JP2009236963A - Training device for endoscopic surgery, and skill evaluation method for endoscopic surgery - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a training device for endoscopic surgery or the like, capable of performing training of an endoscopic surgery operation performed while viewing image of a surgery site and the recognition level of the state of the surgery site. <P>SOLUTION: In the device for training the operation of a medical apparatus used by an operator in an endoscopic surgery, objects within an endoscopic surgery training box 2 imaged by a camera device 2b are presented as a three-dimensional image on a dome screen 11 while changing the distance between the objects, the thickness of each object, the direction or height of each filamentary object, or the size of contour part of each object, and the operator is caused to perform a training task of operating the medical apparatus to hold the object or operating the medical apparatus to pass through the contour part of the object. The training start time and training end time are recorded by a control device 3, and the time required for one operation from the training start time to the training end time is stored. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an endoscopic surgical training apparatus and an endoscopic surgical skill evaluation method for training an operator in a surgical operation to operate a medical instrument.

Conventionally, endoscopic surgery (hereinafter referred to as “endoscopic surgery”) is a patient that has a great merit in that there are few surgical wounds, early bed removal and discharge are possible, and cosmetics are excellent. Invasive surgery. An endoscope system that realizes this endoscopic surgery includes an endoscope device that images an affected area, and a monitor that displays an image captured by the endoscope apparatus, and displays the state of the affected area on the monitor. In this state, the forceps inserted toward the affected area is operated to perform an operation on the affected area (see Non-Patent Document 1 below).
Supervision Makoto Hashizume, Planning / Editing Kozo Konishi Ken Okazaki Kazuo Tagami "Basic Technique Training for Safe Endoscopic Surgery Fundamental Training for Safe Endoscopic Surgery" Daido Gakukan Publishing Department, October 1, 2005

  The biggest problem of endoscopic surgery described above is that, unlike open surgery under direct vision, the surgeon who operates the forceps cannot directly see the surgical site, so the coordinated movement of the eyes and hands is taken. There is a point. In addition, in a suture and ligation work that requires recognition in the depth direction, surgery is particularly difficult.

  Therefore, the present invention has been proposed in view of the above-described situation, and endoscopic surgery training that can train the endoscopic surgery work performed by viewing the surgical site with images and the degree of recognition of the state of the surgical site. An object of the present invention is to provide an apparatus and a skill evaluation method for endoscopic surgery.

  The present invention is an endoscopic surgical training apparatus for training the operation of a medical instrument used by an operator in endoscopic surgery, and includes a distance between objects, a thickness of each object, and a thin line Change the orientation or height of the target object or the size of the ring-shaped part of the target object, present the target object in a video, and make the medical instrument contact the target object. Have the training task to perform the operation or the operation to pass the medical instrument to the ring-shaped part of the object, record the training start time and training end time, and perform one operation from the training start time to the training end time Memorize the time required.

  In addition, the present invention provides a sewing practice board and a predetermined number for training stitching and ligation with respect to a stitching practice board in which a plurality of target points are described in a plate-like material capable of passing a suture needle as a medical instrument. The image obtained by imaging the space including the reference position is presented, and the training start time and the training end time are recorded by performing the stitching work and the ligation work on the stitching practice board, and from the training start time to the training end time. Remember the time it takes to complete the training task.

  Furthermore, the present invention is an endoscopic surgical training apparatus for training an operator in endoscopic surgery, wherein the distance between at least two linear objects, the thickness of each object, or a predetermined shape is determined. Change the orientation or height of the thin line-shaped object formed, the size of the ring-shaped part of the object, present the object in the image, and the front-rear positional relationship of the object recognized by the operator, surgery The direction of the object recognized by the person is input, and the relationship between the input object's front-rear position, the correctness of the object direction or the front-rear position of the actual object, and the difference from the actual object direction is recorded. .

  The present invention displays an image by the presenting means, and changes the distance between the objects, the thickness of each object, the direction or height of the thin line object, or the size of the ring-shaped portion of the object. Since endoscopic surgery training can be performed, it is possible to train endoscopic surgery work performed by viewing the surgical site with images.

In addition, the present invention provides a stitching practice board and a predetermined stitch for training stitching and ligation with respect to a stitching practice board in which a plurality of target points are described in a plate-like material capable of passing a suture needle as a medical instrument. Since the image obtained by imaging the space including the reference position is presented, it is possible to train the operation of endoscopic surgery in which the surgical site is viewed with the image. Further, the present invention provides at least two linear objects. The degree of recognition by changing the distance or thickness of each object, the direction or height of the thin line-shaped object formed in a predetermined shape, the size of the ring-shaped part of the object, and presenting the object in a video Therefore, it is possible to train the degree of recognition of the state of the surgical part in the endoscopic operation in which the surgical part is viewed with a video.

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

  A training apparatus for endoscopic surgery to which the present invention is applied is for training an operation of a medical instrument or an image recognition state used by an operator in endoscopic surgery. For this purpose, this training apparatus for endoscopic surgery is configured to include a dome-shaped screen 11 as shown in FIG. This endoscopic surgical training apparatus images an endoscopic surgical training box 2 that includes therein an object that simulates an affected part to be presented to the presentation unit 1 and the endoscopic surgical training box 2. A control device 3 is provided for acquiring an image captured by the camera device 2b and displaying the image on the dome-shaped screen 11 by the left-eye projector 12 and the right-eye projector 13 of the presentation unit 1.

  As shown in FIGS. 1 and 2, the endoscopic surgical training box 2 includes an insertion port 2a into which a medical instrument 2e such as forceps operated by an endoscopic surgical trainer P is inserted, and an endoscopic surgical training box 2. The camera apparatus 2b which images the state inside the housing | casing of the training box 2 and the insertion jig | tool 2d which the medical instrument 2e is connected and penetrates the said medical instrument 2e inside a housing | casing are provided. A plurality of insertion openings 2 a are provided in the housing of the endoscopic surgery training box 2.

  The insertion port 2a is made of a flexible material that simulates the patient's skin, and the medical instrument 2e is inserted by the insertion jig 2d. The medical instrument 2e is operated so as to perform a predetermined operation on an object on the training table 2f provided inside the housing of the endoscopic surgery training box 2. The inside of the housing of the training box 2 for endoscopic surgery including the training table 2f and the object is an imaging range of the camera device 2b.

  Therefore, in this training apparatus for endoscopic surgery, the object on the training table 2f and the movement of the medical instrument 2e with respect to the object are imaged by the camera apparatus 2b, and the captured image is presented via the control apparatus 3. Projected onto the dome-shaped screen 11 of the section 1. Then, the trainer P can perform the training while looking at the state of his / her operation displayed on the dome-shaped screen 11. The training method for the trainer P will be described later.

  Next, the presentation unit 1 and the control device 3 in such a training apparatus for endoscopic surgery will be described in detail with reference to FIG.

  The presenting unit 1 is connected to the camera device 2b via the control device 3, and displays the image captured by the camera device 2b on the dome-shaped screen 11 without distortion. The trainer P can perform endoscopic surgery training while confirming the image captured by the camera device 2b on the dome-shaped screen 11 from a position almost facing the dome-shaped screen 11. In the following description, an example in which a stereoscopic video is displayed on the dome-shaped screen 11 will be described. However, the video presented to the trainee P may be either a non-stereoscopic video or a stereoscopic video. It may be a planar shape or an arbitrary shape such as a recess.

  In order to display a stereoscopic image on the dome-shaped screen 11 by the presenting unit 1, the camera device 2 b includes a left-eye camera unit that captures a left-eye image and a right-eye camera unit that captures a right-eye image. And. The left-eye camera unit and the right-eye camera unit are juxtaposed in a single housing of the camera device 2b, like the camera device in the endoscope system. In addition, when displaying a two-dimensional image | video on a screen, the camera apparatus 2b may be comprised by one camera part. The camera device 2b may be either a normal endoscope camera or a stereoscopic endoscope camera, and the video to be presented to the trainee P is properly used depending on whether it is a 2D video or a 3D video.

  The presenting unit 1 is reflected by the projectors 12 and 13 (video projection means) that receive video signals and emit video, the reflective mirror 14 that reflects video emitted from the projectors 12 and 13, and the reflective mirror 14. A dome-shaped screen 11 (video display means) having a hemispherical dome-shaped projection surface 11a on which an image is projected, a projector 12, 13, a reflecting mirror 14, and a base portion 15 that supports the dome-shaped screen 11 are integrated. The projectors 12 and 13, the reflecting mirror 14, and the lifting / lowering device 16 that moves the dome-shaped screen 11 perpendicularly to the base portion 15 are provided.

  The control device 3 is connected to the camera device 2b and includes a video signal processing unit that performs distortion correction processing on the video signals input to the projectors 12 and 13 so that the video is displayed on the projection surface 11a without distortion (not shown). ) The video signal processing unit includes, for example, a personal computer, and includes a left-eye video correction unit that corrects a left-eye video signal and a right-eye video correction unit that corrects a right-eye video signal. The eye image correction unit and the right eye image correction unit are supplied to the projectors 12 and 13 in synchronization.

