Abstract: The stent has an expansive force 0.05 N/mm or less per unit length when it has a diameter equal to the lower limit diameter of the target blood vessel and is measured under the following conditions. A radial force testing system manufactured by Blockwise Engineering LLC is used as a tester. The test conditions include a temperature of 37° C.±2° C. in the chamber of the tester; a stent diameter of 0.5 mm for start of test, and a rate of increase of diameter of 0.5 mm/s in the tester. The test method includes radially compressing the stent disposed in the chamber; recording an expansive force while gradually increasing the diameter of the chamber at the rate of increase of diameter; and dividing the expansive force by the effective length of the stent to calculate an expansive force per unit length.

Abstract: A stent includes wavy-line pattern bodies having a wavy-line pattern and arranged side-by-side in an axial direction LD, and coiled elements arranged between the wavy-line pattern bodies adjacent and extending in a spiral manner around an axis. All apices on opposite sides of the wavy-line pattern of the wavy-line pattern bodies that are adjacent are connected by way of the coiled element. When viewing in a radial direction RD, a circular direction CD of the wavy-line pattern bodies is inclined with respect to the radial direction RD, and a winding direction of one of the coiled elements located at one side in the axial direction LD with respect to the wavy-line pattern bodies and a winding direction of one other of the coiled elements located at the other side in the axial direction LD are opposite.

Abstract: A stent 1 which is inserted into a catheter and extruded from the catheter into a blood vessel to dilate a blood vessel, wherein the stent is equipped with a first stent body 10 in which a plurality of first cells comprising struts arranged in a frame shape are spread in the circumferential direction and are contiguous in the central axial direction and a second stent body 20, interpolated into the first stent body, in which a plurality of second cells comprising struts arranged in a frame shape are spread in the circumferential direction and are contiguous in the central axial direction, and, in a state in which the second stent body 20 is interpolated into the first stent body 10, the intersecting portions of the second cells are arranged in the hole portions of the first cells and the first stent body 10 and the second stent body 20 are not connected to each other in the radial direction.

Abstract: A stent 10 includes corrugated pattern bodies 11 and connection elements 12. A corrugated pattern is formed of corrugated units 14, corrugated unit 14 including a first stem 15, a second stem 16, a third stem 17, a first top portion 18 coupling a first end portion 15a of the first stem 15 and a first end portion 16a of the second stem 16, and a second top portion 19 coupling a second end portion 16b of the second stem 16 and a first end portion 17a of the third stem 17. A second end portion 17b of the third stem 17 is connected to a second end portion 15b of the first stem 15 in another corrugated unit adjacent to corrugated unit. A first end portion 12a of connection element 12 is connected to the first top portion 18 of one of adjacent ones of the corrugated units 14, and a second end portion 12b of connection element 12 is connected to the second end portion 15b of the other one of the adjacent ones of the corrugated units 14.

Abstract: A stent 10 includes corrugated pattern bodies 11 and connection elements 12. A corrugated pattern is formed of corrugated units 14, corrugated unit 14 including a first stem 15, a second stem 16, a third stem 17, a first top portion 18 coupling a first end portion 15a of the first stem 15 and a first end portion 16a of the second stem 16, and a second top portion 19 coupling a second end portion 16b of the second stem 16 and a first end portion 17a of the third stem 17. A second end portion 17b of the third stem 17 is connected to a second end portion 15b of the first stem 15 in another corrugated unit adjacent to corrugated unit. A first end portion 12a of connection element 12 is connected to the first top portion 18 of one of adjacent ones of the corrugated units 14, and a second end portion 12b of connection element 12 is connected to the second end portion 15b of the other one of the adjacent ones of the corrugated units 14.

Abstract: A stent 10 includes corrugated pattern bodies 11 and connection elements 12. A corrugated pattern is formed of corrugated units 14, corrugated unit 14 including a first stem 15, a second stem 16, a third stem 17, a first top portion 18 coupling a first end portion 15a of the first stem 15 and a first end portion 16a of the second stem 16, and a second top portion 19 coupling a second end portion 16b of the second stem 16 and a first end portion 17a of the third stem 17. A second end portion 17b of the third stem 17 is connected to a second end portion 15b of the first stem 15 in another corrugated unit adjacent to corrugated unit. A first end portion 12a of connection element 12 is connected to the first top portion 18 of one of adjacent ones of the corrugated units 14, and a second end portion 12b of connection element 12 is connected to the second end portion 15b of the other one of the adjacent ones of the corrugated units 14.

