JP2020069395A - In-vivo imaging device and in-vivo imaging system - Google Patents

Abstract

To provide an in-vivo imaging device capable of shortening an endoscopic operation time and reducing a burden on a patient by improving operability of an operator.SOLUTION: In an in-vivo imaging device (3), an imaging unit (camera unit 11) is rotatable relative to a support tube (13) and is biased toward a predetermined rotational position.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an in-vivo imaging device and an in-vivo imaging system.

  Endoscopic surgery is a minimally invasive surgery in which examinations and therapeutic procedures are performed without opening the patient. In endoscopic surgery, a treatment tool such as forceps and an endoscope are separately introduced into a body cavity through a tubular instrument (trocar) that punctures a body wall (for example, abdominal wall) of the patient's abdomen or the like.

  The surgeon performs an operation while capturing an image of the distal end portion of the treatment instrument inserted in the body cavity within the observation visual field of the endoscope and observing the treatment state of the affected part by the treatment instrument. When performing a procedure such as incision or suturing of an organ, a surgeon brings an endoscope close to the organ and magnifies an image for observation, but then the field of view becomes very narrow. Therefore, there is a demand for the realization of an apparatus capable of widely grasping the state outside the work area (for example, the movement of the treatment tool outside the work area, the bleeding state, the residual state of the residue such as gauze).

  The in-vivo imaging device disclosed in Patent Document 1 is a device that meets such a demand. The camera unit that can be introduced into the body cavity is connected to the trocar in the body cavity. Further, the connection between the camera unit and the trocar is performed via a support tube through which a cable is passed. As a result, the in-vivo imaging device of Patent Document 1 enables execution of connection work within the body cavity, reliable fixation, and securement of communication by a cable, and by fixing the trocar, the range including the work area from an appropriate position. It is possible to shoot.

International Publication WO2016203864A1

  In order to reduce the burden on the patient, the in-vivo imaging device of Patent Document 1 is required to be further improved so that the operator can perform the treatment work more efficiently. For example, if the treatment tool comes into contact with the camera unit during the treatment work, the photographing screen changes from the angle desired by the operator, and the operator has to perform an operation of returning it, which is complicated. ..

  An object of one embodiment of the present invention is to solve the above problems and to realize an in-vivo imaging device capable of shortening the endoscopic surgery time by improving the workability of an operator and reducing the burden on the patient. And

  Further, one embodiment of the present invention realizes an in-vivo imaging system that solves the above problems and enables reduction of endoscopic surgery time by improving workability of an operator and reduction of a burden on a patient. The purpose is to

(1) According to one embodiment of the present invention, an imaging unit (camera unit) that can be introduced into the body and a support tube that has at least one end part that can be introduced into the body and that has a convex joint with the imaging unit. And a cable (camera-side cable) that is connected to the imaging section and passes through the support tube, and the imaging section is connected to the convex joint section of the support tube when the imaging section is joined. The in-vivo imaging device is characterized by being rotatable with respect to the support tube and being biased toward a predetermined rotation position.
(2) In an embodiment of the present invention, in addition to the configuration of (1), the imaging unit has a torsion coil spring into which the convex joint of the support tube is inserted, and the torsion coil spring is The in-vivo imaging device is characterized in that the imaging unit is biased toward a predetermined rotation position with respect to the support tube.
(3) In an embodiment of the present invention, in addition to the configuration of (2) above, the torsion coil spring has a claw portion at an end opposite to a side fixed to the main body of the imaging unit, A support tube has a groove portion in the convex joint portion, and the claw portion and the groove portion engage with each other when the image pickup portion is joined to the convex joint portion of the support tube. It is an in-vivo imaging device.
(4) An embodiment of the present invention is characterized in that, in addition to the configuration of (3), a plurality of the groove portions are provided on the circumference of the convex joint portion of the support tube. Is.
(5) In an embodiment of the present invention, in addition to the configuration of (3) or (4), the groove portion is opened in a taper shape with respect to an end portion of the support tube that is joined to the imaging unit. And an in-vivo imaging device.
(6) In an embodiment of the present invention, in addition to the configurations of (1) to (5) above, the support tube is connected to a tubular device (troker) whose one end is introduced into the body (troker). The in-vivo image pickup device is characterized in that it has a connection part) on the side opposite to the end on the side where it is joined to the image pickup part.
(7) An embodiment of the present invention is an in-vivo imaging device, characterized in that, in addition to the configuration of (6), the connection portion of the support tube is made of an elastic body.
(8) According to an embodiment of the present invention, the in-vivo imaging device according to any one of (1) to (5) above, a control device for the in-vivo imaging device, and an image display for displaying an image captured by the in-vivo imaging device. An in-vivo imaging system, comprising: a device.
Is.
(9) An embodiment of the present invention includes the in-vivo imaging device according to (6) above, a control device for the in-vivo imaging device, and an image display device for displaying an image captured by the in-vivo imaging device. And an in-vivo imaging system.
(10) An embodiment of the present invention includes the in-vivo imaging device according to (7) above, a control device for the in-vivo imaging device, and an image display device for displaying an image captured by the in-vivo imaging device. And an in-vivo imaging system.

