JP4544655B2 - Endoscopic surgical device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an endoscopic surgical apparatus for performing a surgical operation on a patient under observation by an endoscope.
[0002]
[Prior art]
In general, there is JP-A-6-269391 as an endoscopic surgical apparatus for performing a surgical operation in a patient's body under observation with an endoscope. Here, a body cavity diagnostic treatment apparatus is disclosed in which a tactile sensor is provided at the distal end of a treatment instrument, and tactile information obtained by the treatment instrument is displayed superimposed on an endoscopic image of a TV monitor. In this case, the endoscopic image and the tactile information can be confirmed simultaneously by visually observing the screen of the TV monitor during the surgical operation.
[0003]
[Problems to be solved by the invention]
However, in the configuration of the intra-body-cavity diagnostic treatment apparatus described in JP-A-6-269391, the tactile information obtained by the tactile sensor of the treatment tool is superimposed on the endoscopic image on the screen of the TV monitor. The visual information (color, brightness, etc.) that the mirror image has is lost to some extent. For this reason, it is difficult to see the screen of the TV monitor, and there is a problem that information is insufficient to confirm whether an appropriate treatment is being performed or to determine what treatment should be performed.
[0004]
In the traditional laparotomy, the affected part is generally confirmed directly with the eyes, and the operation of the affected part is confirmed by tactile sense of the hand. However, in the configuration of the in-vivo diagnostic treatment apparatus described in Japanese Patent Laid-Open No. 6-269391, a part of the visual information of the affected area displayed on the screen of the TV monitor is lost as described above. There is a problem that it is difficult for a surgeon who has made an accurate judgment regarding the treatment of the affected area.
[0005]
In addition, in order for the surgeon to make a more accurate determination regarding the treatment of the affected area, information related to the affected area requires not only visual information and tactile information but also other information (such as bioimpedance and MRI). The reality is that it is desired to be able to confirm a large amount of information from the monitor screen.
[0006]
The present invention has been made paying attention to the above circumstances, and its purpose is that the operator can obtain all the information necessary for proceeding with the treatment from one monitor, and the treatment currently performed by the operator can be performed. An object of the present invention is to provide an endoscopic surgical apparatus that can easily determine whether or not it is appropriate and can safely and reliably proceed with an operation.
[0007]
[Means for Solving the Problems]
Claim 1 The present invention provides an endoscopic surgical apparatus having observation means capable of displaying an image of a tissue in a living body on a monitor screen and treatment means for performing a treatment such as excision or coagulation on the living body. The living tissue is sandwiched between the distal ends of the elongated insertion portions that are inserted into the body. Having a pair of blades A treatment section is provided, the treatment section One blade of In contact with living tissue Arranged, Detect biological information 1st biological information detection means, It has a 2nd biological information detection means arrange | positioned in the contact part with the biological tissue in the other blade of the said treatment part, and detects biological information. A detection unit, a biological information display unit that displays the biological information obtained by the detection unit as image information on the screen of the monitor; and a biological information display unit configured to display the biological tissue obtained by the observation unit on the monitor screen. An endoscopic surgical apparatus characterized by comprising a display area dividing means for dividing an observation image display area and an image information display area of the biological information display means.
And this claim 1 In the present invention, during endoscopic surgery, the biological information is detected by the detection means of the contact portion with the biological tissue in the treatment section, and the biological information obtained by the detection means is displayed on the monitor screen by the biological information display means. The image information is displayed on the screen, and the display area dividing means divides the display area of the image of the in vivo tissue and the display area of the image information of the biometric information on the screen of the monitor, so that the operator can perform the treatment. All the information necessary for proceeding can be obtained from the screen of one monitor.
Claim 2 According to the present invention, the treatment means is an ultrasonic knife or an electric knife. 1 The endoscopic surgical operation apparatus described in 1.
Claim 3 According to the present invention, the detecting means is The first biological information detecting means Sensor that detects tactile information The second living body information detecting means is a sensor for detecting living body electrical information. Claims 1 The endoscopic surgical operation apparatus described in 1.
Claim 4 According to the present invention, the sensor for detecting the tactile information is a hardness sensor. Or A pressure sensor 3 The endoscopic surgical operation apparatus described in 1.
