JP7480492B2 - Suction type stabilizer - Google Patents

Description

The present invention relates to an adsorption type stabilizer, and more particularly to an adsorption type stabilizer used in coronary artery bypass surgery.

Methods for treating coronary artery disease include percutaneous transluminal coronary angioplasty, which involves placing a stent in the coronary artery to dilate the blood vessels without using a heart-lung machine, and coronary artery bypass surgery, which involves anastomosis of bypass blood vessels.
During coronary artery bypass surgery, a heart positioner is sometimes used to suction and lift the heart in order to unfold the back side of the heart.
Furthermore, in addition to heart positioners, which require suction power strong enough to lift the heart, suction stabilizers are sometimes used to enable the bypass blood vessels to be anastomosed to the coronary arteries while the heart is moving (pulsating).
The suction stabilizer is a device that suppresses the pulsation of the surface of the heart while maintaining the heartbeat in order to make it easier to connect a bypass blood vessel to the anastomosis site.

For example, Patent Document 1 describes an adsorption-type stabilizer (referred to in the document as a suction device) equipped with a holding member (referred to in the document as a paddle) that holds the heart in a state that suppresses heartbeat.
The holding member is formed with a plurality of suction portions (referred to as suction ports in the same document) which are connected to a suction source and subjected to negative pressure suction to come into close contact with the heart and suppress its movement.

International Publication No. WO 1997/010753

However, in the suction-type stabilizer described in Patent Document 1, the part of the suction part that comes into contact with the heart needs to have a certain degree of hardness in order to suppress the pulsation of the heart, and this hardness causes a large impact load to be applied to that part due to the pulsation of the heart. For this reason, there is still room for improvement in terms of more optimally maintaining the state of adhesion to the heart by the suction part of the holding member.

The present invention was made in consideration of the above problems, and provides an adsorption-type stabilizer that can optimally maintain the adsorption capacity of the adsorption part.

An adhesive stabilizer that stabilizes the periphery of an anastomosis target connected to a bypass blood vessel in a coronary artery by adhering to the heart, which is an adhesive target, through negative pressure suction from a suction source and suppressing the pulsation of the heart, and is equipped with an adhesive part that is attached so that its contact surface contacts the periphery of the anastomosis target, an air intake path from the suction source is connected, and an adhesive part that is softer than the adhesive part, is connected to the adhesive part, and adheres closely to the periphery of the anastomosis target, and a recess is formed in the adhesive part to which the air intake path from the suction source is connected to form a negative pressure space, and the adhesive part is provided on the edge of the adhesive part and is flush with the contact surface of the adhesive part or extends downward beyond the contact surface to the side of the adhesive target.

According to the present invention, the suction portion of the holding member can more effectively maintain the suction state on the heart.

FIG. 1 is a schematic diagram showing the overall configuration of an adsorption type stabilizer connected to a suction source according to an embodiment of the present invention. FIG. FIG. FIG. 5 is a cross-sectional view of the holding member taken along line V-V in FIG. 4 . 6 is a cross-sectional view of the holding member taken along line VI-VI in FIG. 3. FIG. FIG. 13 is a diagram showing a holding member according to a first modified example, and is a partial cross-sectional view showing a part of the holding member in cross-section. FIG. 11 is an enlarged cross-sectional view showing a cross section of a part of an adsorption portion according to a second modified example. FIG. 11 is an enlarged cross-sectional view showing a cross section of a part of an adsorption portion according to a third modified example.

The following describes an embodiment of the present invention with reference to the drawings. Note that the embodiment described below is merely an example to facilitate understanding of the present invention, and does not limit the present invention. In other words, the shape, dimensions, arrangement, etc. of the components described below may be modified or improved without departing from the spirit of the present invention, and the present invention naturally includes equivalents.

Furthermore, the various components of the present invention do not need to exist independently, and it is permitted that multiple components are configured as a single component, that one component is divided into multiple components, that one component is a part of another component, that part of one component overlaps with part of another component, etc.
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In all the drawings, the same components are denoted by the same reference numerals, and the description thereof will be omitted as appropriate.