  According to one aspect of the present invention, it is possible to realize an in-vivo imaging device that can shorten the endoscopic surgery time by improving the workability of the operator and reduce the burden on the patient.

  Further, according to one aspect of the present invention, it is possible to realize an in-vivo imaging system that can shorten the endoscopic surgery time by improving the workability of the operator and reduce the burden on the patient.

It is a schematic diagram which shows the structure of the in-vivo imaging system and in-vivo imaging device which concern on Embodiment 1 of this invention. (A), (b) is a longitudinal cross-sectional view and a top view which show typically the camera unit concerning Embodiment 1 of this invention. (A)-(f) is a schematic diagram which shows in sequence the installation method to the patient of the in-vivo imaging device which concerns on Embodiment 1 of this invention. It is a schematic diagram which shows the use condition of the in-vivo imaging system which concerns on Embodiment 1 of this invention. (A) is a schematic diagram which shows the junction part of a support tube and a camera unit regarding Embodiment 1 of this invention. (B) is an enlarged view near the concave joint, (c) is a view showing a torsion coil spring of the concave joint, and (d) is an enlarged view near the convex joint. (A), (b) is a schematic diagram of the convex joint part regarding Embodiment 1 of this invention in the state which the torsion coil spring engaged, and its cross-sectional view. (A), (b) is a schematic diagram which shows the structure of the concave type junction part regarding Embodiment 2 of this invention, and a cross-sectional view. (C), (d) is a longitudinal cross-sectional view and a cross-sectional view showing a state in which a convex joint is joined thereto. (B), (a) is a schematic diagram of the state which the torsion coil spring engaged of the convex-shaped joint part regarding Embodiment 3 of this invention, and its cross-sectional view. (B), (a) is a schematic diagram of the state which the torsion coil spring engaged of the convex-shaped joint part regarding Embodiment 3 of this invention, and its cross-sectional view. (A)-(c) is a schematic diagram which sequentially shows the condition which the convex-shaped joint part regarding Embodiment 4 of this invention engages with a torsion coil spring. (B), (a) is a schematic diagram of the convex joint part regarding Embodiment 5 of this invention in the state which the torsion coil spring engaged, and its cross-sectional view. (A) is a schematic diagram which shows the convex-type joint part regarding Embodiment 6 of this invention. (B), (c) is the schematic diagram of the state which the torsion coil spring engaged with it, and its cross-sectional view. It is a schematic diagram which shows the support tube and camera unit regarding Embodiment 7 of this invention. (A) is a longitudinal cross-sectional view showing a support tube and a camera unit in an in-vivo imaging device of a comparative example. (B) is a schematic diagram of the vicinity of the joint portion, and (c) is a top view of the camera unit.

  Embodiments of the present invention will be described below. In addition, the shape of the configuration described in each drawing, and the dimensions such as length, size, and width do not necessarily accurately reflect the actual shape and dimensions, and for the sake of clarity and simplification of the drawings. Has been changed to

[Embodiment 1]
The first embodiment of the present invention will be described in detail with reference to FIGS. 1 to 6.

(Structure of in-vivo imaging system)
The configuration of the in-vivo imaging system 1 according to the first embodiment is shown in FIG. The in-vivo imaging system 1 includes the in-vivo imaging device 3 according to the first embodiment, a device-side cable 16, a device-side cable connector 161, a control device 17, and an image display device 18. The in-vivo imaging device 3 includes a camera unit 11 (imaging unit), a camera side cable 12 (cable), a camera side cable connector 121, and a support tube 13.

  The camera unit 11 is electrically connected to the control device 17 via the camera side cable 12 and the device side cable 16. The camera side cable 12 and the device side cable 16 can be connected by a camera side cable connector 121 and a device side cable connector 161 provided respectively. As a result, the control device 17 controls the camera unit 11 to perform the control necessary for shooting, and receives the video imaged by the camera unit 11. The control device 17 causes the image display device 18 to display the video received from the camera unit 11. Note that the control device 17 and the image display device 18 do not have to be housed in separate housings, and may be integrally configured.

  The in-vivo imaging system 1 employs a wired system that uses the camera-side cable 12 for signal transmission and power supply between the camera unit 11 and the control device 17. As a result, the signal transmission can be speeded up and the signal transmission / reception is stabilized. Further, by adopting the wired system, communication can be performed with lower power as compared with the wireless system, and the heat generation of the camera unit 11 is small. Furthermore, the camera unit 11 is downsized by supplying power from the outside, and the puncture hole (port) for introducing the camera unit 11 into the body can be reduced. Therefore, the in-vivo imaging device 3 can be made less invasive and the burden on the patient can be reduced.

  The support tube 13 is a tubular member having a vertical through hole. The camera-side cable 12 passes through the through hole, and the support tube 13 is movable along the camera-side cable 12. The support tube 13 has a guide introduction part 131, a trocar connection part 132 (a connection part with a tubular instrument whose one end is introduced into the body), a root part 133, and a convex joint part 134 in this order from the top. ing. Here, the up and down directions are for convenience of description of the support tube 13.