  The left-eye image correction unit refers to the correction parameter for the left-eye image signal so that the left-eye image is displayed on the dome-shaped screen 11 without distortion, and distorts based on the correction parameter. Make corrections. Specifically, a planar image is supplied to the control device 3 from the camera device 2b so that when the image is projected from the projector 13 onto the dome screen 11, the image is not distorted and seen on the dome screen 11. Coordinate transformation or texture mapping is performed on the video. For this purpose, the relative positions of the projectors 12 and 13 and the dome-shaped screen 11, the shape of the dome-shaped screen 11, the relative position of the dome-shaped screen 11 and the trainee P, the driving angle of the left-eye projector 12, etc. A correction parameter, which is a correspondence table for coordinate conversion of a plane image so that the image is not distorted and viewed on the dome-shaped screen 11 due to the projector characteristics, is created in advance and stored in the control device 3 or the projector described above. Texture mapping is performed in real time based on information such as the relative positions of the dome screen 11 and the shape of the dome screen 11. Also, the right-eye video correction unit performs distortion correction in accordance with the correction parameters, similarly to the left-eye video correction unit. As a result, the control device 3 can project the stereoscopic video having a predetermined parallax between the right-eye video and the left-eye video from the projectors 12 and 13.

  One left-eye projector 12 receives the left-eye video signal corrected by the control device 3 and emits the left-eye video from the lens 12a. The other right-eye projector 13 receives the distortion-corrected right-eye video signal output from the right-eye video correction unit, and emits right-eye video light from the lens 13a.

  In addition, this training apparatus for endoscopic surgery employs a polarization method as a method for allowing the trainee P to visually recognize a stereoscopic image. That is, the left-eye polarizing filter 12 b is attached to the lens 12 a of the left-eye projector 12. Similarly, a right-eye polarizing filter 13b is attached to the lens 13a of the right-eye projector 13. The left-eye polarizing filter 12b and the right-eye polarizing filter 13b transmit different circularly polarized light. The left-eye image emitted from the left-eye projector 12 passes through the left-eye projector 12b, and the right-eye image emitted from the right-eye projector 13 passes through the right-eye polarization filter 13b. The polarizing filters 12b and 13b are not limited to those that transmit circularly polarized light, but may transmit linearly polarized light. For example, the left-eye polarizing filter 12b may transmit vertical linearly polarized light, and the right-eye polarizing filter 13b may transmit horizontal linearly polarized light.

  On the other hand, the trainee P wears stereoscopic glasses when looking at the dome-shaped screen 11. The stereoscopic glasses have a polarizing filter of the same polarization type as that of the left-eye polarizing filter 12b in the left eye part and a polarizing filter of the same polarization type as that of the right-eye polarizing filter 13b in the right eye part. By viewing the image displayed on the dome-shaped screen 11 through stereoscopic glasses, the trainer P can view the situation including the medical instrument 2e and the object in the training box 2 for endoscopic surgery as a stereoscopic image. .

  The reflecting mirror 14 is installed above the visual field when the trainee P looks at the center of the dome-shaped screen 11. The reflecting mirror 14 reflects the left-eye image light and the right-eye image light emitted from the left-eye projector 12 and the right-eye projector 13 toward the dome-shaped screen 11 11 a. Since the presentation unit 1 includes the reflecting mirror 14, it is not necessary to install the projectors 12 and 13 and the dome-shaped screen 11 in a single line, and the entire apparatus can be reduced.

  The projection surface 11a of the dome type screen 11 is a hemispherical dome shape as described above, and is coated with a paint having a specular reflection effect such as a silver paint. This dome type screen 11 is generally called a silver screen. Note that the shape of the screen is not limited to the hemispherical dome shape, and may be, for example, a composite screen including a flat surface and a quadric surface. Even in the screen having such a shape, the presentation unit 1 switches a correction parameter in the video signal processing unit to switch a video created by coordinate conversion or texture mapping, and displays a video without distortion. 11a can be displayed.

  In addition, it is preferable that the arithmetic average roughness of the concave surface of the dome-shaped screen 11 is within a range in which the halation due to mutual reflection is reduced while maintaining a high degree of separation. This is because, when images from the projectors 12 and 13 are projected onto the dome-type screen 11, the dome is caused by mutual reflection, which is a reflection of a secondary reflection or more reflected by a surface irradiated by direct light from the projectors 12 and 13. This is because the image on the end side of the mold screen 11 irradiates a part of the dome type screen 11 facing the screen. As a result, halation that appears white as if the entire dome-shaped screen 11 is wrinkled occurs. The degree of occurrence of halation due to this mutual reflection varies depending on the brightness of the projectors 12 and 13, the contrast ratio, and the shape of the dome screen 11. In particular, when the dome-shaped screen 11 is a hemisphere or semicircle, halation due to mutual reflection is likely to occur.

  The dome type screen 11 of FIG. 1 in this embodiment has a collar part (frame) 11b along the outer periphery, and a hemispherical dome type 11a is formed inside the collar part 11b.

  In such a presentation unit 1, the left-eye projector 12, the right-eye projector 13, the reflecting mirror 14, and the dome-shaped screen 11 are combined together using an attachment member 17 to constitute one moving body 18.

  More specifically, the attachment member 17 has a substantially rectangular parallelepiped shape, is formed of a metal plate, has a recess 19 on one surface of the front side of the presentation unit 1 (positive α-axis direction side in FIG. 1), and has an upper surface. The projector storage unit 20 is provided. A pair of arms 21 are extended from both sides of the projector storage unit 20 toward the front side of the presentation unit 1.

  The dome type screen 11 has a concave projection surface 11 a disposed in the concave portion 19 of the attachment member 17 and is fixed to the attachment member 17. When the dome type screen 11 is fixed to the mounting member 17, the opening surface of the dome type screen 11 and the front surface of the mounting member 17 are substantially the same surface. By disposing the concave projection surface 11 a in the concave portion 19, the dome-shaped screen 11 does not protrude from the mounting member 17, and the apparatus can be reduced in size.

  The projector storage unit 20 of the projectors 12 and 13 has a box shape in which at least the front side surface of the presentation unit 1 is opened. The projectors 12 and 13 are fixed in the projector housing portion 20, and the lenses 12a and 13a of the projectors 12 and 13 face the outside through the polarizing filters 12b and 13b from the opened side surfaces.

  The reflecting mirror 14 is fixed to the tips 21a of the pair of arms 21 at a predetermined angle.

  The base portion 15 is formed in a substantially rectangular parallelepiped shape from a metal plate, and includes a box-shaped storage portion 22 having an open upper surface on the front side, and a pair of leg portions 23 at the lower end. Each leg 23 is provided with casters 24 at both ends in the longitudinal direction. Handrails 25 are provided on both sides of the back surface 15 a of the base portion 15.

  The lower part of the above-mentioned moving body 18 is accommodated in the accommodating part 22 so that raising / lowering is possible. The lower part of the moving body 18 is housed in the box-shaped housing portion 22 so that the moving body 18 can stably maintain a constant posture.

  Further, the endoscopic surgical display device 1 is provided with the handrail 25 and the caster 24 on the base portion 15, so that when the user holds the handrail 25 and pushes the base portion 15, the endoscopic surgical display device 1. The device 1 can be easily moved.

  A scale 17 b is provided on the side surface 17 a of the mounting member 17 of the moving body 18, and a triangular mark 15 c is provided on the side surface 15 b of the base portion 15. The presenting unit 1 can cause the user to measure the height of the moving body 18 (screen) using the scale 17b and the triangular mark 15c.

  The lifting device 16 has, for example, a hydraulic power generation mechanism, and moves the moving body 18 up and down by the power generated by the power generation mechanism. The lifting device 16 includes a drive unit 26, an ascending step 27, and a descending lever knob 28. The drive unit 26 is disposed on the lower surface 22a of the storage unit 22, and the movable body 18 is fixedly placed on the upper surface 26a. The ascending step 27 and the descending lever knob 28 are provided on the back surface 15 a side of the storage portion 22. When the user steps on the ascending step 27 from above, the upper surface 26a of the drive unit 26 rises. If the player steps further, the upper surface 26a rises further. On the other hand, when the user turns the lowering lever knob 28 counterclockwise, the upper surface 26a of the driving unit 26 is lowered. When the lowering lever knob 28 is turned clockwise, the vertical movement of the upper surface 26a of the drive unit 26 is locked. That is, the elevating device 16 can elevate the upper surface 26 a of the drive unit 26 vertically with respect to the base unit 15 by the user operating the ascending step 27 and the descending lever knob 28. Thereby, the moving body 18 placed on the upper surface 26 a of the drive unit 26 can move vertically with respect to the base unit 15.

  Here, in the presentation unit 1, the projectors 12 and 13, the reflecting mirror 14, and the dome type screen 11 are combined together to form one moving body 18. For this reason, even if the moving body 18 is moved by the elevating device 16, the positional relationship among the projectors 12 and 13, the reflecting mirror 14, and the dome-type screen 11 remains fixed. Therefore, an image without distortion can always be displayed on the dome-shaped screen 11 regardless of the height of the moving body 18. That is, when the projectors 12 and 13, the reflecting mirror 14, and the dome type screen 11 are not integrated, if the height of the dome type screen 11 is changed, the projectors 12 and 13, the reflecting mirror 14, and the dome type screen 11 are mutually connected. The positional relationship changes, and there is a possibility that an image is not displayed at the center of the dome-shaped screen 11 or a distorted image is displayed on the screen. Therefore, each time the height of the dome-shaped screen 11 is changed, the positional relationship among the projectors 12 and 13, the reflecting mirror 14, and the dome-shaped screen 11 has to be adjusted.