＜Overview＞
First, an outline of an suction type stabilizer 1 according to this embodiment will be described with reference to FIGS. 1 to 6 (mainly FIGS. 5 and 6).
Fig. 1 is a schematic diagram showing the overall configuration of an adsorption type stabilizer 1 connected to a suction source 2 according to an embodiment of the present invention. Fig. 2 is an upper perspective view showing a holding member 4, Fig. 3 is a side view showing the holding member 4, and Fig. 4 is a bottom view of the holding member 4. Fig. 5 is a diagram showing a cross section of the holding member 4, which is a cross section taken along line VV in Fig. 4, and Fig. 6 is a diagram showing a cross section of the holding member 4, which is a cross section taken along line VI-VI in Fig. 3.

The suction-type stabilizer 1 of this embodiment is attached to the heart, which is the object to be suctioned, by using negative pressure suction from a suction source 2, and by suppressing the pulsation of the heart, stabilizes the area around the anastomosis object connected to the bypass blood vessel in the coronary artery.
The suction-type stabilizer 1 is a part that is attached so that the contact surface 4ad is in contact with the periphery of the anastomosis target part, and is connected to an intake path 3 from a suction source 2. The suction-type stabilizer 1 is equipped with an suction part 4a that suppresses pulsation, and an adhesion part 4ea that is softer than the suction part 4a, is connected to the suction part 4a, and adheres closely to the periphery of the anastomosis target part.

The suction portion 4a has a recess 4aa formed therein, to which the intake passage 3 from the suction source 2 is connected to form a negative pressure space.
The adhesion portion 4ea is provided on the edge portion of the suction portion 4a (the outer peripheral edge 4ae of the abutment surface 4ad) and is characterized in that it is flush with the abutment surface 4ad of the suction portion 4a or extends downward beyond the abutment surface 4ad, toward the object to be adsorbed.
The "edge portion of the suction portion 4a" as the portion where the contact portion 4ea is provided is not limited to the outer peripheral edge 4ae on the outer periphery of the contact surface 4ad of the suction portion 4a shown in Fig. 6. For example, the portion where the contact portion 4ea is provided may be an inner peripheral edge 34ae on the inner side of the contact surface 4ad of the suction portion 34a, as shown in Fig. 8 and described later.

According to the above configuration, even if the edge portion (outer peripheral edge 4ae) of the suction portion 4a becomes separated from the heart due to the pulsation of the heart, the presence of the contact portion 4ea can prevent the negative pressure state between the heart and the suction portion 4a from being released.
In addition, the above-mentioned phrase "the adhesive portion 4ea is provided on the edge portion of the suction portion 4a" means that the adhesive portion 4ea is provided on "at least" the edge portion of the suction portion 4a. In this embodiment, as shown in Fig. 2, the adhesive portion 4ea may be a part of a cover 4e formed to cover the upper surface side of the suction portion 4a.

<Overall composition>
As shown in FIG. 1, the suction-type stabilizer 1 comprises a joint member 1a connected to a stand (not shown), an arm portion 1b connected to the joint member 1a and having flexibility and shape retention, and a holding member 4 connected to the arm portion 1b and in contact with the heart to suppress its pulsation.

<Components>
Next, the configuration of each part of the suction type stabilizer 1 will be described.
As shown in Figure 2, the holding member 4 in this embodiment includes a pair of suction portions 4a that are connected to the intake passage 3 and suction-adsorb the heart, a generally U-shaped base portion 4b that connects the base ends of the pair of suction portions 4a, a connecting member 4f, and a connection portion 4bc, and a pair of covers 4e that cover the upper surface and side surfaces of each of the pair of suction portions 4a.

[About the intake passage]
The intake passage 3 is formed by a flexible tube 3c connected to the suction source 2 shown in FIG. 1 and air vents 3d, 3e (see FIG. 5) provided in the holding member 4 connected to the flexible tube 3c, and is connected to the recess 4aa.
More specifically, in the holding member 4 (base portion 4b), the flexible tube 3c is connected to one connector portion 4ba provided at the proximal end portion of one of the suction portions 4a.

As shown in FIG. 5, the connector portion 4ba is provided with an insertion port 4bb at the proximal end into which the flexible tube 3c is inserted, and an air hole 3d at the distal end, which are in communication with each other.
The ventilation hole 3d communicates with the ventilation hole 3e of the connection part 4bc provided on the other suction part 4a through the hollow part of the connecting member 4f.

