JP2021101899A - Adapter and ultrasonic probe with adapter - Google Patents

Abstract

To provide a method of attaching an adapter for puncture needle fixation to an ultrasonic probe without damaging a probe cover.SOLUTION: An adapter includes a first member, a lever, and a second member. When the first member is placed in an attachment region of an ultrasonic probe 10, a part of the first member projects from an end surface of the ultrasonic probe in an extension direction of a probe plane portion, as a support portion. The lever is supported by the support portion so as to be freely rotatable around means acting as a rotation axis included in the support portion. The lever includes a first end and a second end. When the first member is placed in the attachment region, the first end can contact with the ultrasonic probe from a rear side of the attachment region. The second end is located on the opposite side from the first end having the rotation axis therebetween. The second member is mounted so as to fit to the second end of the lever having the first member placed in the attachment region between the second member and the ultrasonic probe. At the time of mounting, the second member pushes the first end to the first member through rotation.SELECTED DRAWING: Figure 16

Description

Embodiments disclosed herein and in the drawings relate to adapters and ultrasonic probes with adapters.

There is a puncture technique in which a puncture needle is inserted into the affected area for the purpose of collecting internal tissues such as tumors, local administration of drug solutions, and treatment with external energy. At this time, ultrasonic-guided puncture, which guides the puncture needle by imaging the puncture target with an ultrasonic diagnostic device and drawing the puncture target and the puncture needle on an ultrasonic tomographic image, is safe and reliable. It is useful for achieving puncture.

In ultrasonic guided puncture, a probe cover may be attached to the ultrasonic probe in order to prevent infection during puncture and contamination of the ultrasonic probe. The probe cover is a bag-shaped cover made of an ultra-thin rubber or plastic material and covers the ultrasonic probe. When the probe cover is attached to the ultrasonic probe, for example, an adapter for fixing the puncture needle is attached to the ultrasonic probe from the outside of the probe cover.

When fixing the adapter to the ultrasonic probe, for example, one end of a lever provided on the adapter is hooked on a protrusion formed on the ultrasonic probe. When hooking the lever end of the adapter to the protrusion of the ultrasonic probe, the user needs to push the lever end beyond the protrusion of the ultrasonic probe. When pushing the lever end, friction may occur between the lever end and the probe cover covering the ultrasonic probe, which may damage the probe cover.

Japanese Unexamined Patent Publication No. 2006-212165

One of the challenges to be solved by the embodiments disclosed herein and in the drawings is to attach the adapter to the ultrasonic probe without damaging the probe cover. However, the problems to be solved by the embodiments disclosed in the present specification and the drawings are not limited to the above problems. It is also possible to position the problem corresponding to each effect of each configuration shown in the embodiment described later as another problem.

According to the embodiment, the adapter comprises a first member, a lever, and a second member. When the first member is placed in the mounting region of the ultrasonic probe, a part of the first member projects from the end face of the ultrasonic probe as a support portion in the extending direction of the probe flat surface portion. The lever is rotatably supported by the support portion around a means that acts as a rotation shaft provided in the support portion. The lever has a first end and a second end. The first end is accessible to the ultrasonic probe from the back side of the mounting area when the first member is placed in the mounting area. The second end is located on the opposite side of the first end and the rotation axis. The second member is mounted so as to sandwich the first member placed in the mounting region between the ultrasonic probe and the second end of the lever. At the time of mounting, the second member pushes the first end toward the first member via the rotation.

FIG. 1 is a perspective view showing an ultrasonic probe to which the adapter according to the present embodiment is attached. FIG. 2 is a perspective view showing an ultrasonic probe covered with a probe cover and to which an adapter is attached. FIG. 3 is a perspective view showing the ultrasonic probe shown in FIG. FIG. 4 is a perspective view showing the ultrasonic probe shown in FIG. 3 from another viewpoint. FIG. 5 is a perspective view of the adapter shown in FIG. FIG. 6 is a perspective view showing the first member shown in FIG. FIG. 7 is a perspective view showing the first member shown in FIG. 6 from another viewpoint. FIG. 8 is a perspective view showing the second member shown in FIG. FIG. 9 is a perspective view showing the second member shown in FIG. 8 from another viewpoint. FIG. 10 is a perspective view showing the lever shown in FIG. FIG. 11 is a diagram showing the lever shown in FIG. 10 from another viewpoint. FIG. 12 is a cross-sectional view when the first member is temporarily fastened to the ultrasonic probe. FIG. 13 is a cross-sectional view when the first member is temporarily fastened to the ultrasonic probe. FIG. 14 is a cross-sectional view when the second member is attached to the first member temporarily fastened to the ultrasonic probe. FIG. 15 is a cross-sectional view when the second member is attached to the first member temporarily fastened to the ultrasonic probe. FIG. 16 is a diagram showing a force applied to the lever in FIG. FIG. 17 is a cross-sectional view of the ultrasonic probe and the adapter when there is no recess on the back surface of the ultrasonic probe. FIG. 18 is a block diagram showing a functional configuration of an ultrasonic diagnostic apparatus to which the ultrasonic probe according to the present embodiment is attached.

Hereinafter, embodiments will be described with reference to the drawings.