The invention according to claim 5 is characterized in that the sensor for detecting the electrical information is an impedance detection sensor. 3 The endoscopic surgical operation apparatus described in 1.
According to a sixth aspect of the present invention, the detection means includes: The first biological information detecting means The temperature sensor for measuring the temperature of a living body. 1 The endoscopic surgical operation apparatus described in 1.
The invention of claim 7 is characterized in that the temperature sensor is a thermocouple or an infrared temperature sensor. 5 The endoscopic surgical operation apparatus described in 1.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
The first embodiment of the present invention will be described below with reference to FIGS. 1 (A) and 1 (B). FIG. 1A shows a schematic configuration of the entire endoscopic surgical apparatus 1 according to the present embodiment. An endoscopic surgical apparatus 1 according to the present embodiment includes an ultrasonic scalpel 2, an ultrasonic driving device 3, a hardness detection unit 4, an impedance, and the like as a treatment means for performing treatment such as excision and coagulation on a living body. It comprises a detection unit 5, a camera control unit (CCU) 6, a monitor 7, a camera head 8, an endoscope (observation means) 9, and a light source device 10.
[0009]
Here, the endoscope 9 for observing the in-vivo tissue is provided with a long and thin insertion portion 9a inserted into the body, and a proximal-side operation portion 9b disposed at the proximal end portion of the insertion portion 9a. It has been. Further, the operation unit 9b is provided with an eyepiece 9c and a light guide connection base 9d. A light guide cable 11 for guiding illumination light sent from the light source device 10 is connected to the light guide connection base 9d.
[0010]
A camera head 8 is attached to the eyepiece 6. The output side of the camera head 8 is connected to the camera control unit 6. Further, a monitor 7 is connected to the camera control unit 6. When observing with the endoscope 9, illumination light transmitted from the light source device 10 is guided into the endoscope 9 and emitted to the outside from the distal end portion of the insertion portion 9 a of the endoscope 9. At this time, an observation image of the living tissue illuminated by the illumination light by the endoscope 9 is imaged on the camera head 8 through a lens system (not shown) inside the endoscope 9 and is shown in the drawing incorporated in the camera head 8. An electrical signal obtained by the non-CCD is input to the camera control unit 6.
[0011]
In addition, the ultrasonic scalpel 2 is provided with an elongated insertion portion 12 to be inserted into the body, and a proximal-side operation portion 13 disposed at the proximal end portion of the insertion portion 12. Here, the insertion portion 12 of the ultrasonic scalpel 2 is inserted into a trocar (not shown) previously punctured into the body, and is inserted into the body through this trocar. Furthermore, a scissors-like treatment portion 14 that sandwiches a living tissue is provided at the distal end portion of the insertion portion 12. The treatment section 14 is provided with a pair of blades (a fixed blade 15 and a movable blade 16).
[0012]
In addition, the operation unit 13 on the hand side has a base part 18 in which an ultrasonic transducer 17 is incorporated, a fixed handle 19 fixed to the base part 18, and a connection pin 20 with respect to the fixed handle 19. A movable handle 21 is provided that is openably and closably connected. Here, the handle 21 is connected to the movable blade 16 via an interlocking mechanism (not shown). Then, by opening and closing the movable handle 21 with respect to the fixed handle 19, the movable blade 16 of the treatment section 14 can be opened and closed.
[0013]
Further, hardness sensors (detection means) 22 and 22 are attached to the fixed blade 15 of the treatment section 14 at the contact portion with the living tissue H. Furthermore, impedance detection units (detection means) 23 and 23 are attached to the movable blade 16 of the treatment unit 14 in contact with the living tissue H.
[0014]
The ultrasonic vibration generated by the ultrasonic vibrator 17 can be transmitted to the fixed blade 15. Then, the living tissue H is sandwiched between the fixed blade 15 and the movable blade 16 of the treatment unit 14, and in this state, the ultrasonic vibration from the ultrasonic transducer 17 is transmitted to the fixed blade 15, thereby the treatment unit 14. The living body tissue H can be coagulated and separated by the ultrasonic vibration, and bleeding can be greatly reduced.
[0015]
A rotation operation unit 24 connected to the treatment unit 14 is disposed between the insertion unit 12 and the operation unit 13 on the hand side. The rotation operation unit 24 is rotatably supported with respect to the operation unit 13 and the insertion unit 12 on the hand side. The treatment section 14 can be rotated in the direction around the axis of the insertion section 12 by the rotation operation section 24.