The holding member 4 also includes a connecting member 4f connected to the pair of suction portions 4a via connecting portions 4bc.
When negative pressure suction force is applied from the suction source 2, the recess 4aa of one of the suction portions 4a, which is directly connected to the flexible tube 3c via the connector portion 4ba, can be made negative pressure, and the recess 4aa of the other suction portion 4a can also be made negative pressure via the connecting member 4f.

[About the base]
The base portion 4b is located at the proximal end of the holding member 4, and is connected to the arm portion 1b, and is a portion to which the flexible tube 3c to which the negative suction force is supplied is connected. The base portion 4b has a connecting portion 4bd for connecting the pair of suction portions 4a.
A connecting member 4f is connected to the distal side of the connecting portion 4bd, and a pair of suction portions 4a are connected to the distal sides of both widthwise sides of the connecting member 4f via a pair of connecting portions 4bc.
The pair of connecting portions 4bc extend distally from both sides of the connecting member 4f in the width direction. The connecting portions 4bc are located distal to the portion to which the connecting member 4f is connected, and are formed such that the width and the height of the upper surface decrease toward the distal side, as shown in Figures 2 and 3.

[About the suction part]
As shown in FIG. 5, the suction portion 4a includes a main body portion 4ac and a recess 4aa that is provided in the main body portion 4ac and forms part of the intake passage 3. In this embodiment, a pair of suction portions 4a are provided on either side of the treatment space OS shown in FIG. 4.
In addition, the suction portions 4a need only be arranged so that at least one part is separated from the other part to form the treatment space OS, and are not limited to being arranged in pairs, but may be formed continuously in, for example, a U-shape or O-shape.
The recess 4aa is a space that is elongated in the far-to-near direction along the main body 4ac that is open on the suction surface side.

6, at least a part of a core material 6 (described later) is embedded in the upper part of the pair of suction parts 4a of the holding member 4. Specifically, at least a part of the core material 6 is accommodated in an accommodation part 4d, which is a long hole in the thick part of the upper part of the suction part 4a.
For example, the flexible tube 3c and the main body 4ac of the adsorption part 4a are made of a soft resin that is softer than the base part 4b, and have flexibility. The flexible tube 3c is bendable more flexibly than the main body 4ac.

As shown in Figures 2 and 6, on the upper surface of the suction portion 4a, a protrusion 4g having an arc-shaped outer edge in cross section and protruding upward is formed so as to extend in the near-far direction along the core material 6 described later.
This protrusion 4g is intended to make the main body 4ac thick so that the suction portion 4a can be stably embedded within the main body 4ac, and also has the function of suppressing misalignment with the cover 4e, which is attached so as to cover the main body 4ac from above, as described later.
5, the suction portion 4a includes a soft member (main body portion 4ac) that covers at least a part of the core material 6. The soft member is made of a material that is less rigid than the core material 6.

[About the core material]
As shown in Fig. 5, the suction-type stabilizer 1 further includes a core material 6 that is harder than the suction part 4a, can be bent to fit the heart (not shown), and can maintain its shape, and that maintains the shape of the suction part 4a. The core material 6 is for suppressing the pulsation of the heart, and as shown in Fig. 6, a part of the core material 6 is embedded inside the thick part (main body part 4ac) of the suction part 4a.
More specifically, since the suction portion 4a is formed from a material softer than the core material 6, when the core material 6 is deformed so as to be curved and retains its shape, the suction portion 4a, which has the core material 6 embedded therein, deforms in accordance with the deformation of the core material 6 and retains its shape.

In particular, if a part of the core material 6 made of a material harder than the main body portion 4ac, for example a metal material, is embedded in the main body portion 4ac and its exposure to the lower side, which is the suction side, is limited, it is possible to prevent bodily fluids and the like that enter the recessed portion 4aa from coming into contact with the core material 6. This makes it possible to suppress deterioration of the core material 6.

