阅读说明：本技术 用于血管压迫的医疗装置 (Medical device for vascular compression ) 是由 马里乌什·克鲁克 于 2020-02-18 设计创作，主要内容包括：本发明涉及一种用于血管压迫的医疗装置,将该医疗装置施用于患者的肢体以便于实现局部止血。本发明的压迫装置配备有远离压迫区域的压迫控制机构,该压迫控制机构通过调节用于将装置附接至患者肢体的带的张力来控制该装置对患者肢体的压迫。该装置还包括稳定支承件,在施用于患者肢体时,该稳定支承件防止装置改变其位置。(The present invention relates to a medical device for vascular compression, which is applied to a limb of a patient in order to achieve local haemostasis. The compression device of the present invention is equipped with a compression control mechanism remote from the compression zone that controls the compression of the patient's limb by the device by adjusting the tension of a strap used to attach the device to the patient's limb. The device also includes a stabilizing support that prevents the device from changing its position when applied to a patient's limb.)

1. A vascular compression device for a limb, the vascular compression device comprising:

a hollow body (2), said hollow body (2) having a substantially annular inner surface and a longitudinal base (15), said substantially annular inner surface and said longitudinal base (15) defining a substantially tubular space (23) and being accessible through said tubular space (23);

a compression region (24), the compression region (24) being located at an outer surface of the base (26);

a compression control mechanism (3) for adjusting the compression applied by the device, wherein the mechanism is located on the body (2) at a position remote from and opposite the compression region (24) and the base (26),

a strap (4), the strap (4) for securing the device to the limb and effecting compression of the limb, the strap being attached to the body (2) at the base (26) and releasably attachable with the compression control mechanism (3) and adjustable by the compression control mechanism (3) without obstructing the tubular space (23);

a support (20), the support (20) for stabilizing the device, the support being positioned adjacent to the base (26) and extending in a longitudinal direction parallel to the base (26).

2. The device according to claim 1, wherein the longitudinal base (26) is a flat surface which partially forms the substantially annular inner surface of the body (2).

3. Device according to claim 1 or 2, wherein the compression control means (3) is a screw and nut mechanism.

4. The apparatus of claim 3, wherein the screw and nut mechanism comprises:

-an externally threaded element (21) in the form of a screw, the axis of rotation of the externally threaded element (21) being perpendicular to the pressing zone (24), the externally threaded element (21) being provided with a plurality of cut-off thread guide grooves (27) parallel to the axis of rotation of the externally threaded element (21),

-a knob (31) of nut-like form, said knob (31) being fitted in an engaging manner on said externally threaded element (21), and

-a tensioner (30), the tensioner (30) being positioned on the knob (31), wherein the tensioner (30) comprises a housing (300) and a knob bearing element (301) and a guiding element (302), the knob bearing element (301) and the guiding element (302) protruding from the housing (300) in the direction of the pressing region (14) and perpendicular to the pressing region (14), wherein the knob bearing element (301) and the guiding element (302) are received by the guiding groove (27) of the externally threaded element (21).

5. The device according to claim 4, wherein said externally threaded element (21) is provided with four guide grooves (27) symmetrically positioned on said externally threaded element (21) and said tensioner (30) is provided with two corresponding pairs of said knob supporting element (301) and said guide element (302), and wherein each pair of said knob supporting element (301) and said guide element (302) is received by a pair of guide grooves (27) positioned opposite each other.

6. Device according to any one of claims 1 to 5, wherein the support (20) is in the form of a curved fin having a wave-shaped cross section, the support (20) being provided with a foot (200) at a free end of the support (20), wherein only the foot (200) of the support (20) is in the same plane as the pressing area (24).

7. The device according to any one of claims 1 to 6, wherein the compression control mechanism (3) is configured to emit an audible click upon adjustment.

8. The device according to any one of claims 1 to 7, wherein the click generating device comprises:

-an annular spring (32), the annular spring (32) being fixed within the housing (300) of the tensioner (30) and the annular spring (32) having at least one protrusion (320) extending towards the knob (31), and

-cogs (310), the cogs (310) being evenly spaced along the rim of the knob (31) at a location close to the tensioner (30), such that upon rotation of the knob (31), the protrusion (320) engages with one of the cogs (310), thereby generating a click sound.

9. Device according to any one of claims 1 to 8, wherein the strip (4) is attached to the hollow body (2) at the pressing region (24) by means of an adhesive (5), wherein the attachment is made over the entire pressing region (24).

10. The device according to any one of claims 1 to 9, wherein the pressing area (24) and the foot (200) of the support (20) are provided with elastic inserts.

11. The device of any one of claims 1 to 10, wherein all components of the device are made of a transparent plastic material.

12. A method of achieving local hemostasis of a blood vessel at a limb of a patient while maintaining blood flow through other blood vessels in the vicinity of the bleeding blood vessel, the method comprising the steps of:

-applying a medical device (1) according to any of the preceding claims at a bleeding vascular site by manually pressing the compression area (24) of the body (2) against the bleeding vascular site,

-securing the device on the patient's limb by applying a strap (4) around the patient's limb and over the compression control mechanism (3) to effect compression of the patient's limb by the device, and

-adjusting the compression of the patient's limb by the device by altering the tension of the strap (4) by means of the compression control mechanism (3).

13. The method according to claim 12, wherein the tension of the belt (4) is modified when the knob (31) of the compression control mechanism (3) is turned and the knob (31) of the compression control mechanism (3) is moved away from or towards the compression area (24).

14. The method according to claim 13, wherein the compression of the patient limb by the device increases as the knob (31) moves away from the compression region (24) and the tension of the strap (4) increases.