  On the other hand, since the presenting unit 1 combines the projectors 12 and 13, the reflecting mirror 14, and the dome-shaped screen 11 to form a single moving body 18, the positional relationship between them is fixed. Even if the height of the moving body 18 is changed by the elevating device 16, images without desired distortion are always displayed on the dome type screen 11 without adjusting the positions of the projectors 12 and 13, the reflecting mirror 14, and the dome type screen 11. It can be done.

  In such a presentation unit 1, when performing endoscopic surgery training, the endoscopic surgery training box 2 is installed facing the dome-shaped screen 11. In addition, the camera device 2b is installed so as to image the object in the training box 2 for endoscopic surgery, and the image (that is, the object) imaged by the camera device 2b is displayed on the dome-shaped screen 11 in a three-dimensional manner. Is done. The training box 2 for endoscopic surgery is provided with a plurality of insertion openings 2a, so that even when a plurality of trainees P operate the medical instrument 2e inserted into the insertion openings 2a, each trainer P can receive a dome. While viewing the video displayed on the mold screen 11, endoscopic surgical training can be performed on the object.

  Moreover, since the moving body 18 can be moved up and down, the presenting unit 1 can be adjusted to a height at which the dome-shaped screen 11 can be easily viewed by operating the lifting device 16 by the trainee P. At this time, since the positional relationship among the projectors 12 and 13, the reflecting mirror 14, and the dome type screen 11 is fixed, an image without distortion is always displayed on the dome type screen 11 even if the moving body 18 is moved. Moreover, since this presentation part 1 is provided with the handrail 25 and the caster 24, it can be easily moved from one room to another room, for example, by holding the handrail 25 and pushing the base part 15. By lowering the height of the moving body 18, for example, a room door can be easily passed.

  As described above, the presenting unit 1 can adjust the height of the dome-shaped screen 11 according to the height and use of the trainee P, and even if the height of the screen is changed, the presenting unit 1 is always distorted. No video can be displayed.

  Using such a presentation unit 1, the training apparatus for endoscopic surgery causes the trainee P to operate the training box 2 for endoscopic surgery to perform endoscopic surgery training. As training for this endoscopic surgery, the first work task to the fourth work task described below with reference to FIGS. 3 to 6 and the first recognition task to be described below with reference to FIGS. There is a third recognition task.

"First work task"
In the first work task, the trainee P operates the forceps, which is the medical instrument 2e, in the endoscopic surgery training box 2, and causes the trainee P to train by bringing the tip of the forceps into contact with the object. The training box 2 for endoscopic surgery for performing the first work task is provided with a training table 2f as shown in FIG. The training table 2f is provided with at least two linear objects 2g-1 and 2g-2 between the upper part and the lower part. The objects 2g-1 and 2g-2 are provided with contact sensors 2h-1 and 2h-2 for detecting an operation in which the medical instrument 2e is contacted. The training table 2f is provided with a reference position contact sensor 2i at a predetermined reference position between the objects 2g-1 and 2g-2 and the normal position of the medical instrument 2e operated by the trainee P. .

  The objects 2g-1 and 2g-2 are distances D and widths W relative to the trainee P, and mounting heights of the contact sensors 2h-1 and 2h-2 on the objects 2g-1 and 2g-2. H1 and H2 can be adjusted. The front-rear direction distance D and the width W of the objects 2g-1 and 2g-2 are changed by providing a mechanism such as a small actuator or a motor (not shown) on the upper or lower portion of the training table 2f. The mounting heights H1 and H2 of the contact sensors 2h-1 and 2h-2 are changed by configuring the objects 2g-1 and 2g-2 with rubber materials, and attaching the objects 2g-1 and 2g-2 to the training table 2f. It is performed by a mechanism that pulls upward or downward. Furthermore, the thickness of the objects 2g-1 and 2g-2 may be changed by a mechanism that automatically replaces the objects 2g-1 and 2g-2. You may change with the mechanism to adjust. Such changes of the objects 2g-1 and 2g-2 and the contact sensors 2h-1 and 2h-2 are controlled by the control unit 3a in the control device 3.

  The endoscopic surgery training box 2 configured as described above uses an area including the objects 2g-1 and 2g-2 and the reference position contact sensor 2i as an imaging area of the camera device 2b. Therefore, the control device 3 is supplied with the left-eye video signal and the right-eye video signal indicating the images including the objects 2g-1 and 2g-2 and the reference position from the camera device 2b, and performs a predetermined distortion correction process. Do. Thereby, the training apparatus for endoscopic surgery can display the movement of the tip of the medical instrument 2e with respect to the objects 2g-1, 2g-2 and the reference position on the dome-shaped screen 11 in three dimensions.

  Further, in the training box 2 for endoscopic surgery, the medical instrument 2e as a forceps is contacted to detect that the tip of the forceps contacts the contact sensors 2h-1, 2h-2 or the reference position contact sensor 2i. A sensor 4a and an opening / closing sensor 4b for automatically detecting opening / closing of the forceps are provided. In the endoscopic surgery training box 2 provided with such objects 2g-1 and 2g-2, a sensor representing a contact operation of the medical instrument 2e with respect to the reference position contact sensor 2i and the contact sensors 2h-1 and 2h-2. The signal is detected by the contact sensor 4 a and output to the control device 3.

  In the control device 3, the distance between the objects 2g-1 and 2g-2 or the thicknesses of the objects 2g-1 and 2g-2 and the contact between the objects 2g-1 and 2g-2 are connected to the controller 3a. A work (training) task defined by the number of times of performing an operation of bringing the medical device 2e into contact with the sensors 2h-1 and 2h-2 is set (setting means). For example, the first work task is “after grasping the contact sensors 2h-1 and 2h-2 at the center of the objects 2g-1 and 2g-2 from the state where the tip of the forceps is in contact with the reference position, The operation of returning the tip to the reference position is performed 20 times in total, 10 times alternately on the left and right objects 2g-1, 2g-2. In addition, as an evaluation index of the first work task, the time required for one operation for grasping the contact sensors 2h-1 and 2h-2 from the state of contact with the reference position and bringing the tip of the forceps into contact with the reference position again. Of 20 times, and the number of times the object 2g-1, 2g-2 is missed during 20 operations.

  The sensor signals of the contact sensors 2h-1, 2h-2 and the reference position contact sensor 2i, the contact sensor 4a of the forceps, and the open / close sensor 4b for such operation of the forceps are supplied to the control unit 3a of the control device 3. The Accordingly, the start and end of the first work task is detected by detecting the operation of the forceps with respect to the reference position contact sensor 2i, and further, the operation of the forceps with respect to the contact sensors 2h-1, 2h-2 and the reference position contact sensor 2i. , The time required for 20 operations, the average time required for one operation, and the number of times that the objects 2g-1 and 2g-2 are missed are calculated by the analysis unit 3b, and the recording unit 3c Can be recorded.

  According to the endoscopic surgery training apparatus that executes such a first work task, the dome-shaped screen 11 can be viewed as a stereoscopic image (3D image) while the state in the endoscopic surgery training box 2 is visually recognized. The training start time and the training end time are recorded based on the detection output of the position contact sensor 2i, the contact sensors 2h-1, 2h-2 from the training start time to the training end time, the reference position contact sensor 2i, the contact sensor 4a, and The time required for one operation defined in the first work task can be stored based on the detection output of the open / close sensor 4b.

  Further, according to this endoscopic surgical training apparatus, the operation success and operation failure of the medical instrument 2e with respect to the objects 2g-1 and 2g-2 are detected, and the operation success frequency and the operation failure frequency are recorded by the recording unit 3c. can do.

  In this first work task, when the time required for one operation is not measured by the training apparatus for endoscopic surgery, the timing for operating the forceps from the reference position to the target object and from the target position to the reference position May be displayed on the dome-shaped screen 11 so as to be superimposed on a stereoscopic image showing the state in the training box 2 for endoscopic surgery. Moreover, you may show the content and description of a 1st work task before starting training. Furthermore, the training apparatus for endoscopic surgery may present the content of training or recorded information on the dome-shaped screen 11. Furthermore, the training apparatus for endoscopic surgery may evaluate the skill of the trainer P as an operator for endoscopic surgery using the information recorded by the recording unit 3c.

  Further, this endoscopic surgical training apparatus is configured so that the dome-shaped screen 11 is in the middle of changing the longitudinal distance D, width W, and mounting heights H1, H2 of the objects 2g-1, 2g-2. It is desirable to prevent stereoscopic images from being displayed.

"Second work task"
Next, the second work task to be performed by the trainer P by the above-described endoscopic surgical training apparatus will be described. In addition, the description is abbreviate | omitted about the part which is common in the description mentioned above.