  The guide introducing portion 131 can be inserted into the tube of the trocar 31 (a tubular device whose one end is introduced into the body). The trocar connection portion 132 is a tapered truncated cone-shaped portion whose diameter expands downward from the lower end of the guide introduction portion 131. The trocar connection part 132 may contact the end of the trocar 31 inside the body, and the trocar 31 and the support tube 13 may be fixed. The root portion 133 is a tapered truncated cone-shaped portion whose diameter is narrowed downward from the lower end of the trocar connection portion 132. The convex joint portion 134 at the lower end of the support tube 13 is a portion that is joined to the concave joint portion 14 of the camera unit 11.

  FIG. 1 is a schematic diagram showing a state where the in-vivo imaging device 3 is installed in a patient. In FIG. 1, in addition to the in-vivo imaging system 1, an abdominal wall 41 of a patient and a trocar 31 (tubular device) punctured in the abdominal wall 41 are shown together. A method of fixing the camera unit 11 inside the patient using the trocar 31 (a method of installing the in-vivo imaging device 3 in the patient) will be described later. Although the body wall is described as the abdominal wall 41 in the first embodiment, the body wall is not limited to the abdominal wall 41.

(Camera unit configuration)
FIG. 2 is a schematic diagram showing the configuration of the camera unit 11, which is a main part of the in-vivo imaging device 3. 2A is a side sectional view, and FIG. 2B is a top view. The camera unit 11 includes a camera housing 111. An imaging element 115, a lens 116, a lighting element 117, a control circuit 118, and a circuit board 119 are provided inside the camera housing 111. The circuit board 119 is electrically connected to the image pickup element 115, the lighting element 117, and the control circuit 118, and exchanges electric power, signals, and the like with each other.

  The image sensor 115 captures an image of the outside of the camera unit 11 through the lens 116. The image pickup device 115 is preferably small and has low power consumption, and a CCD (Charge Coupled Device) or a CMOS (Complementary Metal Oxide Semiconductor) image sensor is preferably used. The illumination element 117 illuminates the field of view for making the image captured by the camera unit 11 clear. The lighting element 117 is preferably small, and for example, an LED (Light Emitting Diode) or the like can be preferably used. It should be noted that a single lighting element 117 may be provided in the camera housing 111, but a plurality of lighting elements 117 may be provided as shown in FIG. The control circuit 118 performs an operation instruction of the image pickup element 115, control of imaging conditions, control of the operation of the illumination element 117, and the like based on an instruction from the control device 17.

  The concave joint 14 is provided on the upper surface of the camera housing 111. The concave joint portion 14 has a hole structure with a circular opening, and the convex joint portion 134 of the support tube 13 can be attached and detached. The state of joining the camera unit 11 and the support tube 13 will be described later in detail.

  A grip portion 112 is provided on each of both opposing side surfaces of the camera housing 111. The operator can change the direction or move the camera unit 11 introduced into the body by grasping the grip portion 112 with forceps.

  The camera-side cable 12 is electrically connected to the circuit board 119 and is led to the outside of the camera unit 11 so as to pass through the inside of the concave joint portion 14. The connection point between the circuit board 119 and the camera side cable 12 is sealed with resin or the like. Further, the camera-side cable 12 is adhesively fixed to the bottom of the concave joint 14 at the portion inside the concave joint 14 where the camera-side cable 12 is pulled out (the bottom of the concave joint 14). As an example of the adhesive fixing, sealing and fixing with an adhesive or an O-ring (o-ring) is performed, and the configuration is such that water intrusion or foreign matter mixing into the camera unit 11 from this portion does not occur. Since the camera side cable 12 is introduced into the body cavity through the trocar 31, it is made of a flexible material. The camera-side cable 12 has sufficient strength to fix the camera unit 11 to the trocar 31 by tension.

(Basic usage of in-vivo imaging device)
Next, a method of installing the in-vivo imaging device 3 on a patient will be described. 3A to 3F are schematic diagrams sequentially showing a method of installing the in-vivo imaging device 3 in a patient.

  As shown in FIG. 3A, the operator first opens a puncture hole (port) in the abdominal wall 41 for inserting the forceps 33a to 33c and the endoscope 34 into the body cavity, and the trocar 32a to the port. 32c is inserted. Further, in order to install the camera unit 11 in the body cavity, a port is opened at a position in the abdominal wall 41 where a location including the affected part can be overlooked (a position where the inside of the body can be observed from a bird's eye view), and the trocar 31 is inserted. Specifically, the trocar 31 is inserted into the abdominal wall 41 by puncturing the obturator at the port position with the needle-shaped obturator passing through the trocar 31.

  The trocar 31 preferably has a short diameter in order to achieve low invasiveness. Specifically, the trocar 31 preferably has a diameter of 3 mm or less. After at least one of the trocars 32a to 32c and the trocar 31 is inserted, the operator sends gas through the trocar into the body to expand the inside of the body cavity in advance and secure a space for inserting the device.

  Next, as shown in FIG. 3B, the operator inserts the endoscope 34 into the body cavity through the trocar 32c, and observes the inside of the body using the endoscope 34. While observing the inside of the body, the operator inserts the camera unit 11 grasped by the forceps 33a, the camera side cable 12, and the support tube 13 passed through the camera side cable 12 into the body cavity through the trocar 32b.