[0016]
Further, a terminal 25 protrudes from the base portion 18 of the operation portion 13. The terminal 25 is connected to the ultrasonic drive device 3, the hardness detection unit 4, and the impedance detection unit 5. Here, the ultrasonic drive device 3 can drive the ultrasonic transducer 17 inside the base portion 18 of the operation portion 13 via the terminal 25.
[0017]
Further, the hardness detection unit 4 is connected to the hardness sensors 22 and 22 of the fixed blade 15 via terminals 25. The hardness information of the living tissue H obtained from the hardness sensor 22 can be converted into an image signal by the hardness detection unit 4 and output. Therefore, a biometric information display means for displaying the hardness information of the living tissue H, which is biometric information obtained by the hardness sensor 22, as image information on the screen of the monitor 7 by the hardness detection unit 4 is formed. Here, the video signal output from the hardness detection unit 4 may be a curve indicating the hardness of the living tissue H, a color, or a numerical value.
[0018]
The impedance detection unit 5 is connected to the impedance detection units 23 and 23 of the movable blade 16 via a terminal 25. The impedance of the living tissue H obtained from the impedance detection unit 23 is converted into a video signal by the impedance detection unit 5 and can be output. Therefore, the impedance detection unit 5 forms biological information display means for displaying the impedance of the biological tissue H obtained from the impedance detector 23 as image information on the screen of the monitor 7. Here, the video signal output from the impedance detection unit 5 may be a curve indicating the impedance of the living tissue H, a color, or a numerical value.
[0019]
Further, as described above, the output side of the camera head 8 is connected to the camera control unit 6, and the output sides of the hardness detection unit 4 and the impedance detection unit 5 are connected to each other. An observation image obtained by the endoscope 9 is converted into an electric signal by a CCD (not shown) in the camera head 8, and the electric signal output from the camera head 8 is input to the camera control unit 6, and the hardness detection unit. 4 and each video signal (hardness information of the living tissue H and impedance of the living tissue H) output from the impedance detection unit 5 are also input to the camera control unit 6. At this time, the camera control unit 6 converts the electrical signal input from the camera head 8 into a video signal and simultaneously displays the video signals input from the hardness detection unit 4 and the impedance detection unit 5 on the monitor 7. It is controllable.
[0020]
For example, as shown in FIG. 1B, a main screen 26 occupying most of the screen of the monitor 7, a first sub-screen 27a displayed at the upper right of the monitor 7 screen, and a lower right of the monitor 7 screen. The second sub-screen 27b displayed on the screen is divided into three, and the observation image of the endoscope 9 obtained by the camera head 8 is displayed on the main screen 26, and the first sub-screen on the upper right of the monitor 7 is displayed. An image showing the hardness of the living tissue H input from the hardness detection unit 4 in 27 a, and an image showing the impedance of the living tissue H input from the impedance detection unit 5 in the second sub-screen 27 b on the lower right of the monitor 7. Can be displayed. In FIG. 1B, the hardness and impedance of the living body are displayed as waveforms as an example. Thus, the camera control unit 6 causes the main screen 26, which is the display area for the observation image of the tissue in the living body, and the upper right first sub-screen 27a, which is the display area for the image information of the biological information, on the screen of the monitor 7. Display area dividing means for dividing the lower right second sub-screen 27b is formed.
[0021]
In the present embodiment, the first sub-screen 27a and the second sub-screen 27b are displayed on the right side of the main screen 26 on the screen of the monitor 7, but may be on the left side. It is good also as a structure which can switch a display place according to.
[0022]
Next, the operation of the above configuration will be described. When using the endoscopic surgical apparatus 1 according to the present embodiment, the operator operates the handle 21 while viewing the screen of the monitor 7 and confirming the observation image of the in vivo tissue by the endoscope 9 on the main screen 26. To do. Then, the living tissue H is grasped in a state where the living tissue H is sandwiched between the fixed blade 15 and the movable blade 16 of the treatment section 14. At this time, the hardness of the living tissue H is detected by the hardness sensor 22 of the fixed blade 15 in contact with the living tissue H, and the impedance of the living tissue H is similarly detected by the impedance detection unit 23 of the movable blade 16 in contact with the living tissue H. Is detected.