FIG. 1 is a perspective view showing an example of an ultrasonic probe 10 to which the adapter 20 according to the present embodiment is attached. When performing the puncture procedure, the ultrasonic probe 10 is covered with the probe cover 2 as shown in FIG. In the following, the probe cover 2 will be omitted for simplification of the drawings. The ultrasonic probe 10 shown in FIG. 1 is provided with a grip portion 11 for the operator to grip the ultrasonic probe 10 and an ultrasonic radiation portion 12 provided in a substantially L shape from the grip portion 11.

The ultrasonic radiation unit 12 is provided so that the radiation surface faces in a direction opposite to the direction in which the grip portion 11 is formed. A plurality of ultrasonic vibrators are arranged inside the ultrasonic radiation unit 12. A notch 13 is provided at the tip of the ultrasonic radiation portion 12 provided in a substantially L shape from the grip portion 11. The notch portion 13 is formed so that the adapter 20 can be attached. The notch portion 13 is an example of a mounting area.

3 and 4 are perspective views of the ultrasonic probe 10 shown in FIG. 1 as viewed from different viewpoints. In the ultrasonic probe 10 shown in FIG. 3, the notch portion 13 has a first surface 131 and a second surface 132. The first surface 131 is provided so as to extend along the forming direction of the ultrasonic radiation portion 12. The second surface 132 extends in a direction orthogonal to the forming direction of the ultrasonic radiation unit 12, and is provided so as to be orthogonal to the first surface 131.

The first surface 131 is provided with, for example, a circular recess 131a. The position where the concave portion 131a is formed is associated with the position of the convex portion 211e provided on the first member 21.

The second surface 132 is provided with, for example, recesses 132a and 132b having a predetermined shape. The positions where the recesses 132a and 132b are formed are associated with the positions of the protrusions 212c and 212d provided on the first member 21.

An end face 14 is provided at the end of the ultrasonic radiation unit 12.

As shown in FIG. 4, a back surface 15 is provided on the back surface of the first surface 131. A recess 15a is formed on the back surface 15. The recess 15a is formed so that the width is larger than the width of the lever 23 of the adapter 20. The position where the recess 15a is formed corresponds to the position where the lever 23 is arranged. The recess 15a is formed so that the shape corresponds to, for example, the shape of the lock portion 23c provided on the lever 23 and the trajectory of the lock portion 23c. The recess 15a is an example of a configuration for hooking the lock portion 23c provided on the back side of the notch portion 13 of the ultrasonic probe 10.

FIG. 5 is a perspective view of the adapter 20 shown in FIG. The adapter 20 shown in FIG. 5 includes a first member 21, a second member 22, and a lever 23. The first member 21, the second member 22, and the lever 23 are provided with, for example, a thermoplastic resin capable of injection molding, blow molding, and the like. Specifically, for example, it is provided by polyethylene, polypropylene, polycarbonate, polyacetal, polyamide, or the like.

6 and 7 are perspective views of the first member 21 shown in FIG. 5 as viewed from different viewpoints. The first member 21 shown in FIGS. 6 and 7 has a seat portion 211 and a back portion 212. The seat portion 211 and the back portion 212 are provided so as to be substantially orthogonal to each other.

The seat portion 211 is an example of a flat portion placed on the first surface 131 of the ultrasonic probe 10, and is formed so that the width gradually narrows from the portion where the back portion 212 is provided. Bifurcated portions 211a-1,211a-2 are provided at the narrowed ends. The seat portion 211 is formed to be slightly larger than the first surface 131 of the notch portion 13 of the ultrasonic probe 10. As a result, when the first member 21 is placed on the first surface 131 of the notch portion 13, the bifurcated portions 211a-1,211a-2 protrude from the end surface 14 of the ultrasonic probe 10. Support portions 211b-1, 211b-2 are provided on the side surfaces of the bifurcated portions 211a-1,211a-2 so as to face each other. The support portions 211b-1, 211b-2 are formed so as to have a substantially cylindrical shape. The support portions 211b-1,211b-2 serve as an example of means for acting as a rotation shaft by rotatably supporting the lever 23 with the recess 23a of the lever 23.

Convex portions 211c and 211d are provided on the surface of the seat portion 211 on the side on which the back portion 212 is formed. The positions where the convex portions 211c and 211d are formed are associated with the positions of the concave portions 221g and 221h provided in the second member 22.

A convex portion 211e is provided on the surface of the seat portion 211 opposite to the surface on which the back portion 212 is formed. The position where the convex portion 211e is formed is associated with the position of the concave portion 131a provided in the notch portion 13 of the ultrasonic probe 10.

The back portion 212 is provided with a hole portion 212a. The hole 212a is formed so as to widen in the longitudinal direction of the back 212a. The position where the hole portion 212a is formed is associated with the position of the convex portion 222a provided on the side surface portion 222 of the second member 22. Further, the shape of the hole portion 212a is associated with the shape of the convex portion 222a.

Convex portions 212c and 212d are provided on the surface of the back portion 212 opposite to the surface on which the seat portion 211 is formed. The positions where the convex portions 212c and 212d are formed are associated with the positions of the concave portions 132a and 132b provided in the notch portion 13 of the ultrasonic probe 10. The convex portions 212c and 212d are formed so that, for example, the convex portions 212c and 212d are gradually widened and increased in height as they are separated from the back surface of the seat portion 211. Further, the convex portions 212c and 212d are formed so that the upper ends thereof are in a plane parallel to the seat portion 211.

