covering element and the contour of the base element coincide. In other positions of the covering element, the user can see that the covering element and the base element are not aligned. This gives the user a visual signal that the device is in a “safe position”. One skilled in the art will appreciate that this feature can be provided by many other forms.

With respect to the first embodiment 1, it can also be mentioned that the covering element is rotatable about an axis, however, the covering element can also be arranged to move along a certain path. For example, the user can slide the cover by a short distance between the first position and the second position. In addition, a combination of rotation and shear is also possible.

On Fig and 9 shows a second embodiment 20 of the gateway according to the invention. In this embodiment, the gateway comprises a base member 21, a septum 22, and a cannula 23 attached to the base portion. In addition, the lock comprises a locking element 24 that is displaced in the direction of the opening 25 of the cannula by the spring 26. The lock is delivered to the user with an insertion needle 27 located in the cannula 23. The locking element 24 is pressed against the insertion needle 27 of the spring 26. When the introduction is removed after securing the gateway to the skin of the user, the blocking element 24 is spring-loaded forward and blocks the entrance to the cannula. Thus, the needle inserted through the septum after removing the needle of the insertion tool will not have access to the cannula. However, fluid injected into the airlock through an injection needle will be able to bypass the blocking element and enter the cannula. On Fig shows the gateway as it is delivered to the user, and Fig.9 shows the gateway after removing the needle of the insertion tool.

One skilled in the art will appreciate that the locking element and spring can be made in various ways. The spring element, for example, may be a plastic beam, bent from the opening of the cannula using a needle tool for insertion. A person skilled in the art of mechanical elements will be able to develop many different blocking elements that will have the same effect as in the embodiment shown in the figures.

10 and 11 show a third embodiment 30 of a gateway according to the invention. This embodiment 30 also includes a base member 31, a cannula 32 attached to the base member, a septum 33, and a blocking member 34. The blocking member is connected to the base member via a drive member 35. The drive member is made of material that increases in volume when exposed to moisture and heat. When the gateway is in its sterile packaging, it is protected from moisture and can be stored in the cold. As soon as the package is opened and the gateway is fixed to the user, the material is exposed to moisture and heat and begins to increase in volume, which causes the blocking element to move forward and cover the cannula opening.

Figure 10 shows the needle 36 of the insertion tool inserted into the device. 11 shows a gateway when it is attached to the skin of a user.

12 and 13 show a fourth embodiment 40 of a gateway according to the invention. In this embodiment, the gateway also comprises a base member 41, a cannula 42, a septum (not shown), and a blocking member 43. In this case, the blocking member is a small ball 43 that is held in place by the insertion needle 44. When the needle of the insertion tool is removed, the ball rolls into the cannula opening and thereby blocks access to the cannula opening. It should be noted that in the second position of the ball, fluid may pass by the ball.

It should be noted that in the above embodiments, a single partition was used as a shutter. In other words, both the injection needle and the injection needle were inserted through the same septum. However, the shutter may contain many different areas. For example, you can imagine two separate partitions, one for the needle port of the insertion tool, and the second for the injection needle port.

On figa-14d shows an embodiment of a system that can also be used to minimize the risks associated with the use of needle-based injection devices. The figures show an injection gateway 50 that includes a base portion 51, a cannula 52 and a septum 53. Figure 14a shows a needle 54 of an insertion tool inserted into the gateway. The gateway 50, as shown in FIG. 14a, is ready to be secured to the user. Once the gateway is fixed to the user, the needle of the insertion tool is removed.

14b shows the needle 55 of a typical needle-based injection device. Before use, the user attaches the wedge-shaped blocking element 56 to the end of the needle 55. Then, the user inserts the needle 55 and the wedge-shaped blocking element 56 through the septum, as shown in figs. Thanks to the wedge-shaped blocking member 56, the cannula is not damaged by the needle 55, and the penetration of the needle 55 into the user is also prevented. When the user removes the needle 55 from the septum, the wedge-shaped blocking element 56 remains in the gateway. This is shown in fig.14d. The next time the user uses the gateway, the blocking device 56 will still remain in the device, ready to block the needle. It should be noted that liquid may flow around the blocking element, or, as shown in the figures, a passage 57 may be formed in the blocking element 56.