As shown in FIG. 5, at least a portion of the core material 6 is embedded in the main body portion 4ac and is provided at a position overlapping the recessed portion 4aa in the suction direction.
According to the above configuration, at least a part of the core material 6 is embedded in the main body portion 4ac and is provided at a position overlapping the recess 4aa in the suction direction, so that the suction portion 4a (main body portion 4ac) can be prevented from becoming bulky. This makes it possible to increase the working space during treatment and improve treatment efficiency.

In particular, the suction portion 4a is formed long and aligned along the central axis CL shown in Figure 2, and the core material 6 is arranged on the side away from the treatment space OS (see Figure 4) relative to the central axis CL (in other words, so that, in a planar view, the central axis of the core material 6 is positioned outward relative to the central axis CL).
As shown in FIG. 6, the holding member 4 needs to be thick enough to allow the core material 6 to be embedded therein, and the height of the portion where the core material 6 is embedded becomes large.
According to the above configuration, the core material 6 is arranged on the side away from the treatment space OS relative to the central axis CL of the suction portion 4a, so that the portion close to the treatment space OS can be made thinner and the height reduced, thereby preventing it from becoming an obstacle to treatment.

In this embodiment, the intake passage 3 is formed in a soft member (main body 4ac) separate from the core material 6. With this configuration, it is not necessary to make the core material 6 a part of the intake passage 3, and the core material 6 can be formed in a rod shape rather than a cylindrical shape. As a result, the core material 6 can be made relatively small in diameter, and the holding member 4 including the core material 6 can be made thin in the vertical direction (the suction direction).
As described above, it is preferable that the core material 6 according to this embodiment is solid, but it is not limited to this form and may be a cylindrical material having a hollow space.

[About the cover (contact part)]
As described above, the pair of covers 4e according to this embodiment are provided so as to cover the upper surfaces and side peripheral surfaces of the pair of suction portions 4a.
The cover 4e includes a covering portion 4ec that covers the suction portion 4a, and a contact portion 4ea that is formed in a flange shape at the lower end of the covering portion 4ec.
As shown in Fig. 2, a through hole 4ed is formed at the proximal and upper end of the cover part 4ec. This through hole 4ed is for passing the suction part 4a from the distal end to the proximal end when the cover 4e is attached to the suction part 4a, and since the cover 4e is made of a soft material, it can be expanded to allow the suction part 4a to pass through. The upper edge of the through hole 4ed is formed in a shape (arc shape) that follows the distal end of the connection part 4bc in a plan view.
The contact portion 4ea is a portion that comes into contact with the heart when the suction portion 4a is brought into contact with the heart and the recess 4aa is made negative pressure by the suction source 2.

As shown in FIG. 6 and other figures, the contact portion 4ea according to this embodiment extends downward beyond the contact surface 4ad of the suction portion 4a, toward the object to be suctioned.
6, and corresponds to the downward position in a normal procedure in which the holding member 4 is applied from above to the subject's heart, which is the object of suction. In a rare example, when the holding member 4 is applied laterally to the subject's heart, the contact portion 4ea may extend laterally beyond the contact surface 4ad.

According to the above configuration, even when the contact surface 4ad moves away from the heart (jumping upward) due to the beating of the heart, the contact portion 4ea extends downward from the contact surface 4ad, making it easier to maintain contact between the contact portion 4ea and the heart. This makes it easier to maintain a negative pressure state between the suction portion 4a and the heart.

As shown in FIG. 4, the contact portion 4ea is formed so as to surround the outer circumferential edge 4ae of the contact surface 4ad of the suction portion 4a.
More specifically, when viewed from the bottom as shown in Figure 4, the adhesion portion 4ea is formed so as to surround the entire outer edge 4ae (the lower edge of the peripheral surface of the suction portion 4a) of the abutment surface 4ad of the suction portion 4a from the outside, relative to the inside where the recess 4aa is located.

With the above configuration, the adhesive portion 4ea surrounds the outer peripheral edge 4ae of the suction portion 4a, making it easier to attach and arrange the adhesive portion 4ea (cover 4e) to the suction portion 4a than if it were arranged along the inner peripheral edge side.