Abstract: Provided is a flexible stent with which it is possible to further improve visibility of an impermeable member which is disposed upon a stent and to further improve operability of the stent. Provided is a flexible stent 11, comprising: a plurality of ring-shaped pattern bodies 13 which have a wavy line-shaped pattern and are positioned side by side in an axial direction LD; and a plurality of connecting elements 15 which connect the adjacent ring-shaped pattern bodies 13. When viewed in a radial direction RD which is perpendicular to the axial direction LD, a ring direction CD of the ring-shaped pattern bodies 13 is or is not oblique with respect to the radial direction RD. A plurality of impermeable members 31 which are highly impermeable to radiation are disposed upon and/or positioned in proximity to struts which configure the ring-shaped pattern bodies 13 and/or the connecting elements 15.

Abstract: The stent has an expansive force 0.05 N/mm or less per unit length when it has a diameter equal to the lower limit diameter of the target blood vessel and is measured under the following conditions. A radial force testing system manufactured by Blockwise Engineering LLC is used as a tester. The test conditions include a temperature of 37° C.±2° C. in the chamber of the tester; a stent diameter of 0.5 mm for start of test, and a rate of increase of diameter of 0.5 mm/s in the tester. The test method includes radially compressing the stent disposed in the chamber; recording an expansive force while gradually increasing the diameter of the chamber at the rate of increase of diameter; and dividing the expansive force by the effective length of the stent to calculate an expansive force per unit length.

Abstract: A stent includes wavy-line pattern bodies having a wavy-line pattern and arranged side-by-side in an axial direction LD, and coiled elements arranged between the wavy-line pattern bodies adjacent and extending in a spiral manner around an axis. All apices on opposite sides of the wavy-line pattern of the wavy-line pattern bodies that are adjacent are connected by way of the coiled element. When viewing in a radial direction RD, a circular direction CD of the wavy-line pattern bodies is inclined with respect to the radial direction RD, and a winding direction of one of the coiled elements located at one side in the axial direction LD with respect to the wavy-line pattern bodies and a winding direction of one other of the coiled elements located at the other side in the axial direction LD are opposite.

Abstract: Provided is a flexible stent in which a free end strut does not tend to project outside when the stent is bent and shortening can be suppressed at the time of expansion of the stent. The flexible stent includes annular bodies having a wavy line pattern and connection elements that connect the annular bodies. The wavy line pattern is formed by V-shaped elements, in which two leg parts are joined by an apex part, being connected in a state where the apex parts alternately face opposite directions in an axial direction. A bending direction of one end part of the connection element and a bending direction of another end part thereof are opposite to one another. The end part of the connection element is connected to a portion other than the apex part of the V-shaped element of the adjacent annular body with the end part of the connection element being extended in a direction different from the direction in which the leg part extends.

Abstract: Provided is a flexible stent with which it is possible to further improve visibility of an impermeable member which is disposed upon a stent and to further improve operability of the stent. Provided is a flexible stent 11, comprising: a plurality of ring-shaped pattern bodies 13 which have a wavy line-shaped pattern and are positioned side by side in an axial direction LD; and a plurality of connecting elements 15 which connect the adjacent ring-shaped pattern bodies 13. When viewed in a radial direction RD which is perpendicular to the axial direction LD, a ring direction CD of the ring-shaped pattern bodies 13 is or is not oblique with respect to the radial direction RD. A plurality of impermeable members 31 which are highly impermeable to radiation are disposed upon and/or positioned in proximity to struts which configure the ring-shaped pattern bodies 13 and/or the connecting elements 15.

Abstract: A stent includes wavy-line pattern bodies having a wavy-line pattern and arranged side-by-side in an axial direction LD, and coiled elements arranged between the wavy-line pattern bodies adjacent and extending in a spiral manner around an axis. All apices on opposite sides of the wavy-line pattern of the wavy-line pattern bodies that are adjacent are connected by way of the coiled element. When viewing in a radial direction RD, a circular direction CD of the wavy-line pattern bodies is inclined with respect to the radial direction RD, and a winding direction of one of the coiled elements located at one side in the axial direction LD with respect to the wavy-line pattern bodies and a winding direction of one other of the coiled elements located at the other side in the axial direction LD are opposite.