  In the second work task, the trainer P operates the forceps as the medical instrument 2e in the training box 2 for endoscopic surgery, and causes the trainer P to train by gripping the target object. The training box 2 for endoscopic surgery for performing this second work task is provided with a training table 2f as shown in FIG. The training table 2f is provided with an object 2g having a thin line shape formed in a predetermined shape and having a needle shape at the tip thereof connected to the upper part of the training table 2f. The training table 2f is provided with a reference position contact sensor 2i at a predetermined reference position between the object 2g and the normal position of the medical instrument 2e operated by the trainee P.

  The object 2g can be adjusted in orientation and mounting height H with respect to the trainee P. The change of the orientation of the object 2g is performed by providing a mechanism such as a small rotary actuator (not shown) on the upper part of the training table 2f. The direction change of the needle portion at the tip of the object 2g is, for example, any one of eight stages from the state in which the tip of the needle faces toward the trainee P to the state in which the prior application of the needle faces away from the trainee P. It is set in the state. The mounting height H of the object 2g is changed by a mechanism that pulls the object 2g to the upper part of the training table 2f. Such a change in the orientation and the mounting height H of the object 2 g is controlled by the control unit 3 a in the control device 3.

  The endoscopic surgery training box 2 configured as described above uses an area including the object 2g and the reference position contact sensor 2i as an imaging area of the camera device 2b. Accordingly, the control device 3 is supplied with the left-eye video signal and the right-eye video signal indicating the image including the object 2g and the reference position from the camera device 2b, and performs a predetermined distortion correction process. Thereby, the training apparatus for endoscopic surgery can display the movement of the tip of the medical instrument 2e with respect to the object 2g and the reference position on the dome-shaped screen 11 in a three-dimensional manner.

  Further, in this endoscopic surgery training box 2, a contact sensor 4a that detects contact with a reference position contact sensor 2i on a medical instrument 2e that is a forceps, and an open / close sensor that automatically detects opening and closing of the forceps. 4b. In the endoscopic surgery training box 2 provided with such an object 2g, a sensor signal representing an operation of gripping the tip of the object 2g is detected by the open / close sensor 4b and the contact sensor 4a, and the reference position contact sensor 2i. A sensor signal representing the contact operation of the medical instrument 2e is detected by the contact sensor 4a and output to the control device 3. Specifically, the operation of grasping the object 2g is performed by detecting that the forceps are opened by the open / close sensor 4b, detecting that the contact sensor 4a is in contact with the needle portion with the forceps being opened, It is detected by detecting that the forceps are closed by the open / close sensor 4b in a state where the contact sensor 4a is in contact with the part.

  In the control device 3, an operation (training) task defined by the direction and the mounting height H of the object 2g and the number of times that the medical instrument 2e grasps the object 2g is set in the control unit 3a. (Setting means). For example, the second work task is “to perform a total of 20 operations to return the tip of the forceps to the reference position again after gripping the needle portion of the object 2g from the state where the tip of the forceps is in contact with the reference position”. . In addition, as an evaluation index for the second work task, 20 times of the time required for one operation of grasping the needle portion of the object 2g and bringing the tip of the forceps into contact with the reference position again from the state of contact with the reference position. And the number of times the needle part of the object 2g was missed during 20 operations.

  The sensor signals of the open / close sensor 4b, the contact sensor 4a, and the reference position contact sensor 2i for such a single forceps operation are supplied to the control unit 3a of the control device 3. Accordingly, the start and end of the first work task is detected by detecting the operation of the forceps with respect to the reference position contact sensor 2i, and further, the operation of the forceps with respect to the object 2g and the reference position contact sensor 2i is detected, The time required for 20 operations, the average time required for one operation, and the number of times the object 2g is missed can be calculated by the analysis unit 3b and recorded in the recording unit 3c.

  According to the endoscopic surgery training apparatus that executes such a second work task, the dome-shaped screen 11 can be viewed as a stereoscopic image (3D image) while the state in the endoscopic surgery training box 2 is visually recognized. The training start time and the training end time are recorded based on the detection output of the position contact sensor 2i, and the first position based on the detection outputs of the reference position contact sensor 2i, the contact sensor 4a, and the open / close sensor 4b from the training start time to the training end time. Time required for one operation defined by two work tasks can be stored.

  Further, according to this training apparatus for endoscopic surgery, it is possible to detect the operation success and operation failure of the medical instrument 2e with respect to the object 2g, and to record the operation success frequency and operation failure frequency by the recording unit 3c.

  In this second work task, when the time required for one operation is not measured by the training apparatus for endoscopic surgery, the timing for operating the forceps from the reference position to the target object and from the target position to the reference position May be displayed on the dome-shaped screen 11 so as to be superimposed on a stereoscopic image showing the state in the training box 2 for endoscopic surgery. Moreover, you may show the content and description of a 1st work task before starting training. Furthermore, the training apparatus for endoscopic surgery may present the content of training or recorded information on the dome-shaped screen 11. Furthermore, the training apparatus for endoscopic surgery may evaluate the skill of the trainer P as an operator for endoscopic surgery using the information recorded by the recording unit 3c.

  Furthermore, it is desirable that this endoscopic surgical training apparatus does not display a stereoscopic image on the dome-shaped screen 11 while the orientation of the object 2g and the mounting height H are being changed.

"Third work task"
Next, a third work task to be performed by the trainer P by the above-described endoscopic surgical training apparatus will be described. In addition, the description is abbreviate | omitted about the part which is common in the description mentioned above.

  In the third work task, the trainer P operates the forceps, which is the medical instrument 2e, in the endoscopic surgery training box 2, and causes the trainee P to train by bringing the tip of the forceps into contact with the object. The endoscopic surgery training box 2 for performing the third work task is provided with a training table 2f as shown in FIG. The training table 2f is provided with at least two objects 2g-1 and 2g-2 that include a ring-shaped portion and are displaced in the front-rear direction with respect to the trainee P of the medical instrument 2e. The training table 2f is provided with a reference position contact sensor 2i at a predetermined reference position between the objects 2g-1 and 2g-2 and the normal position of the medical instrument 2e operated by the trainee P. . Moreover, although not shown in figure, this training stand 2f is equipped with the sensor which detects that the medical instrument 2e passed the ring-shaped part. For example, the magnetic field state in the ring-shaped part is detected, and it is detected that the medical instrument 2e is inserted into the ring-shaped part of the objects 2g-1, 2g-2.

  The objects 2g-1 and 2g-2 can change the size of the ring-shaped portion. The size of the ring-shaped portion of the objects 2g-1 and 2g-2 is changed by a mechanism that automatically replaces the objects 2g-1 and 2g-2. In addition, the training box 2 for endoscopic surgery may be capable of changing the position of the two ring-shaped portions, and may be capable of automatically changing the shape of the foot and the position of the foot that support the ring-shaped portion.

  The endoscopic surgery training box 2 configured as described above uses an area including the objects 2g-1 and 2g-2 and the reference position contact sensor 2i as an imaging area of the camera device 2b. Therefore, the control device 3 is supplied with the left-eye video signal and the right-eye video signal indicating the images including the objects 2g-1 and 2g-2 and the reference position from the camera device 2b, and performs a predetermined distortion correction process. Do. Thereby, the training apparatus for endoscopic surgery can display the movement of the tip of the medical instrument 2e with respect to the objects 2g-1, 2g-2 and the reference position on the dome-shaped screen 11 in three dimensions.

  In the training box 2 for endoscopic surgery, an opening / closing sensor 4b that automatically detects opening / closing of the forceps is provided in the medical instrument 2e that is a forceps. In the endoscopic surgery training box 2 including such objects 2g-1 and 2g-2, sensor signals for the passage of the reference position contact sensor 2i and the ring-shaped portion are output to the control device 3.

  In the control device 3, the control unit 3a allows the medical device 2e to pass through the size of the ring-shaped portion of the objects 2g-1, 2g-2 and the ring-shaped portion of the objects 2g-1, 2g-2. A work (training) task defined by the number of operations is set (setting means). For example, the third work task is “an operation to return the tip of the forceps to the reference position again after passing the ring-shaped portion of the object 2g-1, 2g-2 from the state where the tip of the forceps is in contact with the reference position. ”, 20 times in total, 10 times each for the ring-shaped portions of the left and right objects 2g-1 and 2g-2. In addition, as an evaluation index of the third work task, an average of 20 times of time required for one operation of passing the ring-shaped portion from the state in contact with the reference position and bringing the tip of the forceps into contact with the reference position again is used. Time and the amount of deviation of the passing position with respect to the center of the ring-shaped part.

  The sensor signals of the contact sensors 2 h-1, 2 h-2 and the reference position contact sensor 2 i for such a single forceps operation are supplied to the control unit 3 a of the control device 3. Accordingly, the start and end of the third work task is detected by detecting the operation of the forceps with respect to the reference position contact sensor 2i, and further, the operation of the forceps with respect to the contact sensors 2h-1, 2h-2 and the reference position contact sensor 2i. , The time required for 20 operations, the average time required for one operation, and the amount of deviation from the center of the ring-shaped portion of the object 2g-1, 2g-2 are calculated by the analysis unit 3b. Recording can be performed in the recording unit 3c.

