RU202209U1 - BLOOD STOPPING DEVICE - Google Patents

Abstract

The utility model relates to medical technology and can be used to compress the damaged main blood vessels of the extremities in order to temporarily stop bleeding.

The essence of the utility model: a hemostatic device contains a compression module, consisting of a body, to the front and rear walls of which are attached through connectors the ends of a tensioning belt, one or more pressure rollers, eccentrically rigidly fixed on the axes passed through the side walls of the body, lever gate devices for rotation pressure rollers, receptacles of the lever gate device rods set according to the indications of the position of the rods of the lever gate devices, an extensible belt tensioner of the pressure rollers attached from the inside to the body of the compression module, containing in the zone of pushing out the pressure rollers outside the body of the compression module a flexible plastic support platform with a shock absorbing pad facing the body made of porous ribbed polyethylene with transverse orientation of recesses.

The non-extensible tensioning belt contains a formed loop, the bases of which are interconnected by an additional extensible sling, a rectangular mechanical spring buckle and a quick-acting mechanical connector in the form of a half-ring to be thrown onto a hook located on the compression module housing.

Control of the actual time of soft tissue compression is provided by a visual assessment of the information reflected on a graphical indicator attached to the compression module housing.

The technical result of the presence of the given set of features in the design of the hemostatic device is to expand the indications for its use, increase the availability, reliability and efficiency of the first medical self- and mutual aid for injuries of the great vessels with simultaneous significant optimization in terms of the timing and convenience of the procedure for applying the hemostatic device itself, including including wearing clothes, as well as reducing the likelihood of adverse effects of the imposition of a hemostatic device by eliminating the possibility of additional tissue injury and the possibility of performing controlled compression of soft tissues under medical supervision during transportation of the wounded. 3 C.p. f-ly, 2 dwg

Description

A useful model of a hemostatic device relates to medical technology and can be used to squeeze the damaged main blood vessels of the extremities in order to temporarily stop bleeding.

Known haemostatic tourniquet (tourniquet Esmarch), which contains a rubber tube, at one end of which is fixed a metal hook, and on the other - a metal chain, which are designed to secure the imposed tourniquet [1].

Its main disadvantage is the difficulty of independent application and the difficulty of dosing the level of compression pressure on the tissues of the injured limb.

Known hemostatic tourniquet containing an inextensible tape equipped with a clamping element, an extensible tape with marks made on it corresponding to the attainable compression force for the shoulder and lower leg of 4.3 kg, and for the thigh 12.7 kg, while the tensile tape is connected to the inextensible tape with one end is one-piece, and at the other end it has a rectangular yarn clamp equipped with a clamping element made in the form of a movable bar [2].

The main disadvantage when applying this hemostatic tourniquet to an injured limb is the need to apply great efforts and a low rate of creating the necessary compression pressure on the injured limb when it is applied over clothing.

Known hemostatic tourniquet containing an inextensible tape, consisting of a loop worn on the injured limb, and a tightening mechanism. The tightening mechanism consists of a platform with a clip for fixing the stick, which tightens the tourniquet by twisting an inextensible section of the tape between the buckles. The stick is made in the form of a cylinder with bulges at the ends and a slot in the middle for threading the tape [3] ..

The disadvantages of this device are the lack of elasticity of the tourniquet, low accuracy of creating a dosed force on the tissue of the injured limb, since it depends on the large angle of rotation of the twist stick. The need to fix the twist stick makes the force of the tourniquet application dependent on the frequency of rotation of the twist stick by 180 degrees. In addition, the shortening of the bundle circumference, equal to the length of the tape that goes into the twist during the rotation of the stick, also limits the accuracy of the force control.

Since when twisting the tape with a stick, the length of the tourniquet is limited by the distance between the buckles, in winter it does not always allow creating the necessary pressure through clothing to stop bleeding on the injured limb.

Known hemostatic tourniquet containing an elastic insert having marks corresponding to the achieved compression force for the shoulder and thigh, connected to an inextensible tape on one side with a self-locking rectangular buckle with a pressure element, and the non-stretchable tape is connected to the elastic insert with an additional second self-locking buckle with a pressure element [ four].

The disadvantages of this device are the low speed of creating the required pressure on the injured limb, especially when a tourniquet is applied over clothing.

Known hemostatic tourniquet containing an inextensible tape, an extensible tape in the form of a rubber element connected to two rectangular steel rings on both sides, with rectangles applied to it and the inscriptions "Thigh", "Shoulder", a twist stick, characterized in that the inextensible tape forms a double loop when the tourniquet is applied, and the twist stick is made with a recess in the middle and conical arrow-shaped ends [5].