Abstract: Provided is a flexible stent in which a free end strut does not tend to project outside when the stent is bent and shortening can be suppressed at the time of expansion of the stent. The flexible stent includes annular bodies having a wavy line pattern and connection elements that connect the annular bodies. The wavy line pattern is formed by V-shaped elements, in which two leg parts are joined by an apex part, being connected in a state where the apex parts alternately face opposite directions in an axial direction. A bending direction of one end part of the connection element and a bending direction of another end part thereof are opposite to one another. The end part of the connection element is connected to a portion other than the apex part of the V-shaped element of the adjacent annular body with the end part of the connection element being extended in a direction different from the direction in which the leg part extends.

Abstract: A stent includes: wavy-line pattern bodies having a wavy-line pattern and arranged side-by-side in an axial direction; and coiled elements arranged between the wavy-line pattern bodies adjacent and extending in a spiral manner around an axis, in which all apices on opposite sides of the wavy-line pattern of the wavy-line pattern bodies that are adjacent are connected by way of the coiled element. When viewing in a radial direction, a circular direction-of the wavy-line pattern bodies is inclined with respect to the radial direction, and a winding direction of one of the coiled elements located at one side in the axial direction with respect to the wavy-line pattern bodies and a winding direction of one other of the coiled elements located at the other side in the axial direction are opposite.

Abstract: A stent 11 includes: wavy-line pattern bodies 13 having a wavy-line pattern and arranged side-by-side in an axial direction LD; and coiled elements 5 arranged between the wavy-line pattern bodies 13 adjacent and extending in a spiral manner around an axis, in which all apices 17 on opposite sides of the wavy-line pattern of the wavy-line pattern bodies 13 that are adjacent are connected by way of the coiled element 15. When viewing in a radial direction RD, a circular direction CD of the wavy-line pattern bodies 13 is inclined with respect to the radial direction RD, and a winding direction of one of the coiled elements 15R located at one side in the axial direction LD with respect to the wavy-line pattern bodies 13 and a winding direction of one other of the coiled elements 15L located at the other side in the axial direction LD are opposite.

Abstract: A stent has circular bodies having a wavy-line pattern and arranged side-by-side and coiled elements 15 arranged between the circular bodies that are adjacent and extending in a spiral manner, and apices on opposite sides of the wavy-line pattern of the circular bodies that are adjacent are connected by way of the coiled elements 15. A knob portion 19 is formed at each apex of the wavy-line pattern, and the knob portion 19 includes an extension portion 19a extending in the axis direction and a semicircle portion 19b formed at a tip of the extension portion, and the coiled element 15 is connected with the knob portion 19. A slit is formed at a part of the extension portion 19a of the knob portion 19, and the slit 21 extends in the axis direction from an inner peripheral portion at the apex of the wavy-line pattern of the circular body.

Abstract: A stent has circular bodies having a wavy-line pattern and arranged side-by-side and coiled elements 15 arranged between the circular bodies that are adjacent and extending in a spiral manner, and apices on opposite sides of the wavy-line pattern of the circular bodies that are adjacent are connected by way of the coiled elements 15. A knob portion 19 is formed at each apex of the wavy-line pattern, and the knob portion 19 includes an extension portion 19a extending in the axis direction and a semicircle portion 19b formed at a tip of the extension portion, and the coiled element 15 is connected with the knob portion 19. A slit is formed at a part of the extension portion 19a of the knob portion 19, and the slit 21 extends in the axis direction from an inner peripheral portion at the apex of the wavy-line pattern of the circular body.

Abstract: Provided is a stent to be inserted into an in vivo organ having a tubular structure that allows a degree of freedom in design and excellent mechanical flexibility. A cylinder-shaped stent is inserted to be placed and used in the inner cavity of an in vivo tubular organ, wherein: the wall of the stent has a planar mesh pattern filled with a plurality of closed cells being adjacent to each other and having congruent shapes; the closed cells have point-symmetric parallel hexagonal shapes; all closed cells circumferentially adjacent to each other are congruent and similar in shape; two closed cells adjacent to each other sharing different sides form a substantially V-shaped member; and the vertex of each folded part in the substantially V-shaped member points to the circumferential direction.

Abstract: Provided is a stent to be inserted into an in vivo organ having a tubular structure that allows a degree of freedom in design and excellent mechanical flexibility. A cylinder-shaped stent is inserted to be placed and used in the inner cavity of an in vivo tubular organ, wherein: the wall of the stent has a planar mesh pattern filled with a plurality of closed cells being adjacent to each other and having congruent shapes; the closed cells have point-symmetric parallel hexagonal shapes; all closed cells circumferentially adjacent to each other are congruent and similar in shape; two closed cells adjacent to each other sharing different sides form a substantially V-shaped member; and the vertex of each folded part in the substantially V-shaped member points to the circumferential direction.