In the above embodiments, the cannula was a soft plastic cannula. However, in certain cases, one can imagine that the cannula is a thin needle made of metal. This reduces the risk of damage to the cannula by injection needles, but may be somewhat less comfortable for the user. However, a metal cannula can be inserted into the user's body, the needle of the insertion tool is not required.

It should be noted that in the figures and in the above description, examples of embodiments are presented in a simple and schematic form. The internal parts were not shown in great detail, as one skilled in the art would have to be familiar with such details, and they would only unnecessarily complicate the present description.

It should also be mentioned that in the present description presents a number of independent inventions that can form part of the selected applications. For example, a metal sleeve located between the cannula and the base can be used in many other locks in order to avoid damage to the cannula by the injection needle. Another example is a cannula made of metal. This embodiment can be used in gateways of other types than those claimed in the present invention.

In addition, the embodiments shown herein should not be used unnecessarily to limit the scope of the invention. There are other embodiments of injection gateways that fall within the scope of the present claims. For example, in the embodiments described above, a sluice is provided everywhere in which the needle of the insertion tool punctures the septum. However, one can imagine that the gateway has an open port for the needle of the insertion tool, which is closed and sealed by the closing mechanism in the second position of the closing mechanism. For example, the cover member may be equipped with a seal and a bore. When the gateway is in the “insertion state”, the opening in the lid is located above the opening of the cannula. When the gateway enters the “user-operated state”, the cover element is moved so that the hole moves to the septum used for injection by a standard needle-based injection device and the seal on the lid moves to the cannula opening, thereby preventing access to the cannula. In addition, the seal prevents unwanted bacteria and / or other unwanted objects from entering the airlock. A person skilled in the art should be able to determine the scope of the claims of the present claims using their knowledge and the present description.

Claims (26)