15. The method according to claim 13, wherein the compression of the patient limb by the device is reduced as the knob (31) is moved towards the compression region (24) and the tension of the strap (4) is reduced.

16. A method according to any one of claims 12 to 15, wherein the blood vessel is a radial artery from which a catheter or cannula is being removed.

17. The method of any one of claims 12 to 15, wherein the blood vessel is an ulnar artery from which a catheter or cannula is being removed.

Technical Field

The present disclosure relates to medical devices for vascular compression that are applied to a limb of a patient in order to achieve local hemostasis. In particular, the devices of the present disclosure are used in invasive cardiology and radiology to compress blood vessels when removing a vascular sheath from a patient's blood vessel after cardiac catheterization, coronary angiography, or other endovascular procedures and interventions requiring a vascular access port.

Background

Many different vascular compression devices are known in the art. For example, WO2013060883 discloses an arterial compression band having: a tubular shaped body having a beveled end, and a retaining element in the form of a band attached to an outer surface of the body. The medical device is applied at the site of a bleeding blood vessel, in particular at the site of a bleeding artery (radial or ulnar artery) from which a catheter or cannula has been removed, by: the body is secured on the patient's limb by manually pressing the body against the bleeding vascular site and then applying a retaining element around the patient's limb. The device is secured to the patient's limb by fastening means, such as hook and loop fasteners which may be located on the retaining element. The device disclosed therein is very easy to manufacture and apply to a patient's limb. Most importantly, the disclosed device provides manual control of vascular compression when the device is placed on a patient's limb, i.e. a medical professional (e.g. a doctor or nurse) can apply the body to the site where the catheter or cannula enters the blood vessel while gripping on the interior of the hollow body, remove the catheter or cannula while applying the necessary compression to the blood vessel, and secure the body to the patient's limb by applying the band around the patient's limb and over the body of the device while still maintaining the interior of the hollow body.

However, once applied to a patient's limb, the device is prone to accidental displacement, either by tipping or by shifting or sliding. This may affect the compression force exerted on the blood vessel after the device is applied or may even affect the compression application site on the limb, thereby reducing the effectiveness of the device at the primary use. Furthermore, the device does not provide sufficient control of the level of compression after the device is secured to the patient's limb, especially when it is desired to gradually reduce the compression requirement after the device is placed on the patient. The compression is controlled only by the band positioning or by adjusting the cross-sectional size or shape of the body. However, in the first case, the adjustment of the band is required, which is very inconvenient and requires the medical staff to unfasten the holding device and re-secure it in a new position, risking the displacement of the device which may lead to bleeding. In the latter case, the construction of the body becomes very complex and the level of pressure regulation is also very limited.

To ensure adequate compression control in a compression hemostasis device, a screw and nut system may be used to apply pressure to the patient's limb. In US20100280541, a radial artery compression device is disclosed that includes a rotatable member and a compression pad that is adjusted in a manner such that rotation of the rotatable member does not affect the rotational orientation of the compression pad. Rotation of the rotatable member causes deployment or retraction of the compression pad relative to the body of the radial artery compression device, thereby increasing or decreasing, respectively, compression on the radial artery of the patient. Thus, in such devices, the screw and nut system directly drives the compression pad, thereby achieving precise compression control. A similar arrangement is described in US 20120191127. However, in this case, the screw and nut system may also be located outside the diameter of the compression pad, which is attached to the base of the device. In this case, the level of compression is controlled by the deflection of the entire base.

Although the above devices provide more precise control of the level of compression, these devices are not easily applied. These devices do not provide manual control when applied as the devices described in WO 2013060883. Even if the rotatable member is provided with a recess that can receive the finger or thumb of a medical professional controlling the pressure of the device when positioning the device on the limb of the patient, the recess is not very convenient for gripping, as it is only accessible from the top of the rotatable member. Furthermore, although the recess is provided with a transparent floor, the view of the catheter or cannula entry site is still significantly obstructed by the screw and nut system elements. Finally, in both devices of US20100280541 and US20120191127, the holding device or base is in direct contact with the radial side of the forearm of the patient. This design not only causes discomfort to the patient when the device is applied, but also affects blood flow in adjacent vessels, particularly the arm veins or the ulnar artery, as some pressure is inadvertently applied through the body and the band. A means for compression of a selected vessel, such as a means for more accurate compression in which the radial artery is compressed while maintaining blood flow in adjacent vessels, would be useful but not obvious from the prior art.

It is stated that there is still a need for a device that can be securely held in place on a limb and provide specific and accurate vascular compression. Furthermore, it would be advantageous if the device could accurately control compression without affecting the simplicity of its construction or ergonomic design.

Disclosure of Invention

The present invention provides a vascular compression device for a limb, the vascular compression device comprising: -a hollow body having a substantially annular inner surface and a longitudinal base defining a substantially tubular space and being accessible through the substantially tubular space;

-a compression region located at an outer surface of the base;

-a compression control mechanism for adjusting the compression applied by the device, wherein the mechanism is located on the body at a position remote from and opposite to the compression region and the base;

a strap for securing the device to the limb and effecting compression of the limb, the strap being attached to the body at the base and being releasably attachable with and adjustable by the compression control mechanism without obstructing the tubular space;

-a support for stabilizing the device, the support being positioned adjacent to the base and extending in a longitudinal direction parallel to the base.