[0023]
Furthermore, the hardness information of the living tissue H obtained from the hardness sensor 22 is converted into an image signal by the hardness detection unit 4, and the impedance of the living tissue H obtained from the impedance detection unit 23 is similarly imaged by the impedance detection unit 5. Converted to a signal. Each video signal (hardness information of the living tissue H and impedance of the living tissue H) output from the hardness detection unit 4 and the impedance detection unit 5 is input to the camera control unit 6. The camera control unit 6 converts an electrical signal input from the camera head 8 into a video signal, and simultaneously displays each video signal input from the hardness detection unit 4 and the impedance detection unit 5 on the monitor 7. To control.
[0024]
At this time, the observation image of the in-vivo tissue by the endoscope 9 is displayed on the main screen 26 that occupies most of the screen on the screen of the monitor 7, and the hardness is displayed on the first sub-screen 27 a on the upper right of the screen of the monitor 7. An image indicating the hardness of the living tissue H input from the detection unit 4 and an image indicating the impedance of the living tissue H input from the impedance detection unit 5 are displayed on the second sub-screen 27b at the lower right of the monitor 7, respectively. The
[0025]
During the surgical operation, the operator visually observes the screen of the monitor 7 while coagulating / separating the living tissue H and confirms the coagulating / separating operation state of the living tissue H, Perform work such as separation. Here, during the coagulation and separation work of the biological tissue H, the image of the hardness and impedance of the biological tissue H displayed on the sub-screens 27a and 27b of the monitor 7 is exactly the coagulation / cutting of the biological tissue H. The process of being released is visualized and displayed. Therefore, the operator visually observes the screen of the monitor 7 during the work of coagulation / separation of the biological tissue H, whereby the color and brightness of the surface of the biological tissue H in the image observed by the endoscope 9 appearing on the main screen 26 are displayed. In addition, all the hardness and impedance of the biological tissue H being treated can be confirmed in real time.
[0026]
Therefore, the above configuration has the following effects. That is, in the present embodiment, the observation image of the in-vivo tissue by the endoscope 9 is displayed on the main screen 26 occupying most of the screen on the screen of the monitor 7, and the screen of the monitor 7 separated from the main screen 26 is displayed. An image showing the hardness of the living tissue H input from the hardness detection unit 4 on the first sub-screen 27a in the upper right of the screen, and an input from the impedance detection unit 5 on the second sub-screen 27b in the lower right of the monitor 7 An image showing the impedance of the living tissue H is displayed. For this reason, information on the hardness of the living tissue H in this portion is not displayed as an image on the observation image of the living tissue by the endoscope 9 displayed on the main screen 26 of the monitor 7. Further, there is no possibility that a part of the visual information of the affected part in the image displayed on the main screen 26 of the monitor 7 is lost, and information for determining whether the affected part is appropriately removed or coagulated by the operator. It can be displayed clearly. Therefore, as compared with the conventional case where the information of the hardness of the living tissue H of the portion being treated is superimposed on the image of the living tissue H of the portion to be treated and displayed as an image, the screen of the monitor 7 is visually observed. The amount of information supplied to the person is large, and the treatment is always appropriate for proceeding with the surgery.
[0027]
In particular, in the ultrasonic scalpel 2 of the present embodiment, the sharpness of the treatment section 14 is changed by the force of grasping the living tissue H between the fixed blade 15 and the movable blade 16 of the treatment section 14, and thus the above configuration is adopted. Thus, the surgeon can always proceed with the operation while adjusting the optimal state, that is, the state in which the living tissue H can be cut most. Therefore, it is possible to shorten the time of surgery.
[0028]
In the present embodiment, the configuration in which the hardness and impedance of the living tissue H is displayed as the image information of the living body information on the sub-screens 27a and 27b of the monitor 7 is shown. The temperature or the like may be displayed on the sub-screens 27a and 27b of the monitor 7 as image information of biological information. For example, when displaying MRI tomographic images on the sub-screens 27a and 27b, an MRI antenna may be used instead of the hardness sensor 22, and the hardness detection unit 4 may be changed to an MRI image processing unit.