  Next, as shown in FIG. 3C, the operator operates the forceps 33a to move the camera unit 11 to the vicinity of the trocar 31, and inserts the forceps 33b through the trocar 31 into the body cavity.

  Next, as shown in FIG. 3D, the operator pulls out the forceps 33b from the trocar 31 while holding the camera-side cable 12 between the forceps 33b, and thereby leads the camera-side cable 12 out of the body. .. At this time, the camera unit 11 (its grip portion 112) is in a state of being gripped by the forceps 33a. Thus, the camera side cable connector 121 is pulled out from the inside of the body through the trocar 31. Therefore, the outer diameter of the camera-side cable connector 121 is at least smaller than the inner diameter of the trocar 31. In other words, if the outer diameter of the camera-side cable connector 121 is reduced, the inner diameter of the trocar 31 can be reduced, and further the diameter of the support tube 13 can be reduced. As a result, the in-vivo imaging system 1 has an effect of improving minimally invasiveness. Although the example in which the camera unit 11 side is inserted into the body cavity is illustrated, the camera side cable connector 121 side is first inserted into the body cavity, and the camera unit 11 is inserted into the body after grasping it with forceps. The procedure of inserting it does not matter.

  Next, as shown in (e) of FIG. 3, the operator pulls the camera-side cable 12 led out of the body with forceps or a hand to bring the upper end of the support tube 13 close to the opening of the trocar 31. ..

  Next, as shown in FIG. 3 (f), the operator further pulls up the camera-side cable 12 and the camera unit 11 so that the guide introducing portion 131 at the upper end of the support tube 13 and the upper portion of the trocar connecting portion 132 are trocared. Insert it into the inner end of 31. The outer shape of the trocar connection portion 132 of the support tube 13 is a truncated cone shape, and the upper end of the support tube 13 is inserted into the tube of the trocar 31, so that the tapered portion of the trocar connection portion 132 is located at the inner end of the trocar 31. Contact. In this way, the support tube 13 and the trocar 31 are connected. Further, the operator fits the convex joint portion 134 of the support tube 13 into the concave joint portion 14 of the camera unit 11. In this way, the upper side of the support tube 13 (the trocar connecting portion 132) is connected to the inner end of the trocar 31, and the lower end of the support tube 13 (the convex joint portion 134) and the concave joint portion 14 of the camera unit 11 are connected. To join. Then, the camera side cable 12 is fixed so as to maintain the tension of the camera side cable 12 pulling up the camera unit 11.

  In this way, the camera unit 11 is fixed to the trocar 31, and is in the state shown in FIG.

  The usage status of the in-vivo imaging system 1 at the time of treatment after the camera unit 11 is installed in the body is as follows.

  FIG. 4 is a schematic diagram showing a usage situation of the in-vivo imaging system 1. The camera side cable connector 121 is fitted into the device side cable connector 161, and the camera side cable 12 and the device side cable 16 are connected. As a result, the entire image of the inside of the organ 42 taken by the camera unit 11 is displayed on the image display device 18 by the control device 17. In addition, the local image of the treatment portion taken by the endoscope 34 is displayed on the endoscopic image display device 68 by the endoscopic control device 67.

  Therefore, when performing a procedure such as incision or suturing of an organ, the operator can bring the endoscope 34 close to the organ and magnify an image for observation. Furthermore, the operator uses the in-vivo imaging system 1 to check the overall condition including the condition outside the treatment work area (for example, the movement of the treatment tool outside the work region, the bleeding condition, the residual condition of the residue such as gauze). I can figure it out. Therefore, surgery can be performed more efficiently than when only the endoscope 34 is used for observation.

  The collection of the camera unit 11 after use is as follows.

  First, the operator releases the tension of the camera-side cable 12 while holding the grip portion 112 of the camera unit 11 inside the body with the forceps 33a. Then, the operator separates the support tube 13 and the camera unit 11 by sandwiching the base portion 133 of the support tube 13 with another forceps 33c and sliding the forceps along the taper. Next, the operator separates the support tube 13 from the trocar 31, and then pulls the camera unit 11, the camera-side cable 12, and the support tube 13 out of the body from the trocar 32b. In this way, the camera-side cable 12 and the camera-side cable connector 121 are temporarily returned to the inside of the body when the camera unit 11 is collected. Therefore, the device side cable connector 161 and the part of the device side cable 16 having a predetermined length in contact with the camera side cable 12 need to be kept clean.

  In the example of FIG. 3, the forceps 33b inserted from the trocar 31 is used to pull the tip of the camera-side cable 12 out of the body, but the camera-side cable 12 can be connected to the camera-side cable connector 121 in order to pull it up. You may use the dedicated jig mentioned above. For example, a structure in which a magnet or a magnetic body is attached to the tip of the camera-side cable connector 121, a drawer (not shown) having a holding magnet at the tip is inserted into the trocar 31, and pulled out by using the magnetic attraction. May be

(Structure of the part where the support tube and the camera unit are joined)
Next, with respect to the portion where the support tube 13 and the camera unit 11 are joined, which is a characteristic configuration of the in-vivo imaging system 1 and the in-vivo imaging device 3 according to the first embodiment, based on FIGS. Explained.