8 and 9 are perspective views of the second member 22 shown in FIG. 5 as viewed from different viewpoints. The second member 22 shown in FIGS. 8 and 9 has a lid portion 221 and a side surface portion 222.

The lid portion 221 is formed so that the width gradually narrows from the portion where the side surface portion 222 is provided. A locking portion 221a is provided at the narrowed end. The locking portion 221a includes an inclined portion. The inclined portion is formed from the upper surface side of the lid portion 221 toward the back surface side of the lid portion 221. The back surface side of the lid portion 221 is the side of the lid portion 221 where the first to fourth groove portions 221c to 221f, which will be described later, are provided. In other words, one end of the inclined portion is located on the upper surface side of the lid portion 221 and the other end is located on the back surface side of the lid portion 221. Further, the direction from one end to the other end of the inclined portion is inclined toward the side surface portion 222 with respect to the upper surface of the lid portion 221. A handle portion 221b is provided at the end portion of the lid portion 221 so as to surround the locking portion 221a.

The first to fourth groove portions 221c to 221f are provided on the back surface of the lid portion 221. The first to fourth groove portions 221c to 221f are formed so that a puncture needle can be inserted. The first to fourth groove portions 221c to 221f are formed so that the forming direction corresponds to the insertion angle of the puncture needle.

The back surface of the lid portion 221 is provided with recesses 221g and 221h. The positions where the recesses 221g and 221h are formed are associated with the positions of the protrusions 211c and 211d provided on the first member 21.

The side surface portion 222 is provided with a convex portion 222a. The position where the convex portion 222a is formed is associated with the position of the hole portion 212a provided in the back portion 212 of the first member 21. Further, the shape of the convex portion 222a is associated with the shape of the hole portion 212a.

10 and 11 are perspective views and views of the lever 23 shown in FIG. 5 as viewed from different viewpoints. The lever 23 shown in FIGS. 10 and 11 has a recess 23a, a protrusion 23b, a lock portion 23c, an inclined portion 23d, an arm portion 23e, and a engaging portion 23f.

The recess 23a is provided on the opposite surface in addition to the surfaces shown in FIGS. 10 and 11. The recess 23a is formed to have a diameter slightly larger than that of the support portions 211b-1,211b-2 of the first member 21. The lever 23 is a recess 23a and is supported by support portions 211b-1,211b-2. The lever 23 can rotate around the recess 23a.

The protrusion 23b has a semicircular flat shape. The protrusion 23b is formed so that, for example, when the first member 21, the second member 22, and the lever 23 are attached to the ultrasonic probe 10, the tip thereof is higher than the surface of the second member 22. .. The lock portion 23c has a rounded shape corresponding to the shape of the recess 15a on the back surface 15 of the ultrasonic probe 10.

The inclined portion 23d is formed so as to increase in thickness from the protruding portion 23b toward the concave portion 23a.

The dependency portion 23f is a substantially rectangular notch portion provided at the end of the inclined portion 23d. The engaging portion 23f and the locking portion 23c are provided at positions opposite to the recess 23a, which is the axis of rotation, with the end surface 14 of the ultrasonic probe and the first surface 131 of the notch portion 13 as boundaries. The shape of the engaging portion 23f corresponds to the shape of the locking portion 221a of the second member 22. The distance from the recess 23a to the upper end of the engaging portion 23f is associated with the height of the locking portion 221a of the second member 22.

The arm portion 23e is formed so as to be curved in a substantially arc shape from the back side of the retaining portion 23f to a position between the recess 23a and the lock portion 23c. The arm portion 23e has a structure in which a space is provided between the arm portion 23e and the recess 23a, and the arm portion 23e is bent by a force received from the protrusion portion 23b or the lock portion 23c.

Next, the procedure for attaching the adapter 20 configured as described above to the ultrasonic probe 10 will be specifically described with reference to FIGS. 12 to 15. 12 to 15 are cross-sectional views showing a cross section taken along the line AA in FIG.

12 and 13 are cross-sectional views when the first member 21 is temporarily fastened to the ultrasonic probe 10. First, for example, the recess 23a of the lever 23 is fitted into the support portions 211b-1, 211b-2 of the first member 21. As a result, the lever 23 is rotatably supported by the first member 21.

Subsequently, the first member 21 that supports the lever 23 is placed at a preset position in the notch 13 of the ultrasonic probe 10. At this time, for example, the user places the first member 21 on the first surface 131 of the notch portion 13 so as to align the back portion 212 of the first member 21 with the second surface 132 of the notch portion 13. The first member 21 is placed by associating the positions where the recesses 132a, 132b, 131a are formed in the notch portion 13 with the positions where the convex portions 212c, 212d, 211e are formed in the first member 21. The position is uniquely determined.

As shown in FIG. 13, when the first member 21 is placed on the first surface 131 of the notch portion 13, the bifurcated portions 211a-1,211a-2 of the first member 21 are of the ultrasonic probe 10. It is in a state of protruding from the end face 14. As a result, the rotation axis of the lever 23 is located outside the ultrasonic probe 10, and the degree of freedom of rotation of the lever 23 is hindered until the lock portion 23c comes into contact with the recess 15a of the back surface 15 of the ultrasonic probe 10. It will not be done.