  According to the endoscopic surgical training apparatus that executes such a third work task, the dome-shaped screen 11 can be viewed as a stereoscopic video (3D video) while viewing the state in the endoscopic surgical training box 2 as a stereoscopic video (3D video). The training start time and the training end time are recorded based on the detection output of the position contact sensor 2i, and the third operation is performed based on the detection output of the reference position contact sensor 2i and the ring-shaped portion from the training start time to the training end time. The time required for one operation defined by the task can be stored.

  Further, according to this endoscopic surgical training apparatus, the operation success and operation failure of the medical instrument 2e with respect to the objects 2g-1 and 2g-2 are detected, and the operation success frequency and the operation failure frequency are recorded by the recording unit 3c. can do.

  In this third work task, when the time required for one operation of the training apparatus for endoscopic surgery is not measured, the timing for operating the forceps from the reference position to the target object and from the target position to the reference position May be displayed on the dome-shaped screen 11 so as to be superimposed on a stereoscopic image showing the state in the training box 2 for endoscopic surgery. Moreover, you may show the content and description of a 3rd work task before starting training. Furthermore, the training apparatus for endoscopic surgery may present the content of training or recorded information on the dome-shaped screen 11. Furthermore, the training apparatus for endoscopic surgery may evaluate the skill of the trainer P as an operator for endoscopic surgery using the information recorded by the recording unit 3c.

  Furthermore, this endoscopic surgical training device is provided with a dome-shaped screen while changing the distance D, the width W, the size of the ring-shaped portion, etc. of the objects 2g-1 and 2g-2. It is desirable not to display a 3D image on 11.

"4th work task"
Next, the fourth work task to be performed by the trainer P by the above-described endoscopic surgical training apparatus will be described. In addition, the description is abbreviate | omitted about the part which is common in the description mentioned above.

  In the fourth work task, the trainer P operates the forceps that is the medical instrument 2e in the training box 2 for endoscopic surgery, sutures the thread to the suture practice board that is the object, and further ligates the thread. It trains the operation to do. The training box 2 for endoscopic surgery for performing the fourth work task is provided with a suture practice board as an object 2g on a training table 2f as shown in FIG. This sewing practice board is made of a rubber material or the like simulating a patient's skin, and a plurality of target points through which a suture needle passes are described. The training table 2f is provided with a reference position contact sensor 2i at a predetermined reference position between the suture practice board and the normal position of the medical instrument 2e operated by the trainer P. Further, although not shown, a contact sensor for detecting that the suture needle has passed through the suture practice board is provided at the tip of the suture needle held by the forceps. The contact sensor supplies a sensor signal that can be recognized that the suture is sutured by the suture needle to the control unit 3a of the control device 3 when the suture needle passes the suture practice board by the operation of the forceps.

  The suture practice board can set a target point through which a thread is passed with a suture needle held by forceps. Specifically, in a state where the stitching practice board is displayed on the dome-shaped screen 11, the target point of the stitching practice board is superimposed on the image of the camera device 2 b displayed on the dome-shaped screen 11. . The endoscopic surgical training apparatus detects that the suture needle has passed the target point of the suture practice board set on the dome-shaped screen 11. In this endoscopic surgical training apparatus, the suture ligation operation is detected based on the detection outputs of the contact sensor 4a and the open / close sensor 4b representing the operation of the forceps. This suture ligation operation has a predetermined method as a method of tying sutures. Therefore, the training apparatus for endoscopic surgery performs the grasping of the suture by the grasping of the suture detected by the contact sensor 4a provided on the forceps and the opening / closing of the forceps detected by the opening / closing sensor 4b in a predetermined order. Ligation work can be detected.

  The endoscopic surgery training box 2 configured as described above uses an area including the training table 2f, the suture practice board as the object 2g, and the reference position contact sensor 2i as an imaging area of the camera device 2b. Accordingly, the control device 3 is supplied with the left-eye video signal and the right-eye video signal indicating the video including the stitching practice board and the reference position from the camera device 2b, and performs a predetermined distortion correction process. Thereby, the training apparatus for endoscopic surgery can display the movement of the tip of the medical instrument 2e with respect to the suture practice board and the reference position on the dome-shaped screen 11 in a three-dimensional manner.

  In the control device 3, a work (training) task defined by the number of times of sewing work and the number of times of ligation work for the sewing practice board is set in the control unit 3a (setting means). For example, the fourth work task is “hold the suture needle placed on the suture practice board, perform the suture work once according to the target points arranged on the left and right of the vertical line at the center of the suture practice board, and then In addition, the ligation work by the basic C loop method which is a predetermined stitching method is performed twice. In addition, as an evaluation index of the fourth work task, an average time for two times of time required for one operation including grasping and suturing of a suture needle and two times of ligation work, and one operation The average number of times of error (the number of times that the suture needle and the suture thread are missed) is calculated.

  The sensor signals of the open / close sensor 4b, the contact sensor 4a, and the reference position contact sensor 2i for such a single forceps operation are supplied to the control unit 3a of the control device 3. Accordingly, the start and end of the fourth work task is detected by detecting the operation of the forceps with respect to the reference position contact sensor 2i, and further, the operation of the forceps with respect to the suture practice board and the reference position contact sensor 2i is detected, The time required for one operation, the average time required for one operation, and the number of errors can be calculated by the analysis unit 3b and recorded in the recording unit 3c.

  According to the endoscopic surgical training apparatus that executes such a fourth work task, while making the state in the endoscopic surgical training box 2 visible as a three-dimensional video (3D video) on the dome-shaped screen 11, the reference is made. The training start time and the training end time are recorded based on the detection output of the position contact sensor 2i, and the first position based on the detection outputs of the reference position contact sensor 2i, the contact sensor 4a, and the open / close sensor 4b from the training start time to the training end time. Time required for one operation defined by four work tasks can be stored.

  Further, according to this training apparatus for endoscopic surgery, it is possible to detect the operation success and operation failure of the medical instrument 2e with respect to the object 2g, and to record the operation success frequency and operation failure frequency by the recording unit 3c.

  In this second work task, when the time required for one operation is not measured by the training apparatus for endoscopic surgery, the timing for operating the forceps from the reference position to the target object and from the target position to the reference position May be displayed on the dome-shaped screen 11 so as to be superimposed on a stereoscopic image showing the state in the training box 2 for endoscopic surgery. Moreover, you may show the content and description of a 1st work task before starting training. Furthermore, the training apparatus for endoscopic surgery may present the content of training or recorded information on the dome-shaped screen 11. Furthermore, the training apparatus for endoscopic surgery may evaluate the skill of the trainer P as an operator for endoscopic surgery using the information recorded by the recording unit 3c.

"First recognition task"
Next, a first recognition task for training the recognition state of the situation on the training table 2f in order to train an operator in endoscopic surgery will be described. In addition, the description is abbreviate | omitted about the part which is common in the description mentioned above.

  The first recognition task is to train that the trainer P can accurately recognize the state of the object in the training box 2 for endoscopic surgery. In the first recognition task, a training table 2 f as shown in FIG. 7 is provided in the training box 2 for endoscopic surgery. The training table 2f is provided with at least two linear objects 2g-1 and 2g-2 between the upper part and the lower part.

  The objects 2g-1 and 2g-2 can be adjusted with respect to the trainee P in the front-rear direction distance D and the width W. The front-rear direction distance D and the width W of the objects 2g-1 and 2g-2 are changed by providing a mechanism such as a small actuator or a motor (not shown) on the upper or lower portion of the training table 2f. The thicknesses of the objects 2g-1 and 2g-2 may be changed by a mechanism that automatically replaces the objects 2g-1 and 2g-2, and the tensions of the objects 2g-1 and 2g-2 are adjusted. It may be changed by the mechanism. Such changes of the objects 2g-1 and 2g-2 and the contact sensors 2h-1 and 2h-2 are controlled by the control unit 3a in the control device 3.

  The endoscopic surgery training box 2 configured as described above uses an area including the objects 2g-1 and 2g-2 as an imaging area of the camera device 2b. Therefore, the control device 3 is supplied with the left-eye video signal and the right-eye video signal indicating the video including the objects 2g-1 and 2g-2 from the camera device 2b, and performs a predetermined distortion correction process. Thereby, the training apparatus for endoscopic surgery can display the objects 2g-1 and 2g-2 on the dome-shaped screen 11 in a three-dimensional manner.

  In this state where the states of the objects 2g-1 and 2g-2 are displayed on the dome-shaped screen 11, the first recognition task is performed by any of the objects 2g-1 and 2g-2 being trained. The front-rear positional relationship as to whether it exists in front of or behind the person P is selected by operating the button 5 (input means). This operation is detected by the control device 3, and the analysis unit 3 b determines whether the object 2 g-1, 2 g-2 input to the button 5 is correct in the front-rear positional relationship or the object front-rear position input to the button 5. The difference from the front and rear positions of the actual object is calculated and recorded in the recording unit 3c.

