RU2651089C1 - Magnetically operated urethral sphincter - Google Patents

Abstract

FIELD: medical equipment.

SUBSTANCE: invention relates to medical devices, in particular to surgical devices, and can be used for urinary incontinence treatment. Technical result is achieved in an implanted sphincter, which comprises a cuff, reservoir, connected together by connecting means, and liquid, with which they are filled, wherein the reservoir has deformable walls and is characterized in that it comprises a control element, creating a magnetic field, and a ferrofluid is used as a filling liquid, wherein the walls of the reservoir are designed to be elastically stretched under the action of the control element, at least to dimensions, which provide a pressure reduction in the cuff below the pressure of the urinary tract.

EFFECT: technical result of the invention is increased usability and reliability of the implanted sphincter due to the simplified design.

12 cl, 2 dwg

Description

The invention relates to medical devices, in particular to surgical devices, and can be used to eliminate urinary incontinence.

Urinary incontinence occurs when the sphincter of the bladder is impaired.

Known implantable sphincter according to the patent of the Russian Federation No. 2380058 (publ. 01/27/2010), containing a fillable cuff connected by connecting means to a reservoir with deformable walls that controls the pressure through a manually driven pump for moving fluid from the cuff into the reservoir containing means for regulating fluid flow, comprising a first valve located between the cuff and the pump, and a second valve located between the pump and the pressure regulating tank, the valves being configured to create one direct flow of fluid from the cuff to the reservoir when pumping the device. In this case, the walls of the tank regulate the pressure in the cuff and are made with the possibility of elastic stretching to a position corresponding to the pressure of the closure of the urethra

The disadvantage of this device is that a hand pump is used to fill the cuff, which does not provide ease of use, since the activation of the device is associated with repeatedly squeezing the camera of the implanted hand pump, as well as the fact that the device has a complex structure and it contains movable mechanical elements and valves as well as capillary or porous elements, which reduces its reliability.

The technical result, to which the invention is directed, is to increase the usability and reliability of the implantable sphincter by simplifying the design.

The technical result is achieved in an implantable sphincter, which contains a cuff, a reservoir, interconnected by connecting means, and the fluid with which they are filled, moreover, the reservoir is made with deformable walls and differs in that it contains a control element that creates a magnetic field, and as a filling fluid ferrofluid is used, while the walls of the tank are made with the possibility of elastic stretching when exposed to a control element at least up to sizes that provide ayut decrease the cuff pressure lower urethral pressure overlap.

It is preferable to use a permanent magnet as a control element, made with the possibility of approaching and moving away from the tank.

It is preferable to use a neodymium magnet as a permanent magnet.

In one embodiment of the device, an electromagnet is used as a control element.

In one embodiment of the device, the electromagnet is configured to approach and move away from the reservoir.

In one embodiment of the device, the electromagnet is configured to smoothly lower or increase the magnetic field.

In one embodiment, the electromagnet is configured to programmably change the magnetic field.

In one embodiment of the device, the connecting means are at least two tubes, at least one of the tubes is made with a one-way valve, which provides unidirectional flow from the cuff to the tank, and at least one tube does not contain a valve, and the total cross section tubes without valves are smaller than the total cross-section of tubes with valves.

Preferably, the implementation of the tubes that do not contain valves, with the possibility of ensuring the flow of ferrofluid from the reservoir into the cuff for 2-3 minutes after removing the magnetic field, providing then the pressure in the cuff above the pressure of the closure of the urethra.

Preferably, the elements of the device are made of silicone.

Preferably, the tubes are bend resistant.

It is preferable to perform a reservoir with varying degrees of wall stiffness, the wall facing the bladder after implantation, is stretched. In this case, it is possible to increase the pressure in the cuff, simultaneously with the increase in pressure in the abdominal cavity (with coughing, sneezing, tension of the abdominal muscles), in order to exclude involuntary leakage of urine through the urethra

Figure 1 shows a diagram of an embodiment of a magnetically controlled urethral sphincter containing a cuff 1 located around the urethra, a reservoir 2, a connecting tube 3 filled with ferrofluid 4, and a control element 5: a) when the control element 5 is brought up to the tank 2; b) when removing the control element 5.

Figure 2 shows a diagram of an embodiment of a magnetically controlled urethral sphincter made with two tubes 3 and 6, while one of the tubes 6 is made with a one-way valve 7, which ensures the creation of a unidirectional flow from the cuff to the reservoir, and the other tube 3 does not contain a valve, moreover, its cross section is less than the cross section of the tube 6 with valve 7: a) when the control element 5 is brought up to the reservoir 2; b) when removing the control element 5.

The invention in one of the options can be implemented in a device containing a cuff 1 located around the urethra, a reservoir 2, a connecting tube 3 filled with ferrofluid 4, and also a control element 5 that creates a magnetic field - a permanent neodymium magnet.

The device operates as follows.

The reservoir 2 is implanted in the paravesical space. The cuff 1 is made without folds; the length of the cuff and connecting tubes 3 and 6 is selected individually depending on the place of implantation, and for the bulbous section or neck of the bladder is selected in the range from 4 to 11 cm, with a width of 3.5 cm. It is recommended that sphincter implantation be performed from one penoscrotal access ( S. Wilson et al., 2003). Device activation is carried out after 3-4 weeks in a hospital. Through a connector (not shown), the device is filled with ferrofluid. To ensure the continent, the pressure in the cuff should slightly exceed the pressure in the bladder. Typically, a pressure of 60-70 cm of water is sufficient to provide the continent even with coughing, sneezing, and tension of the abdominal muscles.