[0029]
Further, when pressure is displayed on the sub-screens 27 a and 27 b of the monitor 7 as image information of biological information, a pressure sensor is used instead of the hardness sensor 22, and a pressure sensor is used instead of the hardness detection unit 4. A device that converts the detected signal into an image may be replaced.
[0030]
Further, when displaying temperature as image information of biological information on the sub-screens 27 a and 27 b of the monitor 7, a temperature sensor is used instead of the hardness sensor 22, and the temperature sensor is detected instead of the hardness detection unit 4. What is necessary is just to replace with the apparatus which converts the processed signal into an image.
[0031]
As described above, it is only necessary that the biological information necessary for the operation is displayed on the sub-screens 27a and 27b of the monitor 7, and the biological information is not limited to the hardness or impedance of the biological tissue H.
[0032]
FIG. 2 and FIGS. 3A and 3B show a second embodiment of the present invention. In the present embodiment, the configuration of the treatment section 14 of the ultrasonic scalpel 2 and the screen display of the monitor 7 in the endoscopic surgical apparatus 1 according to the first embodiment (see FIGS. 1A and 1B) are shown. It has been changed as follows.
[0033]
That is, in the present embodiment, the sawtooth 31 is formed on the living body contact surface side portion of the fixed blade 15 of the treatment section 14. Further, a hardness sensor 32 using a semiconductor pressure sensor is disposed in the middle of the saw blade 31.
[0034]
The hardness sensor 32 is disposed on the living body contact surface side that comes into contact with the living body, is provided inside the aluminum film 33, is in contact with the silicone gel 34, and a silicone gel 34 that transmits contact pressure. The semiconductor pressure sensor 35 is fixed to the fixed blade 15.
[0035]
Further, the hardness image displayed on the screen of the monitor 7 shows the degree of hardness as a bar graph 36 as shown in FIG. Further, on the screen of the monitor 7 according to the present embodiment, the bar graph 36 as an image for displaying the hardness is not divided as a sub-screen as in the first embodiment, and a portion that is not of concern to the operator, for example, the monitor 7 It is only necessary to be arranged somewhere in the four corners of the monitor 7 such as the lower right part of.
[0036]
However, the display method of the measurement data by the hardness sensor 32 is not limited to the bar graph 36, and a configuration in which a color display unit 37 for displaying a color indicating hardness is provided as shown in FIG. Soft and blue may be set as a color that means the hardest hardness, and the hardness between them may be configured to change the color displayed on the color display unit 37 according to the hardness. Although the hardness sensor 32 is provided on the fixed blade 15 in the present embodiment, it may be provided on the movable blade 16.
[0037]
Therefore, in the present embodiment, since the bar graph 36 as an image for displaying the hardness is arranged in a portion that does not care for the operator, such as the lower right portion of the monitor 7, an image displayed on the screen of the monitor 7. There is no possibility that a part of the visual information of the affected area will be lost, and information for determining whether the affected area is appropriately removed or coagulated can be displayed in an easy-to-understand manner.
[0038]
FIG. 4 shows a third embodiment of the present invention. In this embodiment, a hard blade attached to the fixed blade 15 of the treatment section 14 in the ultrasonic scalpel 2 of the endoscopic surgical apparatus 1 of the first embodiment (see FIGS. 1A and 1B). A temperature sensor is used instead of the length sensor 22. The temperature sensor used instead of the hardness sensor 22 is a thermocouple or an infrared temperature sensor.
[0039]
Further, in this embodiment, the monitor 7 displays numerical data 38 obtained by directly imaging the numerical value of the temperature measured by the temperature sensor. Instead of the numerical temperature data 38, a color display unit 37 shown in FIG. 3B that changes the color display according to the temperature may be provided. For example, blue is displayed on the color display unit 37 at 30 ° C., and red is displayed on the color display unit 37 at 120 ° C., and the colors displayed on the color display unit 37 are continuously displayed during these periods. You may make it the structure to change.
[0040]
Therefore, in the present embodiment, since the numerical data 38 obtained by directly imaging the numerical value of the temperature measured by the temperature sensor is displayed on the monitor 7, the excision and coagulation of the affected area can be performed as in the first embodiment. In addition to obtaining an effect that information for determining whether it is properly performed can be displayed in an easy-to-understand manner by the operator, in the present embodiment, in particular, by visually observing the numerical data 38 on the screen of the monitor 7, Since treatment can be performed while checking the temperature of the living body, surgery can be performed without applying excessive heat to the living body, and safer treatment is possible.