When applied to a wounded blood vessel, embodiments of the medical devices disclosed herein provide vascular compression, particularly radial compression, for the purpose of establishing hemostasis. The vascular compression device of the present invention is ergonomically designed so that it is easily attached to a patient's limb and is convenient for medical personnel to use. When the device of the present invention is applied to a patient's limb, the device is stable (i.e., does not easily slide or tilt) and provides adequate compression control. The device of the present invention also provides greater comfort to the patient because the compression of the radial side of the forearm of the patient is substantially limited to the entry of the catheter or cannula into the vascular site. The design of the device of the present invention also prevents compression of blood vessels other than those with vascular access ports. The device of the present invention is configured such that the components of the device are easily manufactured by injection molding. The inventors considered the shape of the injection molds while designing the device to ensure that these injection molds have a simple configuration and that the elements produced by injection molding can be easily taken out of the molds.

In a preferred embodiment, the compression control mechanism of the device of the present invention is based on a screw-nut system. Also preferably, when the device is applied on a limb of a patient, the strap-which in embodiments is attached to the hollow body in the vicinity of the compression region (i.e. on the opposite side of the hollow body with respect to the compression control mechanism) -is passed over the compression control mechanism, being guided from one side of the compression control mechanism to the other, which compression control mechanism adjusts the compression of the device by adjusting the tension of the strap.

Also in this embodiment, the hollow body has a cylindrical shape with a chamfered end. More preferably, the tubular space inside the hollow body is formed by a through hole. In this embodiment, i.e. as long as the tubular space inside the hollow body is accessible from both sides, the vascular compression device according to the invention can be used on both forearms of a patient and for compressing different blood vessels.

In an embodiment of the invention, the compression control mechanism comprises a knob and a tensioner, wherein the knob is fitted on an externally threaded element of the hollow body, which is located on the opposite side of the hollow body with respect to the compression area, and the knob supports the tensioner. When the device of the present invention is attached to a patient's limb and the knob is turned, the knob moves along the externally threaded element of the hollow body and changes the vertical position of the tensioner. The tensioner does not rotate in the horizontal direction when it is moved in the vertical position, thereby providing support for the belt. As the knob and tensioner move away from the middle of the hollow body (i.e., away from the compression zone), the tensioner compresses and increases the tension of the strap, thereby increasing the compression of the device on the patient's limb. When the knob is turned in the opposite direction, it moves along the externally threaded element of the hollow body towards the middle of the hollow body (i.e. towards the pressing area). The tensioner follows the movement of the knob, thereby reducing the tension of the belt and the compression of the hollow body on the patient's limb.

The compression control mechanism that adjusts the tension of the strap enables precise control of the compression of the device on the patient's limb. In addition, due to the fact that the band is guided around the hollow body, it does not press the radial sides of the forearm of the patient, eliminating the pressing of other blood vessels, and at the same time it does not block the access to the tubular space of the hollow body, so as to achieve a comfortable grip of the device of the invention by pressing the pressing area of the hollow body with the fingers or thumb of the medical staff received in said tubular space of the hollow body. The hollow body, the compression control mechanism, and the band are preferably made of a transparent material and do not obstruct the view of the vascular compression region. This enables visual control of the catheter or cannula into the vascular site as or after the catheter or cannula is removed. Thus, it can be determined whether hemostasis is achieved or bleeding from the injured blood vessel can be detected.

In a preferred embodiment, the stabilizing support protrudes from the hollow body at a pressing region proximate to the hollow body. In addition, in a preferred embodiment, the support for stabilising the body is in the form of a curved fin, the edge of which opposite to the edge attached to the hollow body is in the same plane as the pressing region of the hollow body, thereby providing support for the hollow body, while the remainder of the support is raised above the plane of the pressing region. This shape of the stabilizing support minimizes contact of the device of the present invention with the patient's limb, thereby increasing patient comfort and reducing compression of the device on areas of the patient's limb other than the site of the punctured blood vessel. In this way, compression on vessels other than the one providing the vascular access point is minimized. Thus, the device of the present invention is designed to provide precise compression control of a selected blood vessel while maintaining blood flow in adjacent blood vessels unaffected.

If the device is used to compress the radial artery, the ulnar artery will not be compressed because the stabilizing support is raised above the surface of the patient's forearm area corresponding to the location of the ulnar artery. Thus, if the device is used to compress the ulnar artery (i.e., the device is applied to the limb in the opposite direction), the radial artery is not compressed. Most importantly, due to the design of the device, particularly the design of the stabilizing support, which is limited in contact with the patient's limb, the device does not compress the adjacent vein. Thus, veins flowing from the hands are not obstructed by compression of the device against the patient's limb and vein stasis is avoided. This not only increases patient comfort, but also reduces the risk of side effects associated with catheterization and limb compression.

The entire device of the invention has the required stability even if only the edge of the stabilizing support opposite the edge connected to the hollow body is in contact with the forearm of the patient. The stabilizing support prevents the device of the present invention from shifting due to toppling or slipping while attached to the patient's limb. In a most preferred embodiment, the stabilizing support is in the form of a curved fin having a wave-shaped cross-section, wherein the edge of the support opposite to the edge connected to the hollow body is provided with a support foot. The support foot increases patient comfort when the device of the present invention is attached to a patient's limb.

In a preferred embodiment, the belt of the device of the invention is made of a non-slip material. Preferably, the strap is made of a material that does not require additional fastening means to hold the device of the present invention on the limb of the patient. In particular, when the band is secured around a patient's limb, one surface of the band, the outer surface, is adhered to the opposite surface of the band, the inner surface, and the outer and inner surfaces of the band are in contact. In an alternative embodiment, the strap may be provided with additional fastening means, with additional fastening meansAdditional securing means for holding the device in a desired position on the limb of the patient, the additional securing means selected from the group consisting of: adhesive (e.g., in the form of a locking sticker), tightening buckles, hooks, snap fasteners (e.g., apertures and corresponding lugs), or hook and loop fasteners, such asIn some preferred embodiments, the fastening means comprises two parts on opposite surfaces of the strap, which parts come into contact when the device of the invention is attached to a limb of a patient. In a preferred embodiment, the fastening means are provided at the free end of the strap, i.e. at the end of the strap opposite to the end of the strap connected to the base of the hollow body.