As shown in FIG. 13, when the first member 21 is placed on the notch 13, the user pushes the protrusion 23b of the lever 23 outward of the ultrasonic probe 10 until the lever 23 stops. When the protrusion 23b is pushed, the lever 23 makes a rotary motion with the recess 23a as the rotation axis. The lever 23 stops its rotational movement when the lock portion 23c of the lever 23 comes into contact with the recess 15a of the ultrasonic probe 10. The shape of the lock portion 23c of the lever 23 is formed so as to share a tangent line with the rotational movement with the recess 23a as the rotation axis and to correspond to the shape of the recess 15a of the ultrasonic probe 10. Therefore, friction does not occur between the lock portion 23c and the back surface 15 until the lock portion 23c reaches the recess 15a. The first member 21 is "temporarily fastened" to the ultrasonic probe 10 by placing the first member 21 in the notch 13 and bringing the lock portion 23c of the lever 23 into contact with the recess 15a of the back surface 15 of the ultrasonic probe 10. To.

14 and 15 are cross-sectional views when the second member 22 is attached to the first member 21 temporarily fastened to the ultrasonic probe 10. The second member 22 is mounted so that the lid portion 221 of the second member 22 and the first surface 131 of the ultrasonic probe 10 sandwich the seat portion 211 of the first member 21.

First, for example, the user grips the handle portion 221b of the second member 22, and the convex portion 222a of the second member 22 is obliquely oriented with respect to the hole portion 212a of the first member 21 from above the first member 21. To insert. The user grips the handle portion 221b with the contact point between the hole portion 212a and the convex portion 222a as an axis, and pushes the lid portion 221 of the second member 22 toward the seat portion 211 of the first member 21.

When the lid portion 221 is pushed toward the seat portion 211 with the convex portion 222a inserted into the hole portion 212a, the locking portion 221a of the second member 22 slides the inclined portion 23d of the lever 23, and the lever 23 The arm portion 23e of the above is pushed outward from the ultrasonic probe 10.

When the lid portion 221 is further pushed in the direction of the seat portion 211, the locking portion 221a reaches the end of the inclined portion 23d, and the expanded arm portion 23e elastically returns to the ultrasonic probe 10 side. When the arm portion 23e returns, the locking portion 221a and the engaging portion 23f of the lever 23 are fitted to each other. At this time, the convex portions 211c and 211d of the first member 21 are inserted into the concave portions 221g and 221h of the second member 22. As a result, the position of the second member 22 with respect to the first member 21 is uniquely determined.

FIG. 16 is a schematic view showing an example of the force applied to the lever 23 in FIG. The engaging portion 23f of the lever 23 is pushed in the outward direction of the ultrasonic probe 10 by the locking portion 221a of the second member 22. As a result, the arm portion 23e is in a state of being elastically deformed. The force applied by the locking portion 221a is propagated through the arm portion 23e and converted into a rotational motion with the recess 23a as the rotation axis. By this rotational movement, the lock portion 23c of the lever 23 pushes the bottom surface of the concave portion 15a with a force in the tangential direction of the rotational movement about the concave portion 23a as the rotation axis. Further, due to this rotational movement, the portion extending from the recess 23a to the lock portion 23c is firmly brought into close contact with the end surface 14 and the back surface 15 of the ultrasonic probe 10. As a reaction force of the force for pushing the engaging portion 23f into the locking portion 221a, the force in the direction of the ultrasonic probe 10 and the force in the direction of pushing against the seat portion 211 of the first member 21 due to the elasticity of the arm portion 23e. Is given. At this time, the amount of elastic deformation of the arm portion 23e is larger than the thickness of the probe cover in the lock portion 23c.

By mounting the second member 22 on the first member 21 temporarily fastened to the ultrasonic probe 10 in this way, the lock portion 23c of the lever 23 is pushed into the ultrasonic probe 10. As a result, the adapter 20 is firmly fixed to the ultrasonic probe 10. The lock portion 23c of the lever 23 that comes into contact with the ultrasonic probe 10 is further pushed by the attachment of the second member 22, so that the first member 21 is "mainly fastened" to the ultrasonic probe 10.

As described above, in the above embodiment, when the first member 21 is placed in the notch 13 of the ultrasonic probe 10, the bifurcated portions 211a-1,211a-2 of the seat portion 211 support the lever 23. In addition, it protrudes from the end face 14 of the ultrasonic probe 10. The lever 23 is rotatably supported by the support portions 211b-1,211b-2 provided on the bifurcated portions 211a-1,211a-2 as a rotation axis. The lever 23 has a lock portion 23c that can come into contact with the back surface 15 of the ultrasonic probe 10 when the first member 21 is placed in the notch portion 13, and a dependency located on the opposite side of the lock portion 23c and the shaft. It has a portion 23f. The second member 22 is mounted so that the seat portion 211 of the first member 21 placed in the notch portion 13 is sandwiched between the ultrasonic probe 10 and the engaging portion 23f. Then, when the second member 22 is attached, the second member 22 engages in the direction in which the lock portion 23c pushes the ultrasonic probe 10 via the rotation of the lever 23, and pushes the receiving portion 23f. As a result, first, the first member 21 is temporarily fastened to the ultrasonic probe 10 by the lock portion 23c of the lever 23. Then, when the second member 22 is attached to the first member 21, the lock portion 23c of the lever 23 is further pushed into the ultrasonic probe 10, and the first member 21 is more firmly fixed to the ultrasonic probe 10. Will be done.