[0041]
FIG. 5 shows a fourth embodiment of the present invention. In this embodiment, a bipolar electric knife 41 is used in place of the ultrasonic knife 2 of the first embodiment (see FIGS. 1A and 1B), and a high frequency is used in place of the ultrasonic driver 3. An oscillator 42 is used.
[0042]
The electric scalpel 41 of the present embodiment is configured in the same manner as the ultrasonic scalpel 2 of the first embodiment except for the treatment section 43 disposed at the distal end of the insertion section 12 inserted into the body. Therefore, the same parts as those in the endoscopic surgical apparatus 1 according to the first embodiment are denoted by the same reference numerals, and the description thereof is omitted here.
[0043]
The treatment portion 43 of the electric knife 41 is provided with a fixed blade 44 and a movable blade 45 that are insulated from each other. A high-frequency current flows between the fixed blade 44 and the movable blade 45, and the living tissue H gripped between the fixed blade 44 and the movable blade 45 is separated or suspected. To be done.
[0044]
Further, the fixed blade 44 is provided with hardness sensors 22 and 22 on the contact surface with the living tissue H, and the movable blade 45 is provided with impedance detection units 23 and 23 on the contact surface with the living tissue H. Yes.
[0045]
Therefore, in the present embodiment, similarly to the first embodiment, the observation image of the in-vivo tissue by the endoscope 9 is displayed on the main screen 26 occupying most of the screen on the screen of the monitor 7, and this main screen is displayed. 26, an image showing the hardness of the living tissue H input from the hardness detection unit 4 on the first sub-screen 27a on the upper right of the screen of the monitor 7 separated from the screen 26, and a second sub-screen 27b on the lower right of the monitor 7 Since the images showing the impedance of the living tissue H input from the impedance detection unit 5 are respectively displayed on the main screen 26 of the monitor 7, this portion is displayed on the observation image of the living tissue by the endoscope 9 displayed on the main screen 26 of the monitor 7. The information on the hardness of the living tissue H is not displayed as an image. Therefore, there is no possibility that a part of the visual information of the affected part in the image displayed on the main screen 26 of the monitor 7 is lost, and information for determining whether the affected part is appropriately removed or coagulated is used. Compared to the case where the information of the hardness of the living tissue H of the part being treated is overlapped and displayed as an image on the image of the living tissue H of the part being treated as in the conventional case. The amount of information supplied to the surgeon who views the screen of the monitor 7 is large, and the treatment is always appropriate for proceeding with the surgery.
[0046]
Although only the hardness sensor 22 and the impedance detection unit 23 are described in this embodiment, all of the MRI antennas, pressure sensors, temperature sensors, etc. shown in the first to third embodiments are applicable. .
[0047]
FIG. 6 shows a fifth embodiment of the present invention. The endoscopic surgical apparatus 51 according to the present embodiment includes an endoscope 52, two camera heads 53A and 53B, a camera control unit 54, and a monitor 55.
[0048]
Further, the endoscope 52 is provided with an operation portion 57 on the proximal side at a proximal end portion of an elongated insertion portion 56 to be inserted into the body. A visible eyepiece 58 is disposed at the terminal portion of the hand side operation unit 57. The eyepiece 58 is connected to the first camera head 53A.
[0049]
A light guide base 59 and an infrared eyepiece 60 project from the outer peripheral surface of the hand side operation unit 57. Here, the second camera head 53 </ b> B is connected to the infrared eyepiece 60. The second camera head 53B is connected to the camera control unit 54 together with the first camera head 53A. Further, the camera control unit 54 is connected to a monitor 55.
[0050]
A battery-type light source device 61 is detachably connected to the light guide base 59 for illumination. Here, a light guide glass fiber 62 is provided from the light guide base 59 to the tip through the inside of the endoscope 52, and the light generated by the light source device 61 is emitted from the tip of the endoscope 52. It has become so.