This design provides the possibility of applying a tourniquet with minimal physical effort, more accurate dosing of the required pressure on the tissues of the injured limb, unlimited possibility of reducing the circumference of the tourniquet to apply it to the limbs of any circumference, regardless of the presence or absence of clothing, no pinching of the underlying tissues when applying the tourniquet, simplified fixation harness due to the design of the twist stick with a recess in the middle.

This device, which is the closest to the proposed utility model in terms of the generality of the tasks to be solved, was chosen as a prototype.

At the same time, the main disadvantages of this and all other known hemostatic devices and tourniquets are the complex technology of their use, significantly limited opportunities for the timing of the compression of the injured vessel, the impossibility of performing controlled compression, and the traumatic effect on soft tissues.

The purpose of the utility model is to develop a design of a multifunctional hemostatic device with unlimited indications for use, which optimizes the time and convenience of the procedure for selective compression of the damaged vessel, which increases the reliability and efficiency of the first medical self- and mutual aid for injuries of the great vessels.

The essence of the utility model: a hemostatic device contains a compression module, consisting of a body, to the front and rear walls of which are attached through connectors the ends of a non-stretching tension belt, one or more pressure rollers, eccentrically rigidly fixed on the axes passed through the side walls of the body, lever gate devices for rotation of the pressure rollers, receptacles for the position of the rods of the lever gate devices set according to the indications, an extensible belt tensioner of the pressure rollers attached to the inside of the compression module housing, containing in the zone of pushing out the pressure rollers outside the compression module housing a flexible plastic support platform with a shock-absorbing pad facing the body, made of porous ribbed polyethylene with transverse orientation of the recesses.

The non-extensible tensioning belt contains a formed loop, the bases of which are interconnected by an additional extensible sling, a rectangular mechanical spring buckle and a quick-acting mechanical connector in the form of a half-ring to be thrown onto a hook located on the compression module housing.

Control of the actual time of soft tissue compression is provided by a visual assessment of the information reflected on a graphical indicator attached to the compression module housing.

The positions of the eccentrically fixed rollers on the axes in the compression module housing, actively modified by literally one movement with the help of a manual lever device, allows, with a previously created, easily reproducible dosed pretension of a tensioning belt located, for example, around a limb, to provide a metered selective contact pressure on a plastic elastic support pad attached to a belt tensioner and located under it a porous ribbed polyethylene lining, and with this and on the tissues located under them to a level at which the cessation of bleeding from the damaged vessel is achieved. At the same time, a sufficiently large elastic support platform automatically takes on the curvature of the underlying tissues at the site of application of the hemostatic device when turning the pressure rollers, and thereby minimizes the level of the required effective pressure on the underlying tissues. The likelihood of a negative effect of compression on underlying tissues is reduced by the additional use of a porous polyethylene pad under the support pad. Rigid tissue ischemia when using a hemostatic device is prevented by the ribbed surface of the shock-absorbing pad, as well as the formation of limb areas free from local compression, directly adjacent to the compression module body, through which collateral blood circulation is possible.

Controlled, strictly reproducible dosed pretension around the limb of an inextensible belt using a spring buckle before changing the position of the rollers in the compression module housing is provided by stretching elastic straps that connect the base of the loop-shaped bend formed from a continuous tension belt.

Control of the effectiveness of clamping of the main vessel is confirmed by the cessation of bleeding.

At the same time, the control of the actual time of soft tissue compression is provided by the astronomical time records on the indicator equipped with a protective lock in the form of a “Contact” tissue fastener.

This design makes it possible to separate the functions of choosing the optimal location of the hemostatic device on the injured limb, preliminary fixing it in the place required for the situation and dosed pre-tensioning of the tensioning belt, as well as the function of creating a local zone of soft tissue compression by a support platform under visual observation of the dynamics of bleeding directly at the moment of compression tissue above the site of injury.

At the same time, the design capabilities of the device allow reducing the "conventional" length of a non-stretching tensioning belt by at least 50 mm after its preliminary pretensioning due to pushing the rollers out of the compression module housing and at the same time strictly controlled and clearly reproducible immersion of the support platform into the underlying tissues by 25 30 mm allows the hemostatic device to be applied both on the naked body and over clothing. In this case, a tension belt covering the limb prevents the tissue from spreading along the sides when the pressure rolls are immersed in them and thereby contributes to the compression of the underlying tissues and ensuring the collapse of the vessels at a shallower immersion depth of the pressure rolls in the tissue.

The technical result, provided by the presence of the given set of features in the design and methods of connecting the structural elements of the hemostatic device, is to expand the indications for use, increase the availability, reliability and efficiency of the first medical self- and mutual aid for injuries of the great vessels with simultaneous significant optimization in terms of timing and convenience of the very procedures for imposing a hemostatic device, as well as reducing the likelihood of adverse consequences of imposing hemostatic devices by eliminating the possibility of additional tissue injury and the possibility of varying the degree of compression at the stages of medical evacuation.