  FIG. 5A is a schematic diagram showing a state where the support tube 13 approaches the camera unit 11 before joining. In the figure, the guide introduction portion 131 of the support tube 13 is inserted inside the trocar 31, and the end portion of the trocar 31 and the trocar connecting portion 132 are in contact with each other.

  FIG. 5B is an enlarged view showing the concave joint portion 14 of the camera unit 11. The concave joint portion 14 is provided with a torsion coil spring 141 fixed to the camera unit 11. The torsion coil spring 141 is installed so that the convex joint portion 134 of the support tube 13 can be inserted into the coil. In addition, a claw portion 142 that protrudes toward the inside of the coil is provided near the end of the torsion coil spring 141 that is not fixed to the camera unit 11. FIG. 5C is a diagram showing only the torsion coil spring 141.

  FIG. 5D is an enlarged view showing the convex joint portion 134 of the support tube 13. The convex joint portion 134 includes a groove portion 135 that extends in the vertical direction (the extending direction of the through hole of the support tube 13).

  FIG. 6A shows a torsion coil spring 141 when the camera unit 11 and the support tube 13 are fixed to each other by inserting the trocar connecting portion 132 of the support tube 13 into the concave joint section 14 of the camera unit 11. FIG. 6 is a diagram showing a state of the convex joint portion 134. Further, FIG. 6B is a cross-sectional view taken along a plane perpendicular to the vertical direction at a position passing through the claw portion 142 in FIG. 6A. In the cross-sectional view, the display of the internal structure such as the situation where the camera-side cable 12 inside the support tube 13 passes is omitted, and the same applies to the following. In the in-vivo imaging device 3, the claw portion 142 of the torsion coil spring 141 is configured to enter the groove portion 135 of the trocar connection portion 132, and the claw portion 142 and the groove portion 135 are engaged with each other.

(effect)
In Patent Document 1, as a method of joining the concave joint portion of the camera unit and the convex joint portion of the support tube, a locking claw provided in the concave joint portion is provided in the circumferential direction in the convex joint portion. It is disclosed to engage and fix the annular groove. FIG. 14 shows an in-vivo imaging device as a comparative example using such a fixing method. The in-vivo imaging device according to the present comparative example is the same as the in-vivo imaging device 3 according to the first embodiment except that the configuration of the support tube 13r and the configuration of the concave joint portion 14r of the camera unit 11r are different from those of the first embodiment. ..

  FIG. 14A is a sectional view schematically showing a state where the support tube 13r approaches the camera unit 11r before joining. FIG. 14B is an enlarged view showing the vicinity of the convex joint portion 134r of the support tube 13r. Unlike the convex joint portion 134 of the first embodiment, in the support tube 13r, the trocar conical portion 132r has an elongated truncated cone shape, and its elongated tip portion is a guide introduction portion that is inserted into the trocar. Also has the role of. Further, the support tube 13r does not have a root portion, and the convex joint portion 134 is provided directly below the trocar connecting portion 132r. Further, a ring-shaped groove 137 is provided in the circumferential direction on the convex joint portion 134r.

  FIG. 14C is a top view of the camera unit 11r, and shows an example of the locking claw 144 with which the annular groove 137 of the convex joint portion 134r is engaged. Unlike the concave joint portion 14 of the first embodiment, the concave joint portion 14r includes such a locking claw 144. The locking claw 144 is made of an elastic member, and is configured such that the locking claw 144 engages with the ring-shaped groove 137 when the convex joint portion 134r is pushed. Further, by applying a force to separate the convex joint portion 134r from the concave joint portion 14r, it is possible to release the engagement of the locking claw 144 with the ring-shaped groove 137, and the camera unit 11r with respect to the support tube 13r. It is removable.

  In such a comparative example, when forceps or other treatment tool contacts the camera unit 11r during the operation of the operator, the orientation of the camera unit 11r may be rotated. If the orientation of the camera unit 11r rotates, the photographing screen will rotate, and the photographing screen will change from the angle desired by the operator. Then, it is very difficult for the operator who operates the treatment tool by looking at the photographing screen to operate the treatment tool. The operator has to perform an operation such as returning the rotation direction of the camera unit 11r in the body using the treatment tool, which is a problem in that it is complicated.

  On the other hand, in order to prevent the camera unit 11r from rotating, it is conceivable that the groove of the convex joint portion 134r with which the locking claw 144 engages is not formed in a ring shape but is formed as a recess only for the locking claw 144 to engage. In this case, however, the camera unit 11r cannot move even if a forceps or other treatment tool comes into contact with the camera unit 11r during the treatment work. Therefore, the engagement of the locking claw 144 with the groove may be disengaged, and if this happens, the operator must perform an operation for re-engagement, which is a complicated problem.

  In the in-vivo imaging system 1 or the in-vivo imaging device 3 according to the first embodiment, the claw portion 142 of the torsion coil spring 141 provided in the concave joint portion 14 of the camera unit 11 and the convex joint portion 134 of the support tube 13 are provided. The groove portion 135 extending in the vertical direction (extending direction of the through hole of the support tube 13) is engaged. Therefore, even if the forceps or other treatment tool comes into contact with the camera unit 11r during the treatment work of the operator, the camera unit 11 can rotate within the range of the elasticity of the torsion coil spring 141 with respect to the support tube 13. Therefore, the engagement of the claw portion 142 with the groove portion 135 is rarely disengaged. Moreover, when the contact is released, the camera unit 11 returns to the original rotational position (predetermined rotational position) by the biasing force applied by the torsion coil spring 141. Therefore, the problem that the rotation of the camera unit 11 makes it difficult to confirm the part to be treated is solved.