[0051]
Also, a prism that divides one optical path guided to the proximal side operation unit 57 side through the lens system 63 inside the insertion unit 56 into two optical paths inside the proximal side operation unit 57 of the endoscope 52. 64 is arranged. Then, the observation image of the endoscope 52 is guided to the hand side operation unit 57 side through the lens system 63 inside the insertion unit 56 and then divided into two optical paths by the prism 64. At this time, one of the branched optical paths travels in the same direction as the optical axis of the lens system 63, is guided to the visible light eyepiece 58 of the proximal side operation unit 57 of the endoscope 52, and is connected to the CCD 65A in the first camera head 53A. Imaged.
[0052]
Further, another branch optical path divided by the prism 64 advances in a direction perpendicular to the optical axis of the lens system 63, passes through the infrared eyepiece 60 of the operation unit 57, and forms an image on the CCD 65B of the second camera head 53B. . A cover glass 66 made of a filter that cuts light having a wavelength smaller than that of infrared light is disposed at the end of the infrared light eyepiece 60. Therefore, the light that has passed through the cover glass 66 is in the infrared region.
[0053]
The camera control unit 54 converts the electrical signals input from the two camera heads 53A and 53B into video signals, and displays the screen of the monitor 55 on the main screen 67 and one of the four corners of the main screen 67, for example, a book. In the embodiment, the image is divided into a sub-screen 68 arranged at the upper left of the main screen 67, an image that has passed through the visible light eyepiece 58 is displayed on the main screen 67, and the intensity and wavelength of infrared light that has passed through the cover glass 66. It is possible to control so as to display the image of the temperature reference portion with emphasis on the sub screen 68 according to the above. Note that the image of the temperature reference portion on the sub-screen 68 of the monitor 55 is controlled so that the temperature of the infrared light generation portion can be known in accordance with the intensity and wavelength of the infrared light.
[0054]
When the endoscopic surgical apparatus 51 of the present embodiment is used, the observation image of the in vivo tissue by the endoscope 52 is displayed on the main screen 67 occupying most of the screen on the screen of the monitor 55, and the affected part An infrared light image obtained by imaging the temperature is displayed on the sub-screen 68 at the upper left of the screen of the monitor 55. Therefore, during the surgical operation, the operator can separate the affected part by visually checking the screen of the monitor 55 while confirming the affected part and the tip of a treatment tool such as an ultrasonic scalpel or an electric knife. At this time, the infrared light image displayed on the sub-screen 68 is an image of the temperature of the affected area, and the surgeon can simultaneously view the image and temperature of the surface of the affected area.
[0055]
Therefore, even in the above configuration, there is an effect that information for determining whether or not the affected part is appropriately excised or coagulated can be displayed in an easy-to-understand manner by the operator, as in the third embodiment. .
[0056]
In this embodiment, the main screen 67 and the sub screen 68 are displayed separately. However, the main screen (normal image) and the sub screen (infrared light enhanced image) are overlaid as necessary. It is good also as a structure which can be switched so that it can display.
[0057]
FIGS. 7A and 7B show a sixth embodiment of the present invention. In the present embodiment, the configuration of the camera control unit 6 and the connection with the ultrasonic driving device 3 in the endoscopic surgical apparatus 1 according to the first embodiment (see FIGS. 1A and 1B) are as follows. It is changed as follows.
[0058]
That is, the camera control unit 71 of the present embodiment is connected to the ultrasonic drive device 3 as shown in FIG. 7A, and the output of the ultrasonic drive device 3 is output by an electrical signal generated by the camera control unit 71. It can be controlled.
[0059]
Further, as shown in FIG. 7B, the camera control unit 71 comprises a video signal generation unit 72, a color extraction unit 73, and an ablation level determination unit 74. Here, the electrical signal sent from the camera head 8 is converted into a video signal by the video signal generation unit 72 and output to the monitor 7 and the color extraction unit 73.
[0060]
Further, the color extraction unit 73 extracts a specific color or luminance, for example, a portion that is significantly whiter or blacker than the surroundings, or has a higher luminance, and outputs the information to the ablation level determination unit 74. The ablation level determination unit 74 determines the ablation level of the living body from the extracted video signal, and transmits an ultrasonic scalpel control signal corresponding to the level to the ultrasonic drive device 3. Here, the output of the ultrasonic driving device 3 is controlled to be lowered by the ultrasonic knife control signal, and the output is stopped particularly when the ablation level is excessive.