In various embodiments, the device of the present invention is equipped with a snap-in mechanism that indicates rotation of the knob on the externally threaded element. This allows for acoustic control of the compression adjustment. The snap mechanism according to a preferred embodiment comprises an annular spring fixed within the tensioner, wherein the annular spring comprises a downward projection that engages with evenly spaced cogs located near the edge of the knob closest to the tensioner. In this way, each time the knob is turned, the protrusions of the annular spring are displaced from one space between the cogs to another, wherein upon displacement the protrusions engage with the cogs and produce a clicking sound. A system consisting of a ring spring with a protrusion that engages an element on the knob has a higher space utilization. Therefore, the snap-in function of the device of the present invention can be introduced without increasing the size of the entire device of the present invention. Furthermore, the design of the snap-in mechanism makes its manufacturing method very simple, since the snap-in mechanism does not require any complicated injection molding forms.

Drawings

The invention will be described in more detail hereinafter with reference to the accompanying drawings, in which:

FIG. 1a presents a perspective view of a vascular compression device in a folded form in accordance with a preferred embodiment of the present invention;

FIG. 1b is a side view showing the device shown in FIG. 1a in expanded form;

fig. 2a presents an exploded view of the vascular compression device of the present invention according to fig. 1a and 1 b;

fig. 2B and 2c present an enlarged part of the exploded view a and the exploded view B, respectively, according to fig. 2 a;

fig. 3 presents the hollow body of the vascular compression device of the present invention in a perspective view (fig. 3a), a front view (fig. 3b), a side view (fig. 3c) and a bottom view (fig. 3 d);

fig. 4 presents a tensioner of a vascular compression device of the present invention in a perspective view from the bottom (fig. 4a), a bottom view with a ring spring (fig. 4b), a top view (fig. 4c) and side views (fig. 4d and 4 e);

FIG. 5 presents the knob of the compression device of the present invention in a perspective view from the bottom (FIG. 4a) and from the top (FIG. 5b), a top view (FIG. 5c), and a cross-sectional view (FIG. 5d) taken along the line A-A of the knob presented in FIG. 5 c;

FIG. 6 presents a perspective view and a top view of a ring spring in the vascular compression device of the present invention; and

figure 7 presents a bottom view of a strap of the vascular compression device of the present invention.

Detailed Description

The present invention relates to a vascular compression device 1.

Whenever reference is made herein to the term "bottom" or "below" or "beneath" with respect to the device 1 or an element of the device 1, this term refers to the portion of the device 1 that is proximal to the patient and the limb that requires compression when the device 1 is properly attached to the limb. The term "downward" also refers to in a direction toward the patient's limb.

The terms "top" or "above" as used herein with reference to the device 1 or an element of the device 1 refer to the portion of the device 1 that is distal to the limb of the patient when the device 1 is properly attached to said limb of the patient. The term "upward" refers to a direction from the distal end of a patient's limb.

The device 1 of the present invention has been designed to apply an appropriate compressive force in a specific area of the limb in order to prevent bleeding from the injured blood vessel. At the same time, the device 1 does not exert forces on other major blood vessels in the limb of the patient.

As shown in fig. 1a and 1b and fig. 2a, 2b and 2c, the device 1 comprises four main elements: a hollow body 2, a compression control mechanism 3 including a tensioner 30 and a knob 31, and a belt 4. The hollow body 2 forms the central element of the device 1. The strip 4 is firmly attached to the hollow body 2, in particular to the base 26 of the hollow body 2. This ensures that the strip 4 remains attached to the hollow body 2 during normal use, when it is subjected to considerable forces. In this embodiment, the strip 4 is attached to the pressing region 24 by means of the adhesive 5, and the contact area between the strip 4 and the hollow body 2 corresponds to the entire pressing region 24 of the hollow body 2. This large contact area not only ensures a good fixation of the strap 4 to the hollow body 2, but also provides additional stability to the device 1 when the device is attached to a patient's limb, in particular preventing the device 1 from sliding sideways when applying the device or when adjusting the compression force.

On the side opposite to the attachment point of the belt 4, i.e. at the top, the device 1 is provided with a tensioner 30 and a knob 31, both the tensioner 30 and the knob 31 forming a bolt-and-nut type movable connection with the hollow body 2, in particular with the externally threaded element 21 of the hollow body 2. Tensioner 30 is supported by a knob 31 located below tensioner 30. After assembly of the device 1, the tensioner 30 and the knob 31 move together with respect to the hollow body 2 along the externally threaded element 21 of the hollow body 2. Movement of the tensioner 30 relative to the hollow body 2 provides control of the compression of the patient's limb by the device 1.