  In the control device 3, a recognition (training) task is set in the control unit 3 a to present all the patterns such as all the front-rear positional relationships and thicknesses in a random order several times and each pattern for 5 seconds. . Then, the analysis unit 3b uses the correct answer rate of the answer and the time required from the presentation of the pattern to the answer as the evaluation index. Then, in the endoscopic surgery training device, the control device 3 controls the actuator according to the recognition task to change the front and back, the thickness and the distance of the objects 2g-1 and 2g-2, and detects the operation of the button 5 To do. Accordingly, the analysis unit 3b determines whether the front-rear positional relationship between the objects 2g-1 and 2g-2 input to the button 5 is correct or incorrect or the front-rear positional relationship between the objects 2g-1 and 2g-2 input to the button 5. The difference with the front-rear positional relationship of the actual objects 2g-1 and 2g-2 is calculated and recorded in the recording unit 3c.

  The endoscopic surgical training apparatus is configured so that the dome-shaped screen 11 is in the middle of changing the distance D, width W, and mounting heights H1, H2 of the objects 2g-1, 2g-2. It is desirable to prevent stereoscopic images from being displayed.

"Second recognition task"
Next, a first recognition task for training the recognition state of the situation on the training table 2f in order to train an operator in endoscopic surgery will be described. In addition, the description is abbreviate | omitted about the part which is common in the description mentioned above.

  The second recognition task is a training for accurately grasping the direction of the distal end portion 2g 'of the object 2g in the training box 2 for endoscopic surgery. In this second recognition task, the training box 2 for endoscopic surgery is provided with a training table 2f as shown in FIG. The training table 2f is provided with an object 2g having a thin line shape formed in a predetermined shape and having a needle shape at the tip thereof connected to the upper part of the training table 2f.

  The object 2g can be adjusted in orientation and mounting height H with respect to the trainee P. The change of the orientation of the object 2g is performed by providing a mechanism such as a small rotary actuator (not shown) on the upper part of the training table 2f. The direction change of the needle portion at the tip of the object 2g is, for example, any one of eight stages from the state in which the tip of the needle faces toward the trainee P to the state in which the prior application of the needle faces away from the trainee P. It is set in the state. The mounting height H of the object 2g is changed by a mechanism that pulls the object 2g to the upper part of the training table 2f. Such a change in the orientation and the mounting height H of the object 2 g is controlled by the control unit 3 a in the control device 3.

  The endoscopic surgery training box 2 configured as described above uses an area including the object 2g and the reference position contact sensor 2i as an imaging area of the camera device 2b. Accordingly, the control device 3 is supplied with the left-eye video signal and the right-eye video signal indicating the image including the object 2g and the reference position from the camera device 2b, and performs a predetermined distortion correction process. Thereby, the training apparatus for endoscopic surgery can display the movement of the tip of the medical instrument 2e with respect to the object 2g and the reference position on the dome-shaped screen 11 in a three-dimensional manner.

  In the control device 3, a recognition (training) task is set in the control unit 3 a for presenting the orientation of the object 2 g and the mounting height H three times in a random order, each pattern for 5 seconds. (Setting means). In the endoscopic surgical training apparatus, the control device 3 controls the actuator according to the recognition task, and detects the operation of the button 5. Thereby, the analysis unit 3b calculates the difference between the direction of the object 2g input to the button 5 or the direction of the object 2g input to the button 5 and the direction of the actual object 2g, and records the result. Record in part 3c.

  Note that it is desirable that this endoscopic surgical training apparatus does not display a stereoscopic image on the dome-shaped screen 11 while the orientation of the object 2g and the mounting height H are being changed.

"Third recognition task"
Next, a third recognition task for training the recognition state of the situation on the training table 2f in order to train an operator in endoscopic surgery will be described. In addition, the description is abbreviate | omitted about the part which is common in the description mentioned above.

  The third recognition task is to train that the trainer P can accurately recognize the state of the object in the training box 2 for endoscopic surgery. In this third recognition task, a training table 2 f as shown in FIG. 9 is provided in the training box 2 for endoscopic surgery. The training table 2f is provided with objects 2g-1 and 2g-2 having at least two linear portions that are linear.

  For the objects 2g-1 and 2g-2, the radius R of the ring-shaped portion, the distance D between the centers of the ring-shaped portions, and the distance A in the width direction of the center of the ring-shaped portion can be changed. The change of the radius R of the ring-shaped portion can be realized by a mechanism for exchanging the objects 2g-1 and 2g-2 itself. The change of the front-rear direction distance D and the width direction distance A drives the actuator below the training table 2f. And can be changed. These controls are controlled by the control unit 3 a in the control device 3.

  The endoscopic surgery training box 2 configured as described above uses an area including the objects 2g-1 and 2g-2 as an imaging area of the camera device 2b. Therefore, the control device 3 is supplied with the left-eye video signal and the right-eye video signal indicating the video including the objects 2g-1 and 2g-2 from the camera device 2b, and performs a predetermined distortion correction process. Thereby, the training apparatus for endoscopic surgery can display the objects 2g-1 and 2g-2 on the dome-shaped screen 11 in a three-dimensional manner.

  In this state where the states of the objects 2g-1 and 2g-2 are displayed on the dome-shaped screen 11, this third recognition task is performed when any of the objects 2g-1 and 2g-2 is trained. The front-rear positional relationship as to whether it exists in front of or behind the person P is selected by operating the button 5 (input means). This operation is detected by the control device 3, and the analysis unit 3 b determines whether the object 2 g-1, 2 g-2 input to the button 5 is correct in the front-rear positional relationship or the object front-rear position input to the button 5. The difference from the front and rear positions of the actual object is calculated and recorded in the recording unit 3c.

  The control device 3 presents the control unit 3a with a plurality of patterns such as all the distances D in the front-rear direction, the radius R of the ring-shaped portion, and the distance A in the width direction in a random order. A recognition (training) task is set. Then, the analysis unit 3b uses the correct answer rate of the answer and the time required from the presentation of the pattern to the answer as the evaluation index. Then, in the endoscopic surgery training apparatus, the control device 3 controls the actuator according to the recognition task, so that the longitudinal distance D, the width direction distance A, and the radius R of the ring-shaped portion of the objects 2g-1 and 2g-2 are obtained. By changing, the operation of the button 5 is detected. Accordingly, the analysis unit 3b determines whether the front-rear positional relationship between the objects 2g-1 and 2g-2 input to the button 5 is correct or incorrect or the front-rear positional relationship between the objects 2g-1 and 2g-2 input to the button 5. The difference with the front-rear positional relationship of the actual objects 2g-1 and 2g-2 is calculated and recorded in the recording unit 3c.

  This endoscopic surgical training apparatus is a dome-shaped screen during the change of the distance D, the width W, the size of the ring-shaped portion, etc. of the objects 2g-1 and 2g-2. It is desirable not to display a 3D image on 11.

  Next, in these work tasks and recognition tasks, as a means for presenting images in the training box 2 for endoscopic surgery, a case where a two-dimensional image (2D) is used by a general 20-inch Trinitron monitor, and the present invention The results for the work task and the recognition task when the 3D video (3D) is used as in the presentation unit 1 to which is applied will be described with reference to FIGS.

"First work task"
As shown in FIG. 3, the first work task is training for gripping a plurality of filamentous objects with different distances from the camera device 2b. As a result of this first work task, FIG. 10 shows the forceps reciprocation time [sec] for each subject (trainer P), FIG. 11 shows the standard deviation of forceps reciprocation time [sec], and FIG. Indicates the number of grip errors [times]. In addition, this training result is obtained by performing the first work task by a plurality of trainees P. Here, “P” shown in FIG. 10 is an analysis method called “Wilcoxon Signed Rank Test”, and “P” shown in FIGS. 11 and 12 is an analysis called “Mann-Whitney-U test”. This is a value obtained by a technique, and if the value of P is 0.05 or less, it indicates that there is a difference in the object to be compared. As can be seen from FIG. 10, the forceps reciprocation time is greater when the situation in the endoscopic surgery training box 2 is displayed as a three-dimensional image (3D) than when displayed as a two-dimensional image (2D). Is shorter, and the difference between the two results is recognized from the value of P.

  Further, as shown in FIG. 11, the three-dimensional image (3D) has a smaller variation in forceps reciprocation time corresponding to the trainee P and a shorter time than the two-dimensional image (2D). In addition, the value of P obtained by the Mann-Whitney-U test is 0.034. The box-and-whisker diagram shown in FIG. 11 is described in the case of a two-dimensional image (2D). Values near 2.6 [sec] and 0.5 [sec] are mild outliers and 2.25 [sec]. ], Values near 0.75 [sec] are the minimum and maximum values, values near 0.9 [sec] and 2.0 [sec] are the first and third quartiles, The value near 5 [sec] is the median value.

  Furthermore, as shown in FIG. 12, in the three-dimensional image (3D), the number of gripping mistakes corresponding to the trainee P is smaller and the variation is smaller than in the two-dimensional image (2D). Further, the value of P obtained by the Mann-Whitney-U test is also 0.0039.

"Second work task"
As shown in FIG. 4, the second work task is training for grasping a needle shape whose orientation is variable with respect to the trainee P. As a result of the second work task, FIG. 13 shows the forceps reciprocation time [sec], and FIG. 14 shows the number of object gripping mistakes [times]. This training result is obtained by performing the second work task by a plurality of trainees P.