  As described above, the torsion coil spring 141 causes the pawl portion 142 to move to the steady position (predetermined position) when the pawl portion 142 rotates in the direction deviating from the steady position regardless of the clockwise or counterclockwise rotation direction. An urging force (elastic force) that pulls back to the rotational position) is applied. That is, the torsion coil spring 141 gives an urging force (elastic force) that pulls the camera unit 11 back to the steady position when the camera unit 11 rotates in a direction deviating from the predetermined steady position with respect to the support tube 13.

  Therefore, in the in-vivo imaging system 1 and the in-vivo imaging device 3, the camera unit 11 rarely interferes with the operation of the forceps and other treatment tools during the operation of the operator. Further, it is also possible to prevent the operator from being forced to perform operations such as re-adjusting the rotational position of the camera unit 11 and re-engaging the disengagement of the camera unit 11. Therefore, the operator can perform the treatment work on the patient extremely efficiently. As a result, the burden on the patient due to endoscopic surgery can be reduced.

[Embodiment 2]
Hereinafter, the in-vivo imaging system and the in-vivo imaging device according to the second embodiment will be described. For convenience of description, members having the same functions as the members described in the above embodiment will be designated by the same reference numerals, and the description thereof will not be repeated.

  The in-vivo imaging system and the in-vivo imaging device according to the second embodiment are the same as the in-vivo imaging system 1 and the in-vivo imaging device 3 according to the first embodiment except that the configuration of the concave joint portion of the camera unit is different.

  FIG. 7 is a diagram illustrating the concave joint portion 14a in the in-vivo imaging system and the in-vivo imaging device according to the second embodiment. FIG. 7A is a diagram showing the torsion coil spring 141 arranged in the concave joint portion 14 a, and is a diagram corresponding to FIG. 5C in the first embodiment. 7B is a cross-sectional view taken along a plane perpendicular to the vertical direction at a position passing through the claw portion 142 in FIG. 7A. Unlike the concave joint portion 14 of the first embodiment, in the concave joint portion 14a, the torsion coil spring 141 is covered with the cover 143 except for the claw portion 142, and most of the torsion coil spring 141 is directly exposed to the outside. Never exposed.

  FIG. 7C shows a convex joint with the torsion coil spring 141 and the like when the convex joint portion 134 of the support tube 13 is inserted into the concave joint portion 14a and the camera unit and the support tube 13 are fixed to each other. It is a figure which shows the state of the part 134. FIG. 7C is a cross-sectional view taken along a plane perpendicular to the vertical direction at a position passing through the coil centers of the claw portion 142 and the torsion coil spring 141, and is located at a position indicated by XX in FIG. 7A. Equivalent to. Further, FIG. 7D is a cross-sectional view taken along a plane Y-Y perpendicular to the vertical direction at a position passing through the claw portion 142 in FIG. 7C. Also in the in-vivo imaging system and the in-vivo imaging device according to the second embodiment, the claw 142 of the torsion coil spring 141 is configured to enter the groove 135 of the trocar connection part 132, and the claw 142 and the groove 135 are engaged with each other. The difference is similar to the first embodiment.

  The cover 143 is configured so that the claw portion 142 is movable in the rotational direction with respect to the camera unit. Therefore, the cover 143 may be made of a hard material and installed so as to be rotatable with respect to the camera unit. Further, the cover 143 may be made of an elastic film such as rubber. Alternatively, the cover 143 may be formed of a flexible film that allows the claw portion 142 to move.

  Also according to the second embodiment, the same effects as the effects described in the first embodiment can be obtained. Furthermore, since the torsion coil spring 141 is not directly exposed except for the claw portion 142, it is easy to clean the in-vivo imaging device according to the second embodiment.

[Embodiment 3]
The in-vivo imaging system and the in-vivo imaging device according to the third embodiment are the same as the in-vivo imaging system 1 and the in-vivo imaging device 3 according to the first embodiment except that the configuration of the convex joint portion of the support tube is different.

  FIG. 8B is a diagram showing the convex joint portion 134a in the in-vivo imaging system and the in-vivo imaging device according to the third embodiment. The figure shows a state in which the claw portions 142 of the torsion coil spring 141 are engaged. 8A is a cross-sectional view taken along a plane perpendicular to the vertical direction at a position passing through the claw portion 142 of FIG. 8B.

  Further, FIG. 9 is a diagram in which the concave joint portion 14a according to the second embodiment is applied to the in-vivo imaging system and the in-vivo imaging device according to the third embodiment. FIG. 9B is a diagram showing the convex joint portion 134a in a state where the claw portions 142 of the torsion coil spring 141 are engaged. 9A is a sectional view taken along a plane perpendicular to the vertical direction at a position passing through the claw portion 142 of FIG. 9B.