As shown in fig. 3a to 3d, the hollow body 2 is formed as a one-piece element. In this embodiment, the hollow body 2 is in the form of a short tube with a flattened circular cross-section. In particular, the base 26 of the hollow body 2 is flattened to provide better contact with the patient's limb. However, the base 26 may be formed in any other shape that will be configured to provide the medical professional with suitable access to the compression region 24 via the base 26 of the hollow body 2 (i.e. a tubular space 23 within the body 2 into which the medical professional can insert his fingers in order to apply a force to the bottom 26 of the hollow body 2 so that the medical professional can manually apply a force to the injured blood vessel when the device 1 is applied to a limb of a patient). In various embodiments, the hollow body 2 is symmetrical along its long axis, so that both hands can operate the device of the invention. Furthermore, the selected shape of the body 2 is required to accommodate the tensioner 30 and the knob 31 disposed over the tubular space 23 within the hollow body 2. For example, the body 2 may have a semi-tubular shape, the walls of which are connected by an externally threaded element 21, the externally threaded element 21 receiving the tensioner 30 and the knob 31. In the presently described preferred embodiment, the tube forming the central part of the hollow body 2 has a longitudinal base 26, which longitudinal base 26 is directed towards the patient's limb in the case of a correct applicator 1. Base 26 is connected to externally threaded element 11 by side wall 22. The base 26 of the tube is wider than the sidewall 22 of the tube and has a greater surface area than the sidewall 22. The outer surface of the base 26 of the hollow body 2 provides a compression zone 24, which compression zone 24 is configured to be in contact with a patient limb when the device 1 is applied. In this embodiment, the pressing area 24 is covered with an adhesive 5, which adhesive 5 connects the strip 4 to the pressing area 24. Thus, the compression zone 24 is in contact with the patient's limb via the band 4 and the adhesive 5. Furthermore, the compression area 24 preferably comprises markings 25, which markings 25 facilitate the positioning of the device 1 on the limb of the patient. When applied to a patient's limb, the positioning indicia 25 should be positioned at the site of the vascular access port. In a preferred embodiment, the hollow body 2, together with its integral elements, is formed of a transparent plastic material. The use of a transparent material ensures visual control of the access site of the catheter or cannula on the limb of the patient. In this embodiment, the body 2 is made of polycarbonate by injection moulding. In addition, the edges of the hollow body 2 are not sharp to increase patient comfort.

In various embodiments, the hollow body 2 is provided with a support 20, which support 20 may be an integral part of the hollow body 2. The support 20 extends from a side of the hollow body 2 (i.e. from a side wall 22 of the hollow body 2 close to a base 26 of the hollow body 2) and away from the pressing area 24.

In the preferred embodiment, the support member 20 is in the form of a curved fin having a wave-shaped cross-section. Initially, as the support 20 extends away from the hollow body 2, the curved fins of the support 20 point upwardly to a deflection point at which the direction of the curved fins changes towards the plane of the compression region 24. The support 20 does not extend beyond the plane of the base 26 of the hollow body 2. Furthermore, at the free end of the support 20 (i.e. the end opposite to the point where the support 20 is connected to the side wall 22 of the hollow body 2), the support 20 is equipped with a support foot 200. When the device is applied to a patient's limb, the support 20 is in contact with the patient's limb at a distance from the compression zone 24. The contact of the support 20 is provided only by the free end of the support 20 or by the foot 200 of the support 20, as is present in the present embodiment. In this way, the device 1 does not compress other major blood vessels located in the vicinity of the blood vessel in which the medical procedure is being performed. Thus, the distance between the compression region 24 and the support foot 200 of the support 20 provides an uncompressed space, which results in undisturbed blood flow in other blood vessels that are not intended to be compressed during a medical procedure. Thus, contact of the device 1 with the volar surface of the forearm of the patient is limited to a minimum, i.e. to the compression zone 24 and the free end of the support member 20 or the foot 200, if the foot 200 is present at the free end of the support member 20, thereby reducing the level of discomfort in the patient when applying the device 1.

The support 20 provides additional support to the device 1 despite limited contact of the support 20 with the patient's limb. The function of the support 20 is therefore to stabilize the hollow body 2 on the patient's limb and thus prevent any unwanted movement of the device 1 after it has been secured to the patient's limb. Without the support 20, the device would tend to tilt sideways due to the force exerted by the belt 4. Preferably, the support member 20 has a wave-like shape, as shown in fig. 3a and 3 b. Other shapes of the support member 20 are also contemplated, however, the corrugated shape is most effective and meets medical and aesthetic requirements. In addition, the free end of the support 20 or the support foot 200 is provided with an insert, preferably made of an elastic material, applied to the surface of the support foot 200 or to the surface of the support 20, which is in direct contact with the limb of the patient. This also aims to increase the comfort of the patient when applying the device 1.

In the presently described embodiment, the hollow body 2 in the form of a tube comprises a side wall 22, the side wall 22 extending circumferentially from a base 26 and being connected at the top by an externally threaded element 21. Inside the tube, a tubular space 23 is provided between the base 26, the side wall 22 and the externally threaded element 21 (i.e. within the periphery formed by the side wall 22, the base 26 and the externally threaded element 21). The tubular space 23 is designed to receive the finger or thumb of a medical professional who applies initial pressure to the pressure area 24 by pressing on the base 26 of the hollow body 2 when applying the device to the limb of a patient. To better access the base 26 of the hollow body 2, the width of the side wall 22 decreases as the side wall 22 extends upwardly (i.e., the wall becomes progressively narrower). The hollow body 2 is designed in such a way that the tubular space 23 is accessible from both sides of the hollow body 2 (i.e. the tube forming the hollow body 2 is open on both ends). In this way, the device is suitable for use on both the left and right forearm of a patient. This ensures the versatile nature of the device.