The contact portion 4ea is formed so as to extend downward from the edge of the contact surface 4ad of the suction portion 4a toward the suction target, and to widen toward the bottom.
According to the above configuration, the contact portion 4ea extends downward from the edge (outer peripheral edge 4ae) of the contact surface 4ad of the suction portion 4a and is formed in a fan-shaped manner, thereby making it possible to maintain the contact of the contact surface of the suction portion 4a with the heart.
Furthermore, even when the suction portion 4a is somewhat separated from the heart, the contact portion 4ea can be kept in contact with the heart, making it easier to maintain a negative pressure state in the region including the recess 4aa.

In addition, the thickness of the contact portion 4ea according to this embodiment is formed to be thinner than the thickness of the cover portion 4ec that covers the side surface of the main body portion 4ac of the suction portion 4a, as shown in Fig. 6. Here, the "thickness" refers to the thickness in a direction perpendicular to each surface that defines the recess 4aa.
With this configuration, the moment of inertia of the contact part 4ea can be reduced, and the rigidity can be reduced, so that the contact part 4ea can deform appropriately to the side that contacts the heart when the inside of the recess 4aa is evacuated, and the contact area between the contact part 4ea and the heart can be increased, making it easier to prevent the vacuum from being broken.

Furthermore, the contact portion 4ea may be formed so as to become thinner toward the end of the contact portion 4ea. With such a configuration, the moment of inertia of the contact portion 4ea can be further reduced, and the rigidity can be lowered. Therefore, when a vacuum is drawn inside the recess 4aa, the contact portion 4ea can be deformed more favorably toward the side that contacts the heart, and the contact area between the contact portion 4ea and the heart can be increased, making it easier to prevent vacuum breakdown.

The contact portion 4ea is formed in a ring shape when viewed from the attraction target side.
According to the above configuration, since the contact portion 4ea is formed in a ring shape when viewed from the side of the object to be adsorbed, the contact portion 4ea makes it easier to suppress vacuum breakdown of the adsorption portion 4a, and makes it easier to maintain a negative pressure state within the recess 4aa.

Further, a groove portion 4eb having a shape corresponding to the protrusion 4g is formed in the cover 4e at a portion facing the protrusion 4g of the main body portion 4ac.
In this embodiment, the shape of the groove 4eb corresponding to the ridge 4g is specifically a shape that has an arc-shaped lower surface in cross section, is recessed upward, and extends in the perspective direction. Note that it is not necessary for all of the groove 4eb to have a shape corresponding to the ridge 4g, as long as at least a part of the groove 4eb has a corresponding shape.
In this way, by forming groove portion 4eb in the cover 4e having a shape corresponding to protrusion 4g, it is possible to suppress misalignment of cover 4e with respect to suction portion 4a after cover 4e is attached to suction portion 4a.

<First Modification>
Next, a holding member 24 according to a first modified example will be described with reference to Fig. 7. Fig. 7 is a diagram showing the holding member 24 according to the first modified example, and is a partial cross-sectional view showing a part of the holding member 24 in cross-section.

7, the suction portion 24a of the holding member 24 according to this example has a plurality of recesses 24aa provided on the lower surface side of the main body portion 24ac, and the plurality of recesses 24aa are connected to the intake passage 23 (suction hole 23b). The contact portion 4ea surrounds the outer peripheral edge 24ae of the contact surface 24ad of the suction portion 24a, thereby surrounding the entire plurality of recesses 24aa.
More specifically, when viewed from the bottom, the adhesion portion 4ea is formed in an oval shape so as to surround the entire outer edge 24ae (the lower edge of the peripheral surface of the suction portion 24a) of the abutment surface 24ad of the suction portion 24a from the outside, relative to the inside where the multiple recesses 24aa are located.
According to the above-described configuration, since the contact portion 4ea surrounds the outer peripheral edge 24ae of the suction portion 24a, it is not necessary to provide the contact portion 4ea individually for each of the recesses 24aa, and the contact portion 4ea can be easily attached to the suction portion 24a.