At this time, the lock portion 23c that has come into contact with the ultrasonic probe 10 during temporary fastening is given a force to push it into the ultrasonic probe 10 at the time of final fastening without moving from the position at the time of temporary fastening. Therefore, when the adapter 20 is attached to the ultrasonic probe 10, there is no friction between the lock portion 23c and the ultrasonic probe 10. In the conventional configuration, the user has fixed the adapter to the ultrasonic probe, for example, by pushing the lever end over the protrusion of the ultrasonic probe. In the present embodiment, since there is no friction between the lock portion 23c and the ultrasonic probe 10, it is possible to suppress wear of the ultrasonic probe, and high durability is expected.

Further, in the present embodiment, even when the ultrasonic probe 10 is covered with the probe cover and the adapter 20 is mounted from above the probe cover, there is no friction between the lock portion 23c and the probe cover. Therefore, it is possible to prevent the probe cover from being damaged.

Further, in the present embodiment, the engaging portion 23f of the lever 23 is pushed by the second member 22, so that the force of the locking portion 23c pushing the ultrasonic probe 10 is strengthened. Therefore, the adapter 20 can be firmly attached to the ultrasonic probe 10 regardless of the presence or absence of the probe cover.

Further, since friction does not occur between the lock portion 23c and the probe cover, it is not necessary to provide a structural clearance between the lock portion 23c and the ultrasonic probe 10 so as not to damage the probe cover. Since no clearance is required, when the adapter 20 is attached to the ultrasonic probe 10, the ultrasonic probe 10 and the first member 21 are closely fixed to each other. Since the ultrasonic probe 10 and the first member 21 are in close contact with each other and fixed, the insertion direction of the puncture needle is constant regardless of the presence or absence of the probe cover.

Further, in the present embodiment, when the second member 22 is mounted on the first member 21, the locking portion 221a of the second member 22 is used as a reaction force of the force for pushing the engaging portion 23f of the lever 23. A force in the direction of the ultrasonic probe 10 and a force in the direction of pressing the first member 21 against the seat portion 211 are applied. Therefore, when the puncture needle is inserted into the adapter 20, even if a force is applied to the inserted puncture needle in the direction of removing the adapter 20, a force that hinders the deformation of the second member 22 is generated. It is possible to reduce the deformation risk of the second member 22.

In the above embodiment, the case where the recess 15a is provided on the back surface 15 of the ultrasonic probe 10 has been described as an example. However, it is not always necessary to provide the recess 15a on the back surface 15 of the ultrasonic probe 10. If the recess 15a is provided, a step is generated, and this step serves as a engaging portion for the lock portion 23c, and the fixing strength after the final fastening is further improved. On the other hand, as shown in FIG. 17, even if the back surface 15 is not provided with the recess 15a, the lock portion 23c is pushed into the ultrasonic probe 10 by the final fastening, so that the probe cover is not damaged. An adapter can be attached to the ultrasonic probe 10.

Further, in the above embodiment, the case where the adapter having the fixing mechanism of the temporary fastening and the final fastening is applied to the puncture adapter has been described as an example. However, the adapter having the fixing mechanism of temporary fastening and final fastening is not limited to the puncture adapter. For example, it may be applied to an adapter that attaches a position sensor for detecting the position of an ultrasonic probe when displaying an ultrasonic image in synchronization with an image acquired by another modality.

Subsequently, the ultrasonic diagnostic apparatus to which the ultrasonic probe 10 according to the present embodiment is attached will be described.
FIG. 18 is a block diagram showing an example of the functional configuration of the ultrasonic diagnostic apparatus 1 to which the ultrasonic probe 10 according to the present embodiment is attached. The ultrasonic diagnostic apparatus 1 shown in FIG. 1 has an apparatus main body 30 and an ultrasonic probe 10. The device main body 30 is connected to the input device 40 and the display device 50. Further, the device main body 30 is connected to the external device 60 via the network NW.

An adapter 20 is attached to the ultrasonic probe 10, and for example, an ultrasonic scan is performed on a scan area in a living body P, which is a subject, under control from the apparatus main body 30. The ultrasonic probe 10 has, for example, a plurality of piezoelectric vibrators, a matching layer provided on the piezoelectric vibrator, a backing material for preventing the propagation of ultrasonic waves from the piezoelectric vibrator to the rear, and the like. The ultrasonic probe 10 is detachably connected to the device main body 30.

The ultrasonic probe 10 is, for example, a 1D array linear probe in which a plurality of ultrasonic vibrators are arranged along a predetermined direction, a 2D array probe in which a plurality of piezoelectric vibrators are arranged in a matrix, or a piezoelectric vibrator train. Is a mechanical 4D probe or the like capable of performing ultrasonic scanning while mechanically agitating in a direction orthogonal to the arrangement direction.