  As shown in FIGS. 8 and 9, unlike the convex joint portion 134 of the first embodiment, in the convex joint portion 134a, the convex joint portion 134a has a circumference in the vertical direction (through hole of the support tube 13). A plurality of groove portions 135 extending in the drawing direction) are provided. Therefore, it is possible to easily engage the claw portion 142 with any of the groove portions 135, and the joining of the camera unit and the support tube becomes easier than in the case of the first embodiment. Furthermore, according to the third embodiment, the same effect as the effect described in the above embodiment can be obtained.

[Embodiment 4]
The in-vivo imaging system and the in-vivo imaging device according to the fourth embodiment are the same as the in-vivo imaging system 1 and the in-vivo imaging device 3 according to the first embodiment except that the configuration of the convex joint portion of the support tube is different.

  FIG. 10 is a diagram showing the convex joint portion 134b in the in-vivo imaging system and the in-vivo imaging device according to the fourth embodiment. A torsion coil spring 141 is also shown in the figure, and from (a) to (c), the operation in which the convex joint portion 134b approaches the torsion coil spring 141 (or the concave joint portion 14) and is joined is shown. It is shown. The convex joint portion 134b is provided with a plurality of groove portions 131b, and each of the groove portions 135b has a tapered region 136 in which the groove width gradually expands toward the lower end of the convex joint portion 134b at the lower end portion of the convex joint portion 134b. Have

  In FIG. 10A, when the convex joint portion 134b approaches the torsion coil spring 141 (A), the tapered region 136 hooks the claw portion 142 in FIG. 10B. Then, even if the center of the groove portion 135b and the claw portion 142 are slightly deviated from each other, when the convex joint portion 134b is further pushed into the coil spring 141, the claw portion 142 is fitted into the center of the groove portion 135b ( B). At that time, since the torsion coil spring 141 is fixed to the camera unit 11, the camera unit 11 itself is slightly rotated with respect to the convex joint portion 134b (support tube) to perform (C) adjustment. Then, in FIG. 10C, while the claw portion 142 is engaged with the groove portion 135b, the convex joint portion 134b is pushed deep into the concave joint portion 14 (D), and the convex joint portion 134b and the concave joint portion 134b are depressed. Joining with the joining portion 14 is completed.

  According to the fourth embodiment, since the tapered region 136 of the groove 135b is formed at the lower end of the convex joint portion 134b, the convex joint portion 134b and the concave joint portion 14 can be easily joined. Furthermore, according to the fourth embodiment, the same effect as that described in the above embodiment can be obtained.

[Embodiment 5]
The in-vivo imaging system and the in-vivo imaging device according to the fifth embodiment are the same as the in-vivo imaging system and the in-vivo imaging device according to the third embodiment except that the configuration of the convex joint portion of the support tube is different.

  FIG. 11B is a diagram illustrating the convex joint portion 134c in the in-vivo imaging system and the in-vivo imaging device according to the fifth embodiment. The figure shows a state in which the claw portions 142 of the torsion coil spring 141 are engaged. 11A is a cross-sectional view taken along a plane perpendicular to the vertical direction at a position passing through the claw portion 142 of FIG. 11B. Unlike the convex joint portion 134a of the third embodiment, in the convex joint portion 134a, the groove portion 135c has a trapezoidal shape in which the cross section of the groove portion 135c significantly expands outward in the radial direction of the convex joint portion 134a. Therefore, it is possible to easily engage the claw portion 142 with the groove portion 135c, and it becomes easier to join the camera unit and the support tube as compared with the case of the third embodiment. Also, the same effects as those of the third embodiment can be obtained by the fifth embodiment.

[Sixth Embodiment]
The in-vivo imaging system and the in-vivo imaging device according to the sixth embodiment are the same as the in-vivo imaging system and the in-vivo imaging device according to the third embodiment except that the configuration of the convex joint portion of the support tube is different.

  FIG. 12A is a diagram showing the convex joint portion 134d in the in-vivo imaging system and the in-vivo imaging device according to the fifth embodiment. FIG. 12B further shows a state in which the claw portion 142 of the torsion coil spring 141 is engaged. FIG. 12C is a sectional view taken along a plane perpendicular to the vertical direction at a position passing through the claw portion 142 of FIG. 12B. Unlike the convex joint portion 134a of the third embodiment, in the convex joint portion 134d, a plurality of groove portions 135d cover the entire circumference of the lower portion of the convex joint portion 134d, and the groove portion 135d is continuous. Is formed. Further, each cross section of the groove portion 135d has an arc shape. Therefore, it is possible to easily engage the claw portion 142 with the groove portion 135d, and it becomes easier to join the camera unit and the support tube as compared with the case of the third embodiment. Further, according to the sixth embodiment, the same effect as that of the third embodiment can be obtained.

[Embodiment 7]
The in-vivo imaging system and the in-vivo imaging device according to the seventh embodiment are the same as the in-vivo imaging system 1 and the in-vivo imaging device 3 according to the first embodiment except that the configuration of the trocar connecting portion of the support tube is different.