<Second Modification>
Next, a suction portion 34a according to a second modified example will be described with reference mainly to Fig. 8. Fig. 8 is an enlarged cross-sectional view showing a cross section of a portion of the suction portion 34a according to the second modified example.
The suction portion 34a according to this example has a plurality of recesses 34aa. The recesses 34aa include an upper portion 34ab that is connected to the intake passage 23, and a step that is continuous with the lower end of the upper portion 34ab and extends radially outward from the lower end of the upper portion 34ab. The step forms a periphery (inner periphery 34ae) at the lower end of the suction portion 34a that is larger in diameter than the upper portion 34ab.
The contact portion (O-ring 34e) according to this example is provided on the periphery of the recess 34aa (the inner periphery 34ae of the suction portion 34a).
According to the above configuration, since the adhesion portion (O-ring 34e) is provided on the periphery (inner peripheral edge 34ae) of the recess 34aa, the space occupied outside the suction portion 34a shown in FIG. 8 can be reduced compared to the case where the adhesion portion surrounds the outer peripheral edge 4ae of the suction portion 4a as shown in FIG. 6, etc., and treatment can be easily performed outside the suction portion 34a.

In FIG. 8, O-ring 34e is shown as being in contact with an imaginary plane including contact surface 4ad, but is not limited to such a configuration. For example, O-ring 34e may be formed or positioned to protrude downward from contact surface 4ad. With such a configuration, O-ring 34e may be able to maintain contact with the heart even if contact surface 4ad is somewhat separated from the heart, and in this case, vacuum breakdown can be prevented.

Furthermore, if the adhesion portion 4ea is provided so as to surround the outer peripheral edge 4ae of the suction portion 4a and is also provided on the periphery of the recess 34aa as shown in Figure 6, etc., it becomes easier to maintain contact with the heart, and it becomes easier to maintain a negative pressure state between the heart and the adhesion portion 4ea.
In this embodiment, the contact portion is an O-ring 34e, but the present invention is not limited to this structure. For example, the contact portion may be an annular angular gasket. Furthermore, the gasket may have a step formed thereon to fit into the periphery of the recess 34aa.

<Third Modification>
Next, a suction portion 44a according to a third modified example will be described with reference mainly to Fig. 9. Fig. 9 is an enlarged cross-sectional view showing a cross section of a portion of the suction portion 44a according to the third modified example.
The suction portion 44a according to this example has a connection opening 43a connected to the intake passage 23 inside the recess 44aa.
The connection opening 43a is an edge portion of the suction portion 44a, and a contact portion (skirt portion 44e) is formed around the connection opening 43a.

In detail, the connection opening 43a is an edge portion inside the suction portion 44a, and is also an edge portion of a recess 44aa formed in the suction portion 44a.
The upper end of the skirt portion 44e is joined by adhesive or the like to the periphery of the connection opening 43a on the lower surface (upper surface) of the recess 44aa provided in the suction portion 44a. Note that the present invention is not limited to this configuration, and the skirt portion 44e may be joined to the peripheral surface of the recess 44aa.

According to the above-described configuration, the space inside the recess 44aa connected to the connection opening 43a of the intake passage 23 is narrowed by the contact portion (skirt portion 44e), thereby making it possible to increase the suction pressure.
In addition, the skirt portion 44e as the contact portion in this example has its upper portion disposed within the recess 44aa, is formed in a circular ring shape when viewed from the bottom, and is formed so as to widen as it extends downward, extending below the abutment surface 4ad.