[0061]
When the endoscopic surgical apparatus 1 according to the present embodiment is used, an endoscope image of the affected part and the tip of the ultrasonic scalpel 2 that holds the affected part are connected to the endoscope 9 and the camera control unit 71. Thus, the image is displayed on the monitor 7. Therefore, during the surgical operation, the operator can separate the affected part by visually checking the screen of the monitor 7 while confirming the affected part and the tip of the ultrasonic scalpel 2 that holds the affected part. At this time, the video signal generation unit 72, the color extraction unit 73, and the ablation level determination unit 74 of the camera control unit 71 determine the ablation level of the separation site, and the output of the ultrasonic driving device 3 is controlled to an appropriate level. .
[0062]
Therefore, the above configuration has the following effects. That is, by the image processing of the camera control unit 71, the ablation level of the separation site of the ultrasonic scalpel 2 is determined, and the output of the ultrasonic driving device 3 is controlled to an appropriate level, so that excision and coagulation are performed. It is possible to reduce the damage to the broken parts and always perform a safe treatment. Moreover, at the same time, an image of the cut site itself is displayed on the main screen 26 of the monitor 7, and the hardness and impedance of the living tissue H can be confirmed on the sub screens 27 a and 27 b of the monitor 7. be able to.
[0063]
In this embodiment, an ultrasonic scalpel is used as a treatment tool, but an electric scalpel may be used instead. In this case, the ultrasonic knife 2 may be changed to an electric knife, and the ultrasonic driver 3 may be changed to a high frequency oscillator. In this case, the same effect as described above can be obtained.
[0064]
Furthermore, the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the present invention.
Next, other characteristic technical matters of the present application are appended as follows.
Record
(Additional Item 1) In an endoscopic surgical apparatus including an observation system capable of displaying an in-vivo image on a monitor and a treatment tool for applying a treatment such as excision or coagulation to the living body, at least the observation system or the treatment tool Endoscopic surgery characterized in that at least one sensor for detecting biological information is provided on either one of the images, and an image obtained by converting the in-vivo image and the biological information obtained by the sensor can be displayed on a monitor. apparatus.
[0065]
(Additional Item 2) The endoscopic surgical apparatus according to Additional Item 1, wherein the sensor is a solid-state imaging device connected to an endoscope of an observation system.
(Additional Item 3) The endoscopic surgical apparatus according to Additional Item 2, wherein the endoscope includes an eyepiece for visible light and an eyepiece for infrared light.
[0066]
(Additional Item 4) The endoscopic surgical apparatus according to Additional Item 3, wherein the infrared eyepiece includes a filter for cutting light having a wavelength smaller than that of the infrared light.
[0067]
(Additional Item 5) The endoscopic surgical apparatus according to Additional Item 1, wherein the sensor is provided at a distal end of a treatment instrument.
(Additional Item 6) The endoscopic surgical apparatus according to Additional Item 1 or 5, wherein the treatment instrument is an ultrasonic knife or an electric knife.
[0068]
(Additional Item 7) The endoscopic surgical apparatus according to Additional Item 5, wherein the sensor is a sensor that detects tactile information.
(Additional Item 8) The endoscopic surgical apparatus according to Additional Item 7, wherein the sensor that detects the tactile information is a hardness sensor or a pressure sensor.
[0069]
(Additional Item 9) The endoscopic surgical apparatus according to Additional Item 5, wherein the sensor is a sensor that detects electrical information of a living body.
(Additional Item 10) The endoscopic surgical apparatus according to Additional Item 9, wherein the sensor that detects electrical information of the living body is an impedance detection sensor.
[0070]
(Additional Item 11) The endoscopic surgical apparatus according to Additional Item 5, wherein the sensor is a temperature sensor that measures the temperature of a living body.
(Additional Item 12) The endoscopic surgical apparatus according to Additional Item 11, wherein the temperature sensor is a thermocouple or an infrared temperature sensor.
[0071]
(Additional Item 13) The endoscope according to Additional Item 1, wherein the image displayed on the monitor is an in-vivo image and an image obtained by converting biological information are arranged at different positions on the same monitor. Lower surgical device.
[0072]
(Additional Item 14) The camera control unit that generates a video signal in the observation system includes a processing unit