  As apparent from FIG. 13, the forceps reciprocation time is shorter in the case of displaying in the three-dimensional image (3D) than in the case of displaying in the two-dimensional image (2D). The value of P is also 0.01. Further, as apparent from FIG. 14, the number of gripping mistakes is smaller in the case of displaying in the three-dimensional image (3D) than in the case of displaying in the two-dimensional image (2D). The value of P is also 0.018.

"Third work task"
As shown in FIG. 5, the third work task is forceps passage training for two ring-shaped portions having different distances from the camera device 2b. As a result of this third work task, FIG. 15 shows the deviation [mm] from the center of the ring-shaped part of the objects 2g-1 and 2g-2, and FIG. 16 shows the standard deviation of this deviation. This training result is obtained by performing a third work task by a plurality of trainees P.

  As apparent from FIG. 15, the amount of shift and the variation are smaller in the case of displaying in the three-dimensional image (3D) than in the case of displaying in the two-dimensional image (2D). Note that the value of P is also 0.036. As is clear from FIG. 16, the standard deviation of the deviation amount is smaller and the variation is smaller in the case of displaying in the three-dimensional video (3D) than in the case of displaying in the two-dimensional video (2D). Note that the value of P is also 0.036.

"4th work task"
As shown in FIG. 6, the fourth work task is a training for causing a predetermined sewing practice board to perform a sewing operation. As a result of the fourth work task, FIG. 17 shows the ligation time [sec] of the suture thread, and FIG. 18 shows the number of times of mistake in grasping the suture thread or suture needle [times]. FIGS. 17A and 18A show the results when the fourth work task is performed after viewing the 3D video (3D) after performing the fourth work task while viewing the 2D video (2D). is there. FIGS. 17B and 18B show the results when the fourth work task is performed after viewing the 2D video (2D) after performing the fourth work task while viewing the 3D video (3D). is there. This training result is obtained by performing a fourth work task by a plurality of trainees P.

  As apparent from FIG. 17, the suture ligation time is shorter in the case of displaying in the three-dimensional image (3D) than in the case of displaying in the two-dimensional image (2D). The value of P is also 0.035. Further, as apparent from FIG. 18, the number of gripping mistakes is smaller in the case of displaying in the three-dimensional image (3D) than in the case of displaying in the two-dimensional image (2D). Note that the value of P is also 0.0015.

"First recognition task"
As shown in FIG. 7, the first recognition task is training for accurately grasping the front-rear positional relationship of a plurality of filamentous objects with different distances from the camera device 2b. The training result of the first recognition task was obtained when the two-dimensional image (2D) was displayed on the flat monitor and when the three-dimensional image (3D) was displayed on the dome-shaped screen 11. In addition, the training result of the first recognition task is that the stereoscopic image is displayed on the dome-shaped screen 11 when the first recognition task is performed (3DP) by displaying a stereoscopic image using a monitor with a flat display screen. And the first recognition task was performed (3DD). The forceps and the training box 2 for endoscopic surgery were the same. As a result of the first recognition task, FIG. 19 shows the correct answer rate of the front-rear positional relationship between the case where the 2D image (2D) is used and the case where the 3D image (3D) on the dome-shaped screen 11 is used. . In addition, FIG. 20 shows the correct answer rate of the front-rear positional relationship when a 3D image is displayed on a flat monitor (3DP) and when it is displayed on a dome type screen 11 (3DD). In addition, this training result is obtained by performing a first recognition task by a plurality of trainees P.

  Referring to FIG. 19, it was confirmed that there was a remarkably large difference in the correct answer rate between using the 2D image and using the 3D image on the dome-shaped screen 11. The value of P was also 0.014. On the other hand, FIG. 20 shows that the variation in the correct answer rate of the subject is large in 3DP using a flat monitor, but the variation in the correct answer rate between subjects is small in 3DD using the dome-shaped screen 11. ing. In 3DD, there is no slight outlier and the minimum value is also high. Note that the value of P was 0.77.

"Second recognition task"
The second recognition task is a training for accurately grasping the direction of the needle shape with respect to the trainee P as shown in FIG. As a result of the second recognition task, the correct answer rate of the direction of the needle-shaped portion when using the two-dimensional image (2D) and when using the three-dimensional image (3D) on the dome-shaped screen 11 is shown in FIG. Indicates. Further, FIG. 22 shows the correct answer rate of the direction of the needle-shaped part when the 3D image is displayed on the flat monitor (3DP) and when it is displayed on the dome-shaped screen 11 (3DD). This training result is obtained by performing the second recognition task by a plurality of trainees P.

  Referring to FIG. 21, a large difference in correct answer rate was confirmed between the case where the 2D image was used and the case where the 3D image on the dome-shaped screen 11 was used. Further, when the 3D image on the dome-shaped screen 11 is used, the variation is gathered with a correct answer rate of 90% or more, and the variation for each trainer P is significantly smaller than when the 2D image is used. Furthermore, the value of P is 0.0001, and a large significant difference is recognized.

  Referring to FIG. 22, the variation in the correct answer rate of the subject is large in 3DP using a flat monitor, but the variation in the correct answer rate between subjects is small in 3DD using the dome-shaped screen 11. . In 3DD, the correct answer rate is 90% even with a slight outlier, and the minimum value is also extremely high. The value of P was 0.0003.

  In this second recognition task, even if the same stereoscopic image is displayed, a significantly higher effect is recognized by using the dome type screen 11 than a flat monitor.

"Third recognition task"
As shown in FIG. 9, the third recognition task is training for accurately grasping the front-rear positional relationship of a plurality of objects whose distances from the camera device 2b are different in the size of the ring-shaped part. As a result of the third recognition task, FIG. 23 shows the correct answer ratios before and after the ring-shaped portion when using the two-dimensional image (2D) and when using the three-dimensional image (3D) on the dome-shaped screen 11. FIG. 24 shows a case where all models in which the radius R of the ring-shaped portion of each object, the distance D between the objects in the front-rear direction and the width W are changed, and the front object from the camera device 2b are shown. The results of the correct answer rate between 3DP using a flat monitor and 3DD using a dome-shaped screen 11 in the case where training is performed to recognize if the radius R of the ring-shaped portion is small are shown.

  Referring to FIG. 23, it was confirmed that the correct answer rate was different between the case where the 2D image was used and the case where the 3D image on the dome type screen 11 was used. Further, when the 3D image on the dome-shaped screen 11 is used, the variation is gathered with a correct answer rate of 90% or more, and the variation for each trainer P is significantly smaller than when the 2D image is used. Furthermore, the value of P is 0.0002, and a large significant difference is recognized.

  Referring to FIG. 24, the 3DD using the dome-shaped screen 11 has less variation and the average value of the correct answer rate is higher than the 3DP using the flat monitor. Note that the value of P is 0.0002, and in the third recognition task, there is a marked difference in both results.

  In the third recognition task, even if the same stereoscopic image is displayed, a significantly higher effect is recognized by using the dome type screen 11 than a flat monitor.

  The above-described embodiment is an example of the present invention. For this reason, the present invention is not limited to the above-described embodiment, and various modifications can be made depending on the design and the like as long as the technical idea according to the present invention is not deviated from this embodiment. Of course, it is possible to change.