The side wall 22 provides support for the top part of the hollow body 2, the externally threaded element 21 forming an integral part of the hollow body 2. In the present embodiment, the externally threaded element 21 has the shape of a hollow screw, the axis of rotation of which is positioned perpendicularly to the axis of the tube of the hollow body 2. The axis of rotation of the externally threaded element 21 is also perpendicular to the surface of the base 26 of the hollow body 2. The threaded element 21 has a plurality of grooves, called guide grooves 27, which extend parallel to the axis of rotation of the externally threaded element 21. In this embodiment, four guide grooves 27 are provided, symmetrically positioned on the externally threaded element 21. The guide slot 27 is located along the axis of rotation and perpendicular to the threads of the externally threaded element 21. When the device 1 is assembled, the guide groove 27 receives the knob support member 301 and the guide member 302 of the tensioner 30. So that the hollow body 2 and the tensioner 30 engage each other. Two of the guide grooves 27, which are located opposite to each other and receive the guide member 302 of the tensioner 30, are provided at the top with the blocking protrusion 270. As the tensioner 30 moves upwardly, the blocking protrusions 270 engage the free ends of the guide elements 302 of the tensioner 30, blocking further upward movement of the guide elements 302 and preventing disengagement of the tensioner 30 from the hollow body 2. Another pair of guide grooves 27, also located opposite each other, receive the knob support member 301 of the tensioner 30.

The hollow body 2 in the assembled form of the device 1 is engaged with a tensioner 30 placed above the hollow body 2. Fig. 4 presents a preferred embodiment of the tensioner 30 of the device of the present invention. Tensioner 30 includes a housing 300, a knob support member 301, a guide member 302, and a belt guide 304. Tensioner 30 is located at the top of compression device 1 (i.e., on the side opposite the patient's limb). The tensioner 30 acts as a means for compressive adjustment of the device 1 by adjusting the tension of the strap 4 when the strap is placed around the hollow body 2 and the limb of the patient. A belt guide 304 is formed on top of the tensioner 30 as a support for receiving the belt 4. The belt guide 304 has a longitudinal portion formed as a groove for receiving a portion of the belt 4, preferably located within longitudinal ribs 305, the longitudinal ribs 305 being separated from each other by a distance equal to the width of the received portion of the belt 4. Within the belt guide 304, in the area between the longitudinal ribs 305, a non-slip insert 33 is arranged. The non-slip insert 33 is formed as a sheet of plastic material, more preferably as a sheet of transparent plastic material, the purpose of the non-slip insert 33 being to secure the received portion of the strap 4, as shown in fig. 1 a. The non-slip insert 33 is further provided with symbols such as "+" and "-" and arrows, as shown in fig. 1a, which are printed directly on the non-slip insert 33 or on a separate sticker placed on the non-slip insert 33 to provide information to the medical staff about the direction in which the knob 31 needs to be turned to increase or decrease the pressure on the device 1.

The non-slip insert 33 engages with the belt 4, the belt 4 extending around the patient's limb and being guided over the hollow body 2 and over the tensioner 30 between the longitudinal ribs 305 of the belt guide 304. The strip 4 extends in a direction perpendicular to the axis of the tube of the hollow body 2 and is guided over the hollow body 2 and across the hollow body 2 in such a way that it does not obstruct access to the tubular space 23 inside the hollow body 2. According to a preferred embodiment, as shown in fig. 4, the belt guide 304 of the tensioner 30 is shaped as a groove having two parallel ribs 305 separated from each other. The ribs 305 have an arcuate shape and are aligned parallel to each other. Below the belt guide 304, an integrally connected housing 300 is provided. The housing 300 has a flat dome shape with a circular base. The bottom edge of the housing 300 is aligned with the rib 305 of the belt guide 304. The housing 300 provides a covered area that receives the annular spring 32. Two knob support members 301 and two guide members 302 protrude downward from below the dome of the housing 300. These elements are arranged in the form of a pair formed by two support elements 301 arranged opposite to each other and a pair formed by two guide elements 302 arranged opposite to each other. These elements are symmetrically spaced from each other with respect to the periphery of the circular base of the housing 300. In this embodiment, the support elements 301 and the guide elements 302 are located away from the rim of the circular housing 300, and the spatial arrangement of the support elements 301 and the guide elements 302 corresponds to the arrangement of the guide grooves 27 of the hollow body 2. These elements (i.e. the support element 301 and the guide element 302) slide into the guide groove 27 of the externally threaded element 21 of the hollow body 2 after assembly of the device 1, so as to engage these components, but also ensure a reciprocating movement without rotation of the tensioner 30 relative to the hollow body 2. The support members 301 and the guide members 302 are preferably formed as protruding beams or protruding cuboids extending from the interior of the dome of the housing 300 (from the top portion of the dome). The support element 301 and the guide element 302 are bent at their free ends, i.e. at the opposite position to the housing 300 to which the support element 301 and the guide element 302 are attached, to form a foot-shaped support. The foot of knob support element 301 is bent away from the medial axis of housing 300 to ensure that the foot engages the bottom edge of knob 31 to effect movement of tensioner 30 with knob 31. The foot-shaped support of the guide element 302 is bent towards the middle axis of the housing 300 to ensure that it engages the blocking projection 270 of the guide groove 27 of the externally threaded element 21 of the hollow body 2. The housing 300 is further provided with studs 303 in the form of protrusions, the studs 303 extending downwardly from a top portion of the dome of the housing 300. The studs 303 are designed to retain the ring spring 32 if the ring spring 32 is present in the assembled device 1.

The guide member 302 not only guides the tensioner 30 to reciprocate without rotating, but also limits the movement of the tensioner 30 within a predetermined range by stopping the movement of the tensioner 30 when the bottom portion of the guide member 302 reaches the top edge of the externally threaded member 21 of the hollow body 2. The knob support member 301 not only guides the tensioner 30 to reciprocate without rotating, but also moves the tensioner 30 together with the knob 31 turning along the thread of the externally threaded member 21, particularly in the downward direction. During the upward movement, the knob 31 raises the tensioner 30 because the tensioner 30 rests on top of the knob 31.