1. Gateway (1; 20; 30; 40) for injection, containing:
- the base part (2; 21; 31; 41), which is used on the patient’s skin during use (3),
- cannula (7; 23; 32; 42), which is connected to the base part and which is inserted into the patient’s body during use,
a shutter (13; 22; 33) comprising a punctured septum through which liquid can be injected into the airlock via a needle-based injection device, said shutter being in a fixed position with respect to said base part, and
- a passage (12) for the liquid, in which the liquid injected through the valve communicates with the cannula,
characterized in that the injection gateway further comprises a closure mechanism (5; 24, 26; 34, 35; 43), said closure mechanism having a first position in which a needle (11; 27; 36; 44) can be inserted into the gateway and can be inserted into the cannula, as well as a second position in which the needle of the needle-based insertion device can be inserted into the airlock in order to inject liquid into the patient through the cannula, but in which said needle cannot come into contact with the cannula, and also that the shutter is located in the same position on to the base part when the closing mechanism is in its first position and when the closing mechanism is in its second position. 2. The gateway (1; 20; 30; 40) for injection according to claim 1, characterized in that the gateway is located in such a way that in the first position of the closing mechanism (5; 24; 26; 34; 35; 43) the needle (11 ; 27; 36; 44), introduced into the gateway and into the cannula (7; 23; 32; 42), passes through the shutter (13; 22; 33). 3. Gateway (1; 20; 30; 40) for injection according to claim 1 or 2, characterized in that the gateway is located in such a way that the needle is in the second position of the closing mechanism (5; 24, 26; 34, 35; 43) inserted through the shutter (13; 22; 33) cannot come into contact with the cannula (7; 23; 32; 42). 4. Gateway (1) for injection according to claim 1, characterized in that the passage (12) establishes a message between the two cameras (9, 10). 5. Gateway (1) for injection according to claim 4, characterized in that the two chambers (9, 10) are located so that the axis of the cannula (7) passes through the first (9) of the two chambers, but not through the second (10) from two chambers. 6. Gateway (1) for injection according to claim 4 or 5, characterized in that the needles (11) inserted into the gateway when the closing mechanism (5) is in its first position are inserted into the first chamber (9), and the fact that the needles inserted into the airlock, when the closing mechanism is in its second position, are inserted into the second chamber (10). 7. Gateway (1) for injection according to claim 1, characterized in that the closing mechanism (5) comprises a cover element (5), which has an access port (6) through which a needle (11) can be inserted into the gateway, said the covering element is movably connected to the base part (2). 8. Gateway (1) for injection according to claim 7, characterized in that the covering element (5) is located so that in the first position of the closing mechanism (5), the access port (6) is aligned with the cannula (7) so that the needle (11) of the insertion instrument could be inserted through the access port and into the cannula. 9. Gateway (1) for injection according to claim 7 or 8, characterized in that the covering element (5) is located so that in the second position of the closing mechanism (5) the access port (6) is not aligned with the cannula (7), so so that the needle inserted into the gateway through the access port cannot come into contact with the cannula. 10. Gateway (1) for injection according to claim 7 or 8, characterized in that the said covering element (5) is connected to the base part (2) with the possibility of rotation about axis (A). 11. Gateway (1) for injection according to claim 10, characterized in that the access port (6) in the covering element (5) and the cannula (7) are located with an offset relative to the axis of rotation (A) of the covering element. 12. Gateway (1) for injection according to claim 7 or 8, characterized in that the covering element (5) is connected to the base part (2) with the possibility of movement along the trajectory. 13. Gateway (1) for injection according to claim 1, characterized in that the closing mechanism (5) contains a locking mechanism by which the closing mechanism can be fixed in the second position. 14. Gateway (1) for injection according to item 13, wherein the locking mechanism comprises a ratchet mechanism. 15. Gateway (1) for injection according to item 13, wherein the locking mechanism comprises an elastically biased protruding element that engages with a corresponding recess when the closing mechanism (5) is placed in the second position of the closing mechanism. 16. Gateway (1) for injection according to claim 7, characterized in that the covering element (5) is located so that it is aligned with the base element (2) in the second position of the closing mechanism (5) and is not aligned with the base element in the first position of the closing mechanism. 17. Gateway (20; 40) for injection according to claim 1, characterized in that the closing mechanism (24, 26; 43) contains a blocking element (24; 43), which in the first position of the closing mechanism moves from the axis of the cannula (23; 42), and in the second position of the closing mechanism is moved to the axis of the cannula to block the entrance (25) to the cannula. 18. Gateway (20) for injection according to claim 17, characterized in that the blocking element (24) is elastically biased in the direction of the position in which it covers the opening (25) of the cannula. 19. Gateway (20; 40) for injection according to 17 or 18, characterized in that the blocking element (24; 43) cannot cover the opening (25) of the cannula (23; 42) in the first position of the closing mechanism, since it is held by a needle (27; 44) introduction tool. 20. An injection gateway (40) according to claim 17 or 18, characterized in that said blocking element is a ball (43) that is released when the needle (44) of the insertion tool is removed and which rolls into the cannula opening (42 ) to block the entrance to the cannula. 21. A kit containing a gateway (1; 20; 30; 40) for injection according to any one of claims 1 to 20 and a needle (11; 27; 36; 44) of an injection tool located in the cannula (7; 23; 32; 42) gateway. 22. The kit of claim 21, wherein said kit further comprises an insertion tool. 23. The kit according to item 21 or 22, in which said kit further comprises a cover that covers the gateway at a time when the gateway is mounted on the user, but is not actively used as a gateway for injection. 24. A method of using a gateway (1; 20; 30; 40) for injection, which contains the following steps: placing the needle (11; 27; 36; 44) of a tool for insertion through the cannula (7; 23; 32; 42) of the gateway for injection , inserting the needle of the insertion tool and cannula under the skin of the user, securing the injection gateway to the user, removing the needle of the insertion tool, moving the locking mechanism (5; 24, 26; 34, 35; 43) so as to prevent the needle from entering the cannula, and injecting fluid from a needle-based injection device to a user through an injection gateway without additional Nogo displacement of the closure mechanism. 25. The method of using a gateway (20; 30; 40) for injection according to paragraph 24, wherein the step of moving the closing mechanism (24, 26; 34, 35; 43) is carried out automatically after removing the needle (27; 36; 44 ) an injection instrument from the injection gateway. 26. The method of using the gateway (1) for injection according to paragraph 24, wherein the step of moving the closing mechanism (5) comprises the step of turning the user of the cover element (5) relative to the base element (2) of the gateway.

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