It is a perspective view which shows the structure of the training apparatus for endoscopic surgery to which this invention is applied. It is a perspective view which shows the external appearance structure of the training box for endoscopic surgery in the training apparatus for endoscopic surgery to which this invention is applied. It is the schematic which shows the structure of the training stand installed in the training box for endoscopic surgery, and the target object provided in the said training stand, and demonstrates a 1st work task. It is the schematic which shows the structure of the training stand installed in the training box for endoscopic surgery, and the target object provided in the said training stand, and demonstrates a 2nd work task. It is the schematic which shows the structure of the training stand installed in the training box for endoscopic surgery, and the target object provided in the said training stand, and demonstrates a 3rd work task. It is the schematic which shows the structure of the training stand installed in the training box for endoscopic surgery, and the target object provided in the said training stand, and demonstrates a 4th work task. It is the schematic which shows the structure of the training stand installed in the training box for endoscopic surgery, and the target object provided in the said training stand, and demonstrates a 1st recognition task. It is the schematic which shows the structure of the training stand installed in the training box for endoscopic surgery, and the target object provided in the said training stand, and demonstrates a 2nd recognition task. It is the schematic which shows the structure of the training stand installed in the training box for endoscopic surgery, and the target object provided in the said training stand, and demonstrates a 3rd recognition task. It is a graph which compares and shows the forceps reciprocation time performed by seeing the two-dimensional image (2D) and the forceps reciprocation time performed by viewing the three-dimensional image (3D) as a training result of the first work task. As a training result of the first work task, the standard deviation of the forceps reciprocation time performed by viewing the 2D image (2D) is compared with the standard deviation of the forceps reciprocation time performed by viewing the 3D image (3D). FIG. As a training result of the first work task, a box-and-whisker diagram showing a comparison between the number of gripping mistakes performed by viewing a 2D image (2D) and the number of gripping errors performed by viewing a 3D image (3D) is there. As a training result of the second work task, a box whisker chart showing a comparison between a forceps reciprocation time performed by viewing a two-dimensional image (2D) and a forceps reciprocation time performed by viewing a three-dimensional image (3D) is there. It is a graph which compares and shows the number of gripping mistakes performed by viewing the 2D video (2D) and the number of gripping errors performed by viewing the 3D video (3D) as a training result of the second work task. It is a box-and-whisker diagram which compares and compares the amount of shift | offset | difference performed by seeing a two-dimensional image | video (2D) and the amount of shift | offset | difference performed by seeing a three-dimensional image | video (3D) as a training result of a 3rd work task. As a training result of the third work task, the standard deviation of the deviation amount obtained by viewing the two-dimensional image (2D) is compared with the standard deviation of the deviation amount performed by viewing the three-dimensional image (3D). FIG. It is a graph which compares and shows the stitching ligation time performed by seeing a two-dimensional image (2D) and the stitching and ligation time performed by viewing a three-dimensional image (3D) as a training result of the fourth work task. It is a graph which compares and shows the frequency | count of a grip mistake performed by seeing a two-dimensional image | video (2D) as a 4th work task, and the number of grip mistakes performed by seeing a three-dimensional image | video (3D). It is a box-and-whisker diagram comparing the correct answer rate when using a two-dimensional image and the correct answer rate when using a three-dimensional image as a training result of the first recognition task. It is a box-and-whisker diagram which compares and compares the correct answer rate performed using the flat monitor and the correct answer rate performed using the dome-shaped screen as a training result of the first recognition task. It is a box-and-whisker diagram comparing the correct answer rate when using a two-dimensional image and the correct answer rate when using a three-dimensional image as a training result of the second recognition task. It is a box-and-whisker diagram which compares and compares the correct answer rate performed using the flat monitor and the correct answer rate performed using the dome-shaped screen as a training result of the second recognition task. It is a box-and-whisker diagram comparing the correct answer rate when using a two-dimensional image and the correct answer rate when using a three-dimensional image as a training result of a third recognition task. It is a box-and-whisker diagram which compares and compares the correct answer rate performed using the flat monitor and the correct answer rate performed using the dome-shaped screen as a training result of the third recognition task.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Presentation part 2 Endoscopic training box 2a Insertion port 2b Camera apparatus 2d Insertion jig 2e Medical instrument 2f Training stand 2g Object 2h Contact sensor 2i Reference position contact sensor 3 Control apparatus 3a Control part 3b Analysis part 3c Recording part 4a Contact Sensor 4b Open / Close Sensor 5 Button 11 Dome Screen 11a Projection Surface 11b Hook 12 Projector for Left Eye 12a Lens 12b Polarization Filter for Left Eye 13 Projector for Right Eye 13a Lens 13b Polarization Filter for Right Eye 14 Reflector 15 Base 15a Back surface 15b Side surface 15c Triangle mark 16 Lifting device 17 Mounting member 17a Side surface 18 Moving body 19 Recess 20 Projector storage portion 21 Arm 21a Tip 22 Storage portion 22a Lower surface 23 Leg portion 24 Caster 25 Handrail 26 Drive portion 26a Upper surface 27 Noboru step 28 down lever knob

Claims (13)

An endoscopic surgical training device for training the operation of a medical instrument used by an operator in endoscopic surgery,
At least two straight objects;
Changing means for changing the distance between the objects or the thickness of each object;
Operation detecting means provided on each object to detect contact of the medical instrument;
Training start / end detection means that is provided at a predetermined reference position with respect to the object and detects the start and end of training by detecting contact of the medical instrument;
Presenting means for presenting an image obtained by imaging a space including the object and a predetermined reference position;
A setting means for setting a training task defined by the distance between the objects or the thickness of each object and the number of times of performing an operation of bringing the medical device into contact with the object;
Record the training start time and training end time based on the detection output of the training start / end detection means, and define in the training task based on the detection output of the operation detection means from the training start time to the training end time And a recording means for storing the time required for one operation. An endoscopic surgical training device for training the operation of a medical instrument used by an operator in endoscopic surgery,
A thin line-shaped object formed in a predetermined shape;
Changing means for changing the orientation or height of the object;
An operation detecting means provided on each object for detecting a gripping operation of the medical instrument;
Training start / end detection means that is provided at a predetermined reference position with respect to the object and detects the start and end of training by detecting contact of the medical instrument;
Presenting means for presenting an image obtained by imaging a space including the object and a predetermined reference position;
Setting means for setting a training task defined by the orientation or height of the object and the number of times that the medical instrument performs an operation of gripping the object;
A training start time and a training end time are recorded based on the detection output of the training start / end detection means, and defined in the training task based on the detection output of the operation detection means from the training start time to the training end time. And a recording means for storing the time required for one operation. The operation detection means detects the operation success and operation failure of the medical instrument for the object,
The training apparatus for endoscopic surgery according to claim 1 or 2, wherein the recording unit records the number of successful operations and the number of unsuccessful operations of the medical instrument based on the detection output of the operation detection unit. . An endoscopic surgical training device for training the operation of a medical instrument used by an operator in endoscopic surgery,
At least two objects including a ring-shaped portion and arranged to be shifted in the front-rear direction with respect to an operator of the medical instrument;
Changing means for changing the size of the ring-shaped portion of the object;
Operation detecting means for detecting that the medical instrument has passed a ring-shaped portion of the object;
Training start / end detection means that is provided at a predetermined reference position with respect to the object and detects the start and end of training by detecting contact of the medical instrument;
Presenting means for presenting an image obtained by imaging a space including the object and a predetermined reference position;
A setting means for setting a training task defined by the size of the ring-shaped part of the object and the number of times of performing the operation of passing the medical device to the ring-shaped part of the object;
Record the training start time and training end time based on the detection output of the training start / end detection means, and define in the training task based on the detection output of the operation detection means from the training start time to the training end time And a recording means for storing the time required for one operation. The operation detecting means detects a shift amount of a passing position of the medical instrument with respect to a center of a ring-shaped portion in the object;
The training apparatus for endoscopic surgery according to claim 4, wherein the recording unit records a shift amount of the passing position of the medical instrument detected by the operation detecting unit. An endoscopic surgical training device for training the operation of a medical instrument used by an operator in endoscopic surgery,
A suture practice board in which a plurality of target points are described in a plate-like material capable of passing a suture needle as the medical instrument;
A suturing detection means for detecting that the suturing needle is sewn to the target point described on the suturing practice board;
Ligation detection means for detecting a ligation operation of a suture by operation of the suture needle;
Training start / end detection means that is provided at a predetermined reference position with respect to the sewing practice board and detects the start and end of training by detecting contact of the medical instrument;
Presenting means for presenting an image obtained by imaging a space including the sewing practice board and a predetermined reference position;
A setting means for setting a training task defined by the number of times of sewing work and the number of times of ligation work for the sewing practice board;
A training start time and a training end time are recorded based on the detection output of the training start / end detection means, and based on the detection outputs of the suture detection means and the ligation detection means from the training start time to the training end time. A training device for endoscopic surgery, comprising: a recording unit that stores a time required to complete the training task. An endoscopic surgical training apparatus for training an operator in endoscopic surgery,
At least two straight objects;
Changing means for changing the distance between the objects or the thickness of each object;
Presenting means for presenting an image obtained by imaging a space including the object;
Input means for inputting the front-rear positional relationship of the object recognized by the operator;
Recording means for recording whether the front-rear position relationship of the object input to the input unit is correct or incorrect, or the difference between the front-rear position of the object input to the input unit and the front-rear position of the actual object. A training device for endoscopic surgery. An endoscopic surgical training apparatus for training an operator in endoscopic surgery,
A thin line-shaped object formed in a predetermined shape;
Changing means for changing the orientation or height of the object;
Presenting means for presenting an image obtained by imaging a space including the object;
Input means for inputting the orientation of the object recognized by the surgeon;
A recording means for recording the correctness of the orientation of the object input to the input means or the difference between the orientation of the object input to the input means and the actual orientation of the object. Mirror surgery training device. An endoscopic surgical training apparatus for training an operator in endoscopic surgery,
At least two objects including a ring-shaped portion and arranged to be shifted in the front-rear direction with respect to an operator of the medical instrument;
Changing means for changing the size of the ring-shaped portion of the object;
Presenting means for presenting an image obtained by imaging a space including the object;
Input means for inputting the front-rear positional relationship of the object recognized by the operator;
Recording means for recording whether the front-rear position relationship of the object input to the input unit is correct or incorrect, or the difference between the front-rear position of the object input to the input unit and the front-rear position of the actual object. A training device for endoscopic surgery.   10. The endoscope according to claim 7, wherein the recording unit records a determination time until a recognition state of the object is input to the input unit. Mirror surgery training device.   The training device for endoscopic surgery according to any one of claims 1 to 10, wherein the presenting unit presents training content or recorded information.   The said presentation means does not present information, when changing the state of the target object by the said change means, The any one of Claim 1 thru | or 5 and Claim 7 thru | or 10 characterized by the above-mentioned. An endoscopic surgical training apparatus according to claim 1.   An endoscopic surgical skill evaluation method for evaluating an operator's skill using information recorded by the recording means of the endoscopic surgical training apparatus according to any one of claims 1 to 12.

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