  FIG. 13 is a schematic diagram showing the support tube 13e and the camera unit 11 in the in-vivo imaging system and the in-vivo imaging device according to the seventh embodiment. Unlike the trocar connection part 132 of the first embodiment, the trocar connection part 132e of the support tube 13e is made of a material (elastic body) whose surface has elasticity. Therefore, when the trocar 31 and the trocar connecting portion 132e are fixed in contact with each other by the tension of the camera-side cable 12, the trocar 31 and the trocar connecting portion 132e are more reliably fixed. Therefore, the rotation of the camera unit 11 with respect to the trocar 31 due to the rotation between the support tube 13e and the trocar 31 can be more reliably prevented. Further, the same effects as the effects described in the first embodiment can be obtained by the seventh embodiment.

  Furthermore, applying the trocar connecting portion 132e according to the seventh embodiment to each of the above-described embodiments may be implemented as a more preferable configuration in each of the embodiments.

[Appendix]
In each of the embodiments, in the joint portion of the convex joint portion and the concave joint portion, the concave joint portion (groove portion) is provided on the convex joint portion side and the claw portion is provided on the concave joint portion (torsion coil spring) side, and they rotate relative to each other. It has been described as a configuration that engages so as to be locked in the direction. However, the claw portion may be provided on the convex joint portion side and the groove portion may be provided on the concave joint portion side.

  In each of the embodiments, when the camera unit rotates in a direction deviating from the predetermined steady position with respect to the support tube, a torsion coil spring is used as a component that applies a biasing force (elastic force) that pulls the camera unit back to the steady position. The example used was described. However, the application of the present invention is not limited to the torsion coil spring as long as it is a component that applies the required biasing force. For example, a spring other than the torsion coil spring, or a component made of an elastic body such as rubber may be appropriately configured.

  In each embodiment, when the in-vivo imaging device is installed in the patient, the camera unit is described as being fixed via a support tube to a tubular instrument (trocar) that is punctured in the body wall of the patient. It was However, the support tube itself may have a function as a tubular device that is punctured into the body wall of the patient. That is, the tubular device that is punctured into the body wall of the patient may have the convex joint portion in each embodiment at the lower end.

  The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the claims, and the embodiments obtained by appropriately combining the technical means disclosed in the different embodiments. Is also included in the technical scope of the present invention. Furthermore, new technical features can be formed by combining the technical means disclosed in each embodiment.

1 In-Body Imaging System 3 In-Body Imaging Device 11, 11r Camera Unit 111 Camera Housing 112 Grip Section 115 Imaging Element 116 Lens 117 Lighting Element 118 Control Circuit 119 Circuit Board 14, 14a, 14r Recessed Joint Section 141 Torsional Coil Spring 142 Claw Section 143 cover 144 locking claw 12 camera side cable 121 camera side cable connector 13, 13e, 13r support tube 131 guide introduction section 132, 132e trocar connecting section 133 root section 134, 134a, 134b, 134c, 134d, 134r convex joint section 135, 135b, 135c, 135d Groove portion 136 Tapered region 137 Ring groove 16 Device side cable 161 Device side cable connector 17 Control device 18 Image display device 31, 32a, 32b, 32c Trocar 3 a, 33b, 33c forceps 34 endoscope 41 abdominal wall 42 organ 67 endoscope control device 68 endoscopic image display device

Claims (10)

An imaging unit that can be introduced into the body,
At least one end portion can be introduced into the body, a support tube having a convex joint with the imaging unit,
A cable connected to the imaging unit and passing through the support tube,
When the imaging unit is joined to the convex joint of the support tube,
The in-vivo imaging device, wherein the imaging unit is rotatable with respect to the support tube and is biased toward a predetermined rotation position. The imaging unit has a torsion coil spring into which the convex joint of the support tube is inserted,
The in-vivo imaging device according to claim 1, wherein the torsion coil spring urges the imaging unit toward the predetermined rotational position with respect to the support tube. The torsion coil spring has a claw portion at the end opposite to the side fixed to the main body of the imaging unit,
The support tube has a groove portion in the convex joint portion,
The in-vivo imaging device according to claim 2, wherein the claw portion and the groove portion are engaged with each other when the imaging portion is joined to the convex joint portion of the support tube.   The in-vivo imaging device according to claim 3, wherein a plurality of the groove portions are provided on a circumference of a convex joint portion of the support tube.   The in-vivo imaging device according to claim 3, wherein the groove portion is opened in a taper shape with respect to an end portion of the support tube on the side where the support tube is joined to the imaging portion.   The support tube has a connection portion with a tubular instrument, one end portion of which is introduced into the body, on the side opposite to the end portion on the side where the imaging unit is joined. The in-vivo imaging device as described in any one of 1 above.   The in-vivo imaging device according to claim 6, wherein the connection portion of the support tube is made of an elastic body. An in-vivo imaging device according to any one of claims 1 to 5,
An in-vivo imaging system, comprising: a control device for the in-vivo imaging device; and an image display device for displaying an image captured by the in-vivo imaging device. An in-vivo imaging device according to claim 6;
An in-vivo imaging system, comprising: a control device for the in-vivo imaging device; and an image display device for displaying an image captured by the in-vivo imaging device. An in-vivo imaging device according to claim 7;
An in-vivo imaging system, comprising: a control device for the in-vivo imaging device; and an image display device for displaying an image captured by the in-vivo imaging device.

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