By the totality of the distinctive features of the design and the methods of connecting the structural elements with each other, as well as the achieved effects, the proposed utility model is characterized by "non-obviousness of the design used as a means for temporarily stopping bleeding", "novelty", "technical feasibility" and "industrial applicability" for complex solving applied problems to ensure the necessary level of the first medical self-and mutual aid for injuries of the great vessels.

FIG. 1 and 2 show a schematic diagram of the general view of the hemostatic device in longitudinal section in the initial position and when it is transferred to the working position.

Structurally, the hemostatic device (Fig. 1, 2) contains an inextensible tension belt 1 and a compression module 2.

Non-extensible tensioning belt 1, equipped with a mechanical spring buckle 3 of a rectangular shape, is mechanically divided into two segments attached to the sides of the housing 4 of the compression module 2. In this case, one segment of the belt 1 is additionally equipped with a quick connector made in the form of a half-ring 5, thrown onto the hook 6, located on the housing 4. In the area of fastening of the spring buckle, a loop-shaped bend 7 is formed from a single piece of belt, connected to each other by an elastic sling 8 having a resistance to full extension equal to, for example, 4 kg.

Inside the body 4 there are two pressure rollers 9, eccentrically rigidly fixed on the axes 10 passed through the front and rear walls of the body 4. On the axes 10 protruding beyond the edge of the body 4, the rods 11 are hinged with side pins directed towards the body, performing the function lever gate device.

On the front and rear walls of the housing 4 of the compression module 2 for receiving and fixing the rods 11 in the selected position, there are notched holes 12 along the circumference with a pitch, for example, 10 degrees and a diameter equal to the diameter of the side pins of the rod 11.

From the inside to the housing 4 of the compression module 2 from opposite sides are attached the ends of the elastic tape tensioners 13 of the pressure rollers 9 allowing their elongation equal to at least two diameters of the pressure rollers 9. In this case, the elastic tape tensioner 13 in the contact zone with the pressure rollers 9 contains a flexible a support platform 14 and a body-facing porous ribbed polyethylene spacer 15.

In addition, the device is equipped with a tape indicator of the time of the device application with a latch made in the form of a “Contact” fabric fastener (not shown in the figure).

The use of the hemostatic device shown in FIG. 1 and 2, with injuries of the great vessels is carried out as follows.

The person applying the device is positioned facing the victim from the outside of the injured limb and starts the end of the section of the mechanically disconnected tensioning belt 1, equipped with a half ring 5, under the limb (leg or arm) above the area of injury.

Secures the half-ring 5, connected to the end of the tensioning belt segment 1, on the hook 6 located on the side wall of the housing 4 of the compression module 2.

Installs the compression module 2 in the desired position above the site of the bleeding vessel and presses the included elastic support pad 14 with a porous polyethylene liner 15 oriented to the body located under it with ribbing applied to it from the outside.

Pre-tension the belt 1 by pulling it in the spring buckle 3 until it is eliminated by stretching to the limit of the shortened elastic sling 8 of the loop-shaped bend 7.

After that, using the rods 11 of the lever gate devices, it rotates the eccentrically rigidly fixed on the axes 10 in the body 4 of the pressure rollers 9 to press the support platform 14 and the porous polyethylene gasket 15 oriented to the body until the bleeding stops visually.

To do this, the rods 11 are sequentially extended from the toothed holes located on the axes 10 of the two pressure rollers 9, and they rotate from left to right until the first signs of perceptible pressure of the support platform 14 and the porous polyethylene gasket 15 oriented to the body appear. cessation of bleeding is visually observed.

The side pins of the rods 11 are sequentially fixed in the toothed holes 12, which function as a device for fixing the pressure rollers 9 in the selected (required) position.

When a subjectively unpleasant, perceived as excessive local pressure of the support platform 14 appears with a porous polyethylene lining 15 located under it oriented to the body, it is allowed, if there are conditions for constant visual monitoring of the wound with a bleeding vessel, to reduce the tension on the belt 1 using a spring buckle 3 or by changes in the lock 12 of the position of the rods 11, orienting the position of the pressure rollers 9.

This design makes it possible to separate the functions of choosing the optimal location for the hemostatic device and the function of subsequent compression of soft tissues by the support pad 14, which allows stopping bleeding by minimal and dosed compression of tissues above the site of vessel damage. At the same time, due to the elasticity of the support platform 14, an automatic functional adjustment of its curvature to the area of the human body where the hemostatic device is applied is provided, and thereby minimizes the likelihood of excessive pressure on the tissue.