All elements of tensioner 30-housing 300, support element 301 and guide element 302, and belt guide 304-are formed as a unitary element from a plastic material. Preferably, the plastic material is transparent, which makes the element very aesthetically pleasing, but is also useful in medical applications of the component, as it does not obstruct the view of the patient's limb, in particular the vascular puncture site. In the most preferred embodiment, tensioner 30 is made of polycarbonate by injection molding. Tensioner 30 is easily released from the injection mold due to its configuration.

Due to the system comprising both the tensioner 30 and the knob 31, a movement of the tensioner 30, and thus a pressure control of the device 1, is possible. The knob 31 as shown in fig. 5 is preferably formed as a swivel nut having an outer diameter at one end corresponding to the outer diameter of the circular base of the dome of the housing 300. The knob 31 comprises an inner opening, the surface of which is provided with an internal thread 312, which internal thread 312 engages with the thread of the externally threaded element 21 of the hollow body 2 after assembly of the device. The outer wall of the knob 31 is covered by pointers 311 arranged equidistantly in the circumferential direction. The pointer 311 indicates a value assigned to the rotation state of the knob 31. It is also possible to indicate between the hands a value to provide additional information about the pressing force of the device 1. As already described, the knob 31 is movably engaged with the tensioner 30 via the protruding knob support element 301. The knob 31 is arranged such that the knob support element 301 and the guide element 302 are all located within the opening of the knob 31. In addition, the knob support member 301 prevents the knob 31 from disengaging from the tensioner 30, while the guide member 302 prevents both the tensioner 30 and the knob 31 from sliding off the hollow body 2 by engaging with the blocking projection 270 of the guide groove 27 of the externally threaded member of the hollow body 2.

Knob 31 performs both rotational and reciprocating motion, wherein reciprocating motion of knob 31 causes reciprocating motion of tensioner 30. The reciprocating motion is a motion of the pressing force of the adjusting device 1 of the pressing control mechanism 3 to the limb of the patient. The rotary movement of the knob 31, effected by engagement with the external thread of the externally threaded element 21 of the hollow body 2, forces the compression control mechanism 3 to perform a reciprocating movement perpendicular to the limb, the knob 31 being screwed with its internal thread 312 onto this external thread. This movement of the compression control mechanism 3 regulates the compression of the device 1 by the strap 4, thereby regulating the compression of the patient's limb by the device 1. Furthermore, the knob 31 has a peripherally located groove in its top area. The groove is provided with cogs 310, which cogs 310 are preferably formed in the manner of gear teeth, i.e. the cogs 310 are protrusions separated by recesses. Cog 310 interacts with an annular spring 32 seated within housing 300 of tensioner 30 and produces a clicking sound as knob 31 is rotated. This click is an audible confirmation of the rotation of the knob 31, which further corresponds to information about the pressing of the device 1.

Like the other elements of the device 1, all the edges of the knob 31 are rounded, not only for aesthetic purposes, but also to prevent any injury to the patient. Furthermore, according to a preferred embodiment, the knob 31 is formed of a plastic material. More preferably, the knob 31 is formed of a transparent plastic material, such as poly (ethylene terephthalate), by injection molding. The transparent nature of this element is advantageous for the same reasons as already described for the other components of the device 1.

The radial pressing device 1 is provided with a pressing adjustment member composed of a tensioner 30 and a knob 31. According to a preferred embodiment of the invention, the device 1 is provided with means for indicating the displacement of the tensioner 30 and the knob 31 to facilitate the compression control. In addition to the pointer 311 and the numerical indicator on the knob 31, in a preferred embodiment of the invention, the device is provided with audio means for indicating the rotation of the knob 31. For this purpose, an annular spring 32 is provided. As shown in fig. 6, the annular spring 32 has the shape of a ring comprising two sets of protrusions, a protrusion 320 and a blocking tongue 321. Protrusions 320 are positioned circumferentially opposite one another along the ring. Each protrusion 320 extends in a direction perpendicular to a plane containing the ring. The protrusion 320 of the ring spring 32 engages with the recess between the cog 310 of the knob 31. This engagement provides the desired audible click when the knob 31 is turned in either direction. When the knob is turned, the protrusion 320 is displaced from one recess to another recess on the knob 31, regardless of the direction or speed of the turning, and a click sound is generated. The second set of protrusions, the blocking tongues 321, prevents the annular spring 32 from rotating when the knob 31 is turned. The stop tongue 321 is circumferentially disposed along the inner diameter of the ring. In the present embodiment, the blocking tongue 321 lies in the plane of the annular piece and extends towards the middle of the circle defined by the annular spring 32. As shown in fig. 4b, the annular spring 32 is seated within the housing 300 of the tensioner 30 between the housing 300 and the knob 31, thereby engaging both the housing 300 and the knob 31 through two sets of protrusions 320, 321. The protrusions 320 engage with the knob 31 in the recesses between the cogs 310, while the blocking tongue 321 is seated between the studs 303, the studs 303 projecting downwards within the housing 300 of the tensioner 30. The distance between two adjacent studs 303 corresponds to the width of the corresponding blocking tongue 321.