The plurality of piezoelectric vibrators generate ultrasonic waves based on a drive signal supplied from an ultrasonic transmission circuit 31 described later, which is included in the apparatus main body 30. As a result, ultrasonic waves are transmitted from the ultrasonic probe 10 to the living body P. When ultrasonic waves are transmitted from the ultrasonic probe 10 to the living body P, the transmitted ultrasonic waves are reflected one after another on the discontinuity surface of the acoustic impedance in the body tissue of the living body P, and are reflected by a plurality of piezoelectric elements as reflected wave signals. Is received. The amplitude of the received reflected wave signal depends on the difference in acoustic impedance on the discontinuity where the ultrasonic waves are reflected. Further, the reflected wave signal when the transmitted ultrasonic pulse is reflected by the moving blood flow or the surface of the heart wall or the like depends on the velocity component in the ultrasonic transmission direction of the moving body due to the Doppler effect. And undergo frequency shift. The ultrasonic probe 10 receives the reflected wave signal from the living body P and converts it into an electric signal.

The device main body 30 is a device that generates an ultrasonic image based on a reflected wave signal received by the ultrasonic probe 10. The apparatus main body 30 includes an ultrasonic transmission circuit 31, an ultrasonic reception circuit 32, an internal storage circuit 33, an image memory 34, an input interface 35, an output interface 36, a communication interface 37, and a processing circuit 38.

The ultrasonic transmission circuit 31 is a processor that supplies a drive signal to the ultrasonic probe 10. The ultrasonic transmission circuit 31 is realized by, for example, a pulse generator, a transmission delay circuit, and a pulser circuit. The pulse generator repeatedly generates a rate pulse for forming a transmitted ultrasonic wave at a predetermined repetition frequency (PRF: Pulse Repetition Frequency). The transmission delay circuit sets the delay time for each piezoelectric vibrator, which is required to focus the ultrasonic waves generated from the ultrasonic probe 10 in a beam shape and determine the transmission directivity, for each rate pulse generated by the pulse generator. Give to. The transmission delay time for determining the transmission direction or the transmission direction is stored in the internal storage circuit 33 and is referred to at the time of transmission. The pulsar circuit applies a drive signal (drive pulse) to a plurality of ultrasonic vibrators provided in the ultrasonic probe 10 at a timing based on the rate pulse. By changing the delay time given to each rate pulse by the transmission delay circuit, the transmission direction from the piezoelectric vibrator surface can be arbitrarily adjusted.

The ultrasonic wave receiving circuit 32 is a processor that generates a received signal by performing various processes on the reflected wave signal received by the ultrasonic probe 10. The ultrasonic wave receiving circuit 32 is realized by, for example, a preamplifier, an A / D converter, a demodulator, and a beam former.

The preamplifier amplifies the reflected wave signal received by the ultrasonic probe 10 for each channel and performs gain correction processing. At this time, the preamplifier changes the gain value according to, for example, a predetermined time response. The A / D converter converts the gain-corrected reflected wave signal into a digital signal. By demodulating the digital signal, the demodulator converts the digital signal into a baseband band in-phase signal (I signal, I: In-phase) and an orthogonal signal (Q signal, Q: Quadrature-phase). The beamformer gives the I signal and the Q signal (hereinafter referred to as IQ signal) the delay time required to determine the reception directivity. The beamformer adds an IQ signal with a delay time. The beamformer processing generates a received signal in which the reflected component from the direction corresponding to the receiving directivity is emphasized.

The internal storage circuit 33 has, for example, a magnetic or optical storage medium, a storage medium that can be read by a processor such as a semiconductor memory, or the like. The internal storage circuit 33 stores, for example, a program for realizing ultrasonic transmission / reception. Further, the internal storage circuit 33 contains diagnostic information, a scan sequence, a diagnostic protocol, ultrasonic transmission / reception conditions, signal processing conditions, image generation conditions, image processing conditions, body mark generation programs, display conditions, and color data used for visualization. It stores various data such as a conversion table in which the range is preset for each diagnosis site. The program and various data may be stored in advance in the internal storage circuit 33, for example. Further, for example, it may be stored and distributed in a non-transient storage medium, read from the non-transient storage medium, and installed in the internal storage circuit 33.

Further, the internal storage circuit 33 stores the reception signal generated by the ultrasonic reception circuit 32, various ultrasonic image data generated by the processing circuit 38, and the like according to the operation input via the input interface 35. The internal storage circuit 33 can also transfer the stored data to the external device 60 or the like via the communication interface 37.

The internal storage circuit 33 may be a drive device or the like that reads and writes various information to and from a portable storage medium such as a CD-ROM drive, a DVD drive, and a flash memory. The internal storage circuit 33 can also write the stored data to the portable storage medium and store the data in the external device 60 via the portable storage medium.

The image memory 34 has, for example, a magnetic storage medium, an optical storage medium, or a storage medium that can be read by a processor such as a semiconductor memory. The image memory 34 stores image data corresponding to a plurality of frames immediately before the freeze operation, which is input via the input interface 35. The image data stored in the image memory 34 is, for example, continuously displayed (cine display).

The internal storage circuit 33 and the image memory 34 do not necessarily have to be realized by independent storage devices. The internal storage circuit 33 and the image memory 34 may be realized by a single storage device. Further, each of the internal storage circuit 33 and the image memory 34 may be realized by a plurality of storage devices.