The present embodiment encompasses the following technical ideas.
(1) A suction-type stabilizer that uses negative pressure suction from a suction source to suction a heart, which is an object to be suctioned, and stabilizes the periphery of an anastomosis object connected to a bypass blood vessel in a coronary artery by suppressing the pulsation of the heart,
an adsorption section which is attached so that an abutment surface is abutted against the periphery of the anastomosis target section, to which an air intake path from the suction source is connected, and which suppresses the pulsation;
an adhesion portion that is softer than the adsorption portion, is connected to the adsorption portion, and adheres closely to the periphery of the anastomosis target portion;
The suction unit has a recess formed therein to which an air intake path from the suction source is connected to form a negative pressure space,
An adhesive stabilizer characterized in that the adhesion portion is provided on the edge portion of the adhesive portion and is flush with the abutment surface of the adhesive portion or extends downward beyond the abutment surface on the side of the object to be adsorbed.
(2) An adsorption type stabilizer as described in (1), in which the adhesion portion extends downward on the side of the object to be adsorbed beyond the contact surface of the adsorption portion.
(3) An adsorption type stabilizer described in (1) or (2), in which the adhesion portion is formed so as to surround the outer peripheral edge of the contact surface of the adsorption portion.
(4) The recessed portion is provided in plurality,
An adsorption type stabilizer described in any one of (1) to (3), wherein the adhesion portion surrounds the outer peripheral edge of the abutment surface of the adsorption portion, thereby surrounding the entirety of the multiple recesses collectively.
(5) An adsorption type stabilizer described in any one of (1) to (4), in which the adhesion portion is provided on the periphery of the recess.
(6) The suction portion has a connection opening connected to the intake passage inside the recess,
The connection opening is an edge portion of the suction portion,
The suction type stabilizer according to any one of (1) to (5), wherein the adhesion portion is formed around the connection opening.
(7) An adsorption type stabilizer described in any one of (1) to (6), in which the adhesion portion is formed so as to extend downward from the edge of the contact surface of the adsorption portion toward the object to be adsorbed, and to become wider toward the end.
(8) An adsorption type stabilizer described in any one of (1) to (7), in which the contact portion is formed in a ring shape when viewed from the side of the object to be adsorbed.
(9) A core material having a harderness than the suction portion, being bendable along the heart and capable of retaining its shape, and further comprising a core material for retaining the shape of the suction portion;
The suction-type stabilizer according to any one of (1) to (8), wherein the core material is embedded inside the thick portion of the suction portion.

REFERENCE SIGNS LIST 1 suction type stabilizer 1a joint member 1b arm portion 2 suction source 3 intake passage 3c flexible tube 3d, 3e ventilation hole 4 holding member 4a suction portion 4aa recess 4ac main body portion (thick portion)
4ad: contact surface 4ae: outer periphery (edge portion)
4b base portion 4ba connector portion 4bb socket 4bc connection portion 4bd coupling portion 4d storage portion 4e cover 4ea contact portion 4eb groove portion 4ec cover portion 4ed through hole 4f connection member 4g protrusion 6 core material 23 intake passage 23b suction hole 24 holding member 24a suction portion 24aa recess 24ac main body portion 24ad contact surface 24ae outer periphery (edge portion)
34a: Adsorption portion 34aa: Recess 34ab: Upper portion 34ae: Inner peripheral edge (edge portion)
34e O-ring (contact part)
43a Connection opening (edge portion)
44a: Adsorption portion 44aa: Recess 44e: Skirt portion (close contact portion)
OS Treatment space

Claims (5)

A suction-type stabilizer that uses negative pressure suction from a suction source to suction a heart, which is an object to be suctioned, and suppresses the pulsation of the heart, thereby stabilizing the periphery of an anastomosis object connected to a bypass blood vessel in a coronary artery,
an adsorption section which is attached so that an abutment surface is abutted against the periphery of the anastomosis target section, to which an air intake path from the suction source is connected, and which suppresses the pulsation;
an adhesion portion that is softer than the adsorption portion, is connected to the adsorption portion, and adheres closely to the periphery of the anastomosis target portion;
The suction unit has a recess formed therein to which an air intake path from the suction source is connected to form a negative pressure space,
The suction portion has a connection opening connected to the intake passage inside the recess,
The connection opening is an inner edge portion of the suction part,
the adhesion portion is provided on an edge portion of the suction portion, is formed around the connection opening, and is flush with the abutment surface of the suction portion or extends downward beyond the abutment surface toward the object to be suctioned,
An adsorption type stabilizer, characterized in that a portion of the contact portion is located in the internal space of the recess. The suction stabilizer according to claim 1, wherein the adhesion portion extends downward beyond the contact surface of the suction portion toward the object to be suctioned. 3. The suction-type stabilizer according to claim 1, wherein the contact portion is formed so as to extend downward from an edge of the contact surface of the suction portion toward the object to be suctioned and to widen toward the end. The suction-type stabilizer according to claim 1 , wherein the contact portion is formed in a ring shape when viewed from the side of the object to be attracted. a core material having a harder hardness than the suction portion, being bendable along the heart and capable of retaining its shape, and further comprising a core material for retaining the shape of the suction portion;
5. The suction type stabilizer according to claim 1, wherein the core material is embedded inside the thick portion of the suction portion.

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