RU2108765C1 - Device to be implanted in vessels and hollow organs - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: device has a set of arrow-shaped cell rows obeying some relationship existing among cell angles and sides to enable device diameter to be changed without its length changed. EFFECT: full correspondence to geometric properties of vessels and hollow organs. 4 cl, 9 dwg

Description

 The invention relates to medical equipment, and more specifically to a device for implantation in vessels and hollow organs.

Various diseases of blood vessels and hollow organs cause
narrowing or complete obstruction (occlusion) of their lumen;
expansion of their clearance;
the presence of pathological messages, etc.,
which leads to a decrease or complete loss of their functional properties.

 The problem of creating such devices has existed for a long time. Nevertheless, to date, not created a universal reliable device that meets all the necessary requirements.

For example, a device for implantation in vessels and hollow organs in case of narrowing or complete obstruction (occlusion) of their lumen should satisfy the following requirements:
effective performance of the function of restoring and maintaining the lumen of blood vessels and hollow organs;
the possibility of using in a wide range of sizes 2 - 50 mm or more in diameter and any length;
reliability and ease of management of the delivery system;
the possibility of using in various anatomical zones of blood vessels and hollow organs;
the ability to cause minimal trauma during and after surgery;
the possibility of biological compatibility with body tissues, structural rigidity to provide resistance to external compressive forces;
high radiopacity required during implantation under the control of X-ray television (necessary by the method of operation).

 A device for implantation in vessels and hollow organs of a knitted structure, for example, to maintain the lumen of blood vessels and hollow organs in case of their narrowing or complete obstruction, is a cylindrical shape made of tantalum or nitinol [1].

 The device has a fairly reliable and easy-to-manage delivery system, has biocompatibility, high X-ray contrast and causes minimal trauma during and after surgery, however, due to the lack of rigidity of the structure, the ability to perform the function of restoring and maintaining the lumen of blood vessels and genitals is sharply reduced. In addition, due to the limited range of sizes, their application areas are sharply narrowed.

 A device for implantation in vessels and hollow organs, for example, to maintain the lumen of blood vessels and hollow organs in case of narrowing or obstruction, a knitted structure of a cylindrical shape from nitinol [2].

 The device has a structural rigidity and a highly efficient function of restoring and maintaining the lumen of blood vessels and hollow organs, high radiopacity, biological compatibility. However, this device has a limited size range, a traumatic, large-sized delivery system and an ultra-rigid design, which sharply limits its scope.

 The objective of the invention is to provide such a device for implantation in vessels and hollow organs of a knitted structure, for example, to maintain the lumen of blood vessels and hollow organs in case of narrowing or obstruction, which would satisfy the above requirements (Fig. 9).

 The problem is solved in that the device for implantation in the vessels and hollow organs, which is a rotational body of a cylindrical or conical shape of a knitted structure from a material with "shape memory", is formed by many rows of arrow-shaped cells with a certain relationship between the corners and sides, allowing you to change the diameter of the device without changing its length, each of which is connected to adjacent ones by means of one-piece units and is a rigidly closed functional element, with neighboring cells in one th diametrical row are mirror image (FIGS. 1 and 7).

 It is possible that the device for implantation in vessels and hollow organs, which is a rotational body of a cylindrical or conical shape of a knitted structure made of a material with "shape memory", is formed by many rows of arrow-shaped cells with a certain relationship between the corners and sides, allowing you to change the diameter of the device without changes in its length, each of which is connected to neighboring ones by means of elastic twists and is a closed functional element, and neighboring cells in one diametrical Poison are mirror image (FIG. 2, 6.8).

 Each vertex / angle α β represents a fastening (one-piece) unit 1 formed by rigidly intertwined one-piece nodes (Fig. 5) and elastic twists (Fig. 3).

 Such a constructive implementation of the device for implantation in vessels or hollow organs, for example, to maintain the lumen of blood vessels or hollow organs in case of their narrowing or obturation, provides structural rigidity in the radial direction under the action of external compressive forces due to the presence of rigidly closed functional cell elements, rigidly interconnected. This also ensures complete restoration of the shape and size of the device during implantation and the effective performance of the desired functions by the device.

 These same design features make it possible to manufacture and use the device in any range of their types-sizes from 2 mm to 50 mm or more in diameter and any length, depending on the aspect ratio and angles, where b = 2.1a; β = 2,6α and also be applicable in various anatomical zones of blood vessels and hollow organs, have a minimal in size and reliable, easy-to-manage delivery system, causing minimal trauma during and after surgery. The latter can be achieved due to the presence of an inelastic cover fixed on the ends of the device inside and out. The possibility of knitting only with a single continuous thread (wire) without physico-chemical-electrochemical compounds ensures biological inertness and biological compatibility of the device with body tissues.

 The use of rigidly or elastically interconnected closed functional elements-cells makes it possible to widely vary the axial and radial stiffness of the structure by changing the cross section of the thread (wire) for knitting, without exceeding the maximum permissible deformation of its material, as well as the number of axial rows of cells.

 The above-described design features of the device allow it to be implemented with a rigid connection of the cells with each other, which increases reliability and increases its service life, or with elastic, which increases the degree of deformation of the thread and, therefore, reduces the size of the delivery device. Such designs allow the latter to better adapt to the geometry of the vessel or hollow organ.

 The operation of the device for implantation in vessels and hollow organs, for example, to maintain the lumen of blood vessels and hollow organs in case of narrowing and obstruction, is as follows.

 The device using a special device (not shown) is crimped and placed in a radiopaque hollow tube (not shown). The radiopaque hollow tube with the device placed in it is delivered to the site of the proposed implantation and is pushed out of the radiopaque tube using a special pusher (not shown).

 The restoration of the original form occurs sequentially by forming in the plane perpendicular to the axis of the device a closed ring-shaped contour. The latter interacts with the walls of, for example, arteries, keeping the lumen unchanged and repeating its geometry due to the maximum radial stiffness and optimal axial stiffness of the device.

Claims (3)

 A device for implantation in vessels and hollow organs, which is a rotational body of a cylindrical or conical shape of a knitted structure from a material with "shape memory", characterized in that it is formed by many rows of arrow-shaped cells with a certain relationship between the corners and sides, allowing you to change the diameter of the device without changing its length, each of which is connected to adjacent by one-piece nodes and is a rigidly closed functional element, and neighboring cells in the same diameter The main row is a mirror image.  2. A device for implantation in vessels and hollow organs, which is a rotational body of a cylindrical or conical shape of a knitted structure from a material with "shape memory", characterized in that it is formed by many rows of arrow-shaped cells with a certain relationship between the angles and sides, allowing you to change the diameter of the device without changing its length, each of which is connected to neighboring by means of elastic twists and is a closed functional element, and neighboring cells in one diametrically m row are a mirror image. 3. The device according to claims 1 and 2, characterized in that the aspect ratio is equal to b = 2,1a; β = 2.6α.
4. The device according to paragraphs. 1 to 3, characterized in that it is equipped with a thin inelastic cover fixed on the ends of the device both inside and outside.

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