The input interface 35 receives various instructions from the operator via the input device 40. The input device 40 is, for example, a mouse, a keyboard, a panel switch, a slider switch, a trackball, a rotary encoder, an operation panel, and a touch command screen (TCS). The input interface 35 is connected to the processing circuit 38 via, for example, a bus, converts an operation instruction input from the operator into an electric signal, and outputs the electric signal to the processing circuit 38. The input interface 35 is not limited to those connected to physical operation parts such as a mouse and a keyboard. For example, an example of an input interface is a circuit that receives an electric signal corresponding to an operation instruction input from an external input device provided separately from the ultrasonic diagnostic apparatus 1 and outputs this electric signal to the processing circuit 38. included.

The output interface 36 is, for example, an interface for outputting an electric signal from the processing circuit 38 to the display device 50. The display device 50 is an arbitrary display such as a liquid crystal display, an organic EL display, an LED display, a plasma display, and a CRT display. The output interface 36 is connected to the processing circuit 38 via, for example, a bus, and outputs an electric signal from the processing circuit 38 to the display device.

The communication interface 37 is connected to the external device 60 via, for example, a network NW, and performs data communication with the external device 60.

The processing circuit 38 is, for example, a processor that functions as the center of the ultrasonic diagnostic apparatus 1. The processing circuit 38 realizes a function corresponding to the program by executing the program stored in the internal storage circuit 33. The processing circuit 38 has, for example, a B mode processing function 381, a Doppler processing function 382, an image generation function 383, a display control function 384, and a system control function 385. In this embodiment, a case where the B mode processing function 381, the Doppler processing function 382, the image generation function 383, the display control function 384, and the system control function 385 are realized by a single processor will be described. Not limited. For example, a processing circuit is configured by combining a plurality of independent processors, and the B mode processing function 381, the Doppler processing function 382, the image generation function 383, the display control function 384, and the system control function are executed by each processor executing a program. 385 may be realized. Further, a dedicated hardware circuit capable of executing each function may be incorporated.

The B-mode processing function 381 is a function of generating B-mode data based on the received signal received from the ultrasonic wave receiving circuit 32. Specifically, in the B mode processing function 381, the processing circuit 38 performs envelope detection processing, logarithmic compression processing, and the like on the received signal received from the ultrasonic receiving circuit 32, and the signal strength is bright. The data (B mode data) represented by the above is generated. The generated B-mode data is stored in a RAW data memory (not shown) as B-mode RAW data on a two-dimensional ultrasonic scanning line (raster).

The Doppler processing function 382 analyzes the frequency of the received signal received from the ultrasonic wave receiving circuit 32, and blood based on the Doppler effect of the moving body in the imaging ROI (Region Of Interest) set in the scan area. It is a function to generate data (Doppler data) related to flow information. Blood flow information includes the average velocity, dispersion, power, or combination thereof of blood flow in the subject. The generated Doppler data is stored in a RAW data memory (not shown) as Doppler RAW data on a two-dimensional ultrasonic scanning line.

The image generation function 383 is a function of generating various ultrasonic image data based on the data generated by the B mode processing function 381 and / or the Doppler processing function 382. Specifically, in the image generation function 383, the processing circuit 38 converts the B-mode RAW data stored in the RAW data memory into RAW-pixel conversion, for example, an ultrasonic scanning mode by the ultrasonic probe 10. By executing the corresponding coordinate conversion, B-mode image data composed of pixels is generated.

Further, the processing circuit 38 generates Doppler image data in which blood flow information is visualized by, for example, performing RAW-pixel conversion on the Doppler RAW data stored in the RAW data memory. The Doppler image data is average velocity image data, distributed image data, power image data, or image data obtained by combining these.

The display control function 384 is a function of displaying an image based on various ultrasonic image data generated by the image generation function 383 on the display device 50, and is an example of a display control unit. Specifically, for example, in the display control function 384, the processing circuit 38 is in the image display device 50 based on the B-mode image data, the Doppler image data, or the image data including both of them generated by the image generation function 383. Control the display.

In the display control function 384, the processing circuit 38 converts (scan-converts), for example, a scanning line signal string of an ultrasonic scanning into a scanning line signal string of a video format typified by a television or the like, and generates image data for display. .. Further, the processing circuit 38 may execute various processes such as dynamic range, brightness (brightness), contrast, and γ-curve correction, and RGB conversion on the display image data. Further, the processing circuit 38 may add additional information such as character information, scales, and body marks of various parameters to the display image data. Further, the processing circuit 38 may generate a user interface (GUI: Graphical User Interface) for the operator to input various instructions by the input device, and display the GUI on the display device 50.

The system control function 385 is a function for controlling basic operations such as input / output of the ultrasonic diagnostic apparatus 1 and ultrasonic transmission / reception. In the system control function 385, the processing circuit 38 receives, for example, various imaging mode selection instructions via the input interface 35. The various imaging modes include, for example, a B mode, a blood flow imaging mode, and the like. The processing circuit 38 controls the ultrasonic transmission circuit 31 and the ultrasonic reception circuit 32 so as to execute the scan in the selected imaging mode.

According to at least one embodiment described above, the adapter can be attached to the ultrasonic probe without damaging the probe cover.