Prolonged clamping of a limb with a hemostatic device, especially if the conditions for its safe use are not observed, can lead to serious consequences, therefore it is necessary to enter the time of its imposition in the index (not shown in the figure).

The simplicity of the design of the hemostatic device eliminates the need for special training of the user before use and allows its independent use, as well as free use by unauthorized persons. In this case, the standard of time for its imposition is reduced to 5 s by performing four sequential actions:

- wrapping the injured limb with the free end of a section of the tensioning belt and restoring the integrity of the belt using a quick connection of the integrity of the tensioning belt, provided by putting a half-ring on the hook located on the side of the compression module housing;

- installation of a compression module with a tension strap thrown over it on the limb above the bleeding vessel and pressing the base of the compression module body to the body to reduce or, at best, to stop bleeding;

- exercising, while pressing the base of the compression module body to the tissues of the limbs, dosed pretension of the belt using a spring buckle lock until the loop-like bend on the belt is eliminated

- implementation of a separate sequential transfer of the pressure rollers of the compression module by rotating the rods of the lever gate devices to the working position, in which the cessation of bleeding will be visually established in the absence of pain. In this position, the pressure rollers are secured by placing the lateral pins of the rods in the corresponding holes on the compression module housing.

This device is applicable for stopping arterial bleeding in single-bone and two-bone segments of the upper and lower extremities, which expands the indications and possibilities of its practical application.

After transferring the hemostatic device to the working position, if necessary and having the opportunity for constant medical visual monitoring of the wound, it is possible to correct the dosed compression of the damaged vessel by changing the position of the pressure rollers.

All metal, plastic and fabric materials used in the manufacture of a utility model are widely adopted by the industry, technologically easily processed to give them the necessary properties and shape, in accordance with the design and technological features and do not have a harmful effect on the human body, both during use and during manufacture.

The industrial applicability of the utility model is ensured by the relevance of the problem being solved and the high medical and technical characteristics of the product itself, such as simplicity of design, convenience and wide availability of use, quick transfer to a working position, including independently without applying great efforts, eliminating the possibility of additional injury to damaged tissues, ensuring the maximum possible comfort for the wounded the very procedure of applying the hemostatic device and the subsequent finding of the hemostatic device on the body.

This hemostatic device can be used in the provision of emergency medical care both in hospitals and in the field, including when applied over clothing.

SOURCES TAKEN INTO ACCOUNT WHEN DRAFTING A UTILITY MODEL DESCRIPTION

1. Traumatology and Orthopedics: Textbook. Kotelnikov G.P., Mironov S.P., Miroshnichenko V.F. - M .: GEOTAR-Media, 2006 .-- 400 p .: ill.

2. RF patent for invention №2113825.

3. US patent for invention No. 2012071917.

4. RF patent for useful model No. 65747.

5. RF patent for invention №2537777.

Claims (4)

1. A hemostatic device, consisting of an elastic strap, equipped with a mechanical tensioner and fastener for fixing the selected position, characterized by the presence of a compression module, consisting of a body, to the side walls of which the ends of the segments of a mechanically disconnected inextensible tension belt, one or more pressure rollers are attached through the connectors, eccentrically fixed on the axes passed through the front and rear walls of the body, lever gate devices made in the form of rods containing side pins, fixed on the axes of the pressure rollers with the possibility of providing an arbitrary setting of the angle of rotation of the pressure rollers, receiver-retainers of the selected position of the rods, made in the form toothed slots located around the circumference of the side walls with a pitch of at least 10 degrees, equal in size to the diameter of the side pins of the rods and an elastic belt tensioner of pressure rollers attached to the inside of the compression module housing, complement A flexible plastic support platform and a shock-absorbing pad from the side facing the human body, separately containing in the zone of pushing out the pressure rollers outside the compression module housing, while an inextensible tension belt mechanically divided into two sections is assembled so that one end of the first section of an inextensible tension belt is connected to the housing compression module, and the second end of this section is equipped with a mechanical spring buckle, made with the possibility of providing arbitrary tension and automatic fixing of the position of the free end of the second section of the inextensible belt passed through it, the second end of the second section of the tensioning belt is equipped with a mechanical connector. 2. The haemostatic device according to claim 1, in which the mechanical connector is made in the form of a half-ring, thrown over a hook located on the side of the compression module housing. 3. The hemostatic device according to claim 1, characterized by the presence on the side of the support platform facing the human body, a ribbed shock-absorbing pad with a transverse orientation of the recesses. 4. The hemostatic device of claim. 4, wherein the cushioning pad is made of porous polyethylene.

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