In the assembled device 1, the annular spring 32 is seated within the dome of the casing 300 such that the annular spring 32 is adjacent to the peripheral wall of the casing 300, the blocking tongue 321 is inserted between adjacent studs 303 of the casing 300, and the protrusion 320 extends downwards towards the recess between the cogs 310 of the knob 31. In a preferred embodiment, the annular spring 32 is curved such that the portion of the annular spring 32 provided with the protrusion 320 protrudes from the plane of the annular spring 32 in the direction of the knob 31. Further, the ring spring 32 is formed of a plastic material. In a preferred embodiment, the plastic material is resilient to ensure the desired flexibility of the annular spring 32. In the most preferred embodiment, the annular spring 32 is made of polyetherimide, which provides both flexibility and durability of the annular spring 32. The use of the annular spring 32 is very advantageous in that it provides a snap-in mechanism and at the same time does not increase the size of the device 1 (i.e. the snap-in mechanism has been significantly miniaturized).

As mentioned above, the movement of the aforementioned compression control mechanism 3, including the tensioner 30 and knob 31, can be responsible for tightening or loosening the belt 4 extending around the patient's limb and the tensioner 30. In this way, the device 1 makes it easy to control the compression force applied to the blood vessels in the limb. When the knob 31 is rotated, the knob 31 reciprocates the compression control mechanism 3 in a direction perpendicular to the surface of the limb. As the tensioner 30 moves upwardly, increased tension is applied to the belt 4, which in turn creates increased compression of the hollow body 2 against the patient's limb.

The strip 4 is a one-piece element, i.e. the strip 4 is formed from a single piece of plastics material. In a preferred embodiment, the belt 4 also has anti-slip properties, i.e. the surfaces of the belt 4 do not slide against each other when in contact. This also increases the stability of the device 1 when it is applied to a limb of a patient. Preferably, the strap 4 is transparent, i.e. the strap 4 does not obstruct the view of the patient's limb. Whilst the strap 4 is resilient, the strap 4 may be wrapped around the limb of the patient and over the top of the device 1. As shown in fig. 7, the belt 6 may be divided into three sections that gradually transition from one section to another: a narrower strip portion 41, the narrower strip portion 41 beginning at the free end of the strip 4; a wider belt portion 42, the wider belt portion 42 forming a middle portion of the belt 4; and a connecting band portion 43, the connecting band portion 43 attaching the band 4 to the hollow body 2. When the device 1 is applied to a patient's limb, the narrower band portion 41 extends over the tensioner 30 and wraps around the patient's limb again. Thus, the width of the narrower belt portion 41 corresponds to the width of the belt guide 304 of the tensioner 30. The narrower strip portion 41 is optionally provided with a locking sticker 40 near the free end of the strip 4, which locking sticker 40 helps to secure the strip 4 in the folded position.

The narrower strip portion 41 extends, preferably gradually, into the wider strip portion 42. When the device is applied to a patient's limb, the wider band portion 42 is in contact with the back side of the patient's limb. The increased width of the strap 4 in this section increases the comfort of the patient and the stability of the device when applied to the limb. The wider belt portion 42 is preferably provided with two guide edges 44, the guide edges 44 extending in the length direction of the belt 4 and forming a groove. The distance between the guide edges 44 corresponds to the width of the narrower strip portions 41, the narrower strip portions 41 being received in the grooves formed between the guide edges 44 when the device 1 is applied to a limb. The guide edge 44 ensures that the narrower strip portion 41 remains in place as the strap 4 is wrapped around the limb of the patient.

The belt 4 is connected to the hollow body 2 by a connecting belt portion 43. The connection between the belt 4 and the hollow body 2 is durable because it is subjected to the forces associated with the tension forces generated by the upward movement of the tensioner 30. In the present embodiment, the connecting band portion 43 is connected to the hollow body 2 by the adhesive 5, the adhesive 5 being disposed between the connecting band portion 43 and the pressing region 24 of the hollow body 2. In addition, on the surface opposite to the adhesive 5, the connecting band portion 43 is provided with a pressing insert 45 (i.e., the pressing insert 45 faces the limb of the patient). The compression insert 45 is preferably formed of an elastic material and provides additional compression in a desired area of the limb.

As shown in fig. 1a and 1b, vascular compression device 1 according to the preferred embodiment is applied to a limb by placing a primary compression region 24 of hollow body 2 over the appropriate blood vessel to be compressed. Regardless of the vessel under compression or the limb on which the device of the invention is mounted, the stabilizing support 20, which provides proper support for the device and proper fixation of the device position, is facing the middle of the wrist. For example, if the device is attached to the left wrist and is to compress the radial artery, support member 20 protrudes in the direction of the middle of the wrist. The device is applied to the limb by pressing the hollow body 2 by means of the tubular space 23 of the hollow body 2 (for example by pressing the inner surface of the base 26 of the tube) and is fixed and secured by wrapping the strap 4 around the limb and also around the device 1 itself. The end of the belt 4 is fixed, thereby preventing the belt 4 from unwinding. Preferably, the ends of the strip 4 are secured by an adhesive, such as a locking sticker 40. This also prevents any accidental release of compression.

Component list

1-vascular compression device

2-hollow bodies/tubes

20-support element

200-support foot

21-elements with external thread

22-side wall of hollow body

23-tubular space

24-compression zone (i.e. outer surface of longitudinal base) 25-positioning mark

26-longitudinal base

27-guide groove

270-blocking projection

3-compression control mechanism

30-tensioner

300-shell

301-knob support element

302-guide element

303-stud

304-tape guide

305-longitudinal rib with guide

31-knob

310-cog

311-pointer

312-internal screw thread

32-ring spring

320-projection

321-blocking tongue

33-slip insert

4-band

Locking sticker at free end of 40-strap

41-narrower band part

42-wide belt portion

43-connecting band part

44-guide edge

45-primary compression insert

5-adhesive for fixing a strip to a hollow body