The word "processor" used in the description of the embodiment means, for example, a CPU (central processing unit), a GPU (Graphics Processing Unit), an integrated circuit for a specific application (Application Specific Integrated Circuit (ASIC)), or a programmable logic device. (For example, a circuit such as a simple programmable logic device (SPLD), a complex programmable logic device (CPLD), and a field programmable gate array (FPGA)) is meant. The processor realizes the function by reading and executing the program stored in the storage circuit. Instead of storing the program in the storage circuit, the program may be directly embedded in the circuit of the processor. In this case, the processor realizes the function by reading and executing the program embedded in the circuit. It should be noted that each processor of each of the above embodiments is not limited to the case where each processor is configured as a single circuit, and a plurality of independent circuits are combined to form one processor to realize its function. May be good. Further, a plurality of components in each of the above embodiments may be integrated into one processor to realize the function.

Although some embodiments have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in various other embodiments, and various omissions, replacements, changes, and combinations of embodiments can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, as well as in the scope of the invention described in the claims and the equivalent scope thereof.

1 ... Ultrasonic diagnostic device 2 ... Probe cover 10 ... Ultrasonic probe 11 ... Grip part 12 ... Ultrasonic radiation part 13 ... Notch 131 ... First surface 131a ... Recessed 132 ... Second surface 132a ... Recessed 132b ... Recessed 14 ... End face 15 ... Back surface 15a ... Recessed portion 20 ... Adapter 21 ... First member 211 ... Seat portion 211a-1,211a-2 ... Bifurcated portion 211b-1,211b-2 ... Support portion 211c ... Convex portion 211d ... Convex portion 211e ... Convex part 212 ... Back part 212a ... Hole part 212c ... Convex part 212d ... Convex part 22 ... Second member 221 ... Lid part 221a ... Locking part 221b ... Handle parts 221c to 221f ... First to fourth groove parts 221g ... Concave part 221h ... Recessed portion 222 ... Side surface portion 222a ... Convex portion 23 ... Lever 23a ... Recessed portion 23b ... Protruding portion 23c ... Locking portion 23d ... Inclined portion 23e ... Arm portion 23f ... Interface receiving portion 30 ... Reception circuit 33 ... Internal storage circuit 34 ... Image memory 35 ... Input interface 36 ... Output interface 37 ... Communication interface 38 ... Processing circuit 381 ... B mode processing function 382 ... Doppler processing function 383 ... Image generation function 384 ... Display control function 385 ... System control function 40 ... Input device 50 ... Display device 60 ... External device

Claims (9)

When placed in the mounting area of the ultrasonic probe, a first member that partially protrudes from the end face of the ultrasonic probe as a support portion in the extending direction of the probe flat surface portion, and
The support portion is rotatably supported around a means that acts as a rotation shaft provided in the support portion, and when the first member is placed in the mounting region, the ultrasonic probe is provided from the back side of the mounting region. A lever having a contactable first end and a second end located on the opposite side of the first end and the rotation axis.
The first member placed in the mounting area is sandwiched between the ultrasonic probe and mounted so as to be fitted with the second end of the lever. At the time of mounting, the first member of the lever is mounted via the rotation. An adapter comprising a second member that pushes an end toward the first member. The lever temporarily fastens the first member when the first end comes into contact with the ultrasonic probe from the back side of the mounting region, and the first end is expanded by the second member pushing the second end. The adapter according to claim 1, wherein the first member is finally fastened by further pushing the ultrasonic probe. The adapter according to claim 2, wherein the first end does not come into contact with the ultrasonic probe except for temporary fastening and final fastening when the position changes due to the rotation. The adapter according to claim 2, wherein the position with respect to the ultrasonic probe to which the first end is temporarily fastened is substantially the same as the position with respect to the ultrasonic probe to which the first end is finally fastened. The adapter according to claim 2, wherein a force is generated on the second member in the direction of sandwiching the first member by elastically deforming the lever in the main fastened state. The adapter according to claim 5, wherein the elastic deformation is equal to or larger than the thickness of the probe cover when the probe cover is used at the first end. An ultrasonic probe with a mounting area and
It is equipped with an adapter that can be attached to the attachment area.
The adapter
When placed in the mounting region, a first member that partially protrudes from the end face of the ultrasonic probe as a support portion in the extending direction of the probe flat surface portion, and
The support portion is rotatably supported around a means that acts as a rotation shaft provided in the support portion, and when the first member is placed in the mounting region, the ultrasonic probe is provided from the back side of the mounting region. A lever having a contactable first end and a second end located on the opposite side of the first end and the rotation axis.
The first member placed in the mounting area is sandwiched between the ultrasonic probe and mounted so as to be fitted with the second end of the lever. At the time of mounting, the first member of the lever is mounted via the rotation. An ultrasonic probe with an adapter that includes a second member that pushes the end toward the first member. The lever temporarily fastens the first member when the first end comes into contact with the ultrasonic probe from the back side of the mounting region, and the first end is expanded by the second member pushing the second end. 7. The ultrasonic probe with an adapter according to claim 7, wherein the first member is finally fastened by further pushing the ultrasonic probe. The ultrasonic probe with an adapter according to claim 7 or 8, wherein the ultrasonic probe has a configuration for hooking the first end pushed by the ultrasonic probe on the back side of the mounting region.

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