The ferromagnetic fluids synthesized in the 60s are colloidal solutions of the smallest particles of magnetic material in a liquid carrier, strongly polarized in the presence of a magnetic field. To ensure the stability of such a liquid, ferromagnetic particles bind to a surfactant that forms a protective shell around the particles and prevents them from sticking together due to Van der Vasals or magnetic forces. A ferrofluid is a suspension of nanoparticles of ferromagnet (usually magnetite) of about 10 nm in size, placed in a surfactant (an organic solvent such as oleic acid or water), which forms a film around the nanoparticle, preventing the nanoparticles from sticking together. This is a black liquid, attracted by a magnet without separation of solid particles and liquid. Since 1 cm ^{3 of} magnetic fluid contains about 10 ¹⁷ such particles, thus, the force acting on each particle is transmitted by viscous friction to adjacent fluid layers, and the entire volume of the solution moves into the field of strong fields as a whole. Ferromagnetic fluids do not exhibit ferromagnetic properties, since they do not retain residual magnetization after the disappearance of an external magnetic field; possess high magnetic susceptibility, stability for several years and at the same time have good fluidity in combination with the properties of magnetism. Their advantage is: incompressibility, low density, quick reaction to external magnetic action (less than 1 ms).

In the device shown in figure 1, a), when the magnet 5 is brought to the reservoir 2 filled with ferrofluid 4 (its location can be noted, for example, with green paint on the skin), the fluid 4 moves from the cuff 1 through the tube 3 into the reservoir 2, due to deformation the walls (expansion) of the reservoir 2 with a ferrofluid 4 drawn to the magnet 5, and, as a result of this, creating pressures between the cuff 1 and the reservoir 2, the cuff 1 is emptied and the urine is poured out of the bladder. After the magnet 5 is removed (see FIG. 1, b), the reservoir 2 decreases in size due to the elasticity of the walls, and due to the pressure difference in the reservoir 2 and the cuff 1, the cuff 1 through the connecting tube 3 is refilled and squeezes the urethra.

In the device shown in Fig. 2, a, when the magnet 5 is brought to the reservoir 2 filled with ferrofluid 4 (its location can be noted, for example, with green paint on the skin), the fluid 4 moves from the cuff 1 through the tube 3 and 6 into the reservoir 2 due to deformation the walls of the reservoir 2 with a ferrofluid 4 attracted to the magnet 5, and, as a result of this, creating pressures between the cuff 1 and the reservoir 2, the cuff 1 is emptied and the urine begins to pour out from the bladder. After removing the magnet 5 (see Fig. 2, b) in the tube 3, due to the pressure difference in the reservoir 2 and the cuff 1, the valve 7 closes, and the cuff 1 is filled through the connecting tube 6 and compresses the urethra. The cross section of the tube 6 provides a reverse transfer of ferrofluid 4 from the reservoir 2 to the cuff 1 for 2-3 minutes, which is enough to complete the act of urination. If necessary, you can block the reverse pumping of fluid 4 from the reservoir 2 by re-applying the magnet 5 to a previously designated point on the skin.

The device does not contain mechanical elements and does not require any mechanical impact on the patient’s body. Thus, a technical result is achieved in the form of improving the usability and reliability of the implantable sphincter.

Claims (12)

1. Urethral magnetically controlled sphincter containing a cuff, a reservoir interconnected by connecting means, and the fluid with which they are filled, the reservoir being made with deformable walls, characterized in that it contains a control element configured to create a magnetic field, and the filling fluid is ferrofluid, while the walls of the tank are made with the possibility of elastic stretching when exposed to a control element at least to sizes that provide reduced The pressure in the cuff is lower than the pressure of the closure of the urethra. 2. Urethral magnetically controlled sphincter according to claim 1, characterized in that the connecting means are at least two tubes, at least one of the tubes is made with a one-way valve, which ensures the creation of a unidirectional flow from the cuff to the reservoir, and at least one the tube does not contain a valve, and the total cross-section of tubes without valves is less than the total cross-section of tubes with valves. 3. Urethral magnetically controlled sphincter according to claim 2, characterized in that the tubes that do not contain valves are configured to allow ferrofluid to flow from the reservoir into the cuff 2-3 minutes after the magnetic field is removed, after which the cuff pressure is higher than the overlap pressure urethra. 4. Urethral magnetically controlled sphincter according to claim 1 or 2, characterized in that a permanent magnet is used as a control element, made with the possibility of approaching and moving away from the reservoir. 5. The urethral magnetically controlled sphincter according to claim 4, characterized in that a neodymium magnet is used as a permanent magnet. 6. The urethral magnetically controlled sphincter according to claim 4, characterized in that an electromagnet is used as a control element. 7. Urethral magnetically controlled sphincter according to claim 6, characterized in that the electromagnet is made with the possibility of approaching and moving away from the reservoir. 8. The urethral magnetically controlled sphincter according to claim 6, characterized in that the electromagnet is configured to smoothly decrease or increase the magnetic field. 9. The urethral magnetically controlled sphincter according to claim 6, characterized in that the electromagnet is configured to programmably change the magnetic field. 10. Urethral magnetically controlled sphincter according to claim 1 or 2, characterized in that the elements of the device are made of silicone. 11. The urethral magnetically controlled sphincter according to claim 1 or 2, characterized in that the tubes are made flexible. 12. Urethral magnetically controlled sphincter according to claim 1 or 2, characterized in that the reservoir is made with varying degrees of wall stiffness, the wall facing the bladder after implantation is made to stretch, and the other walls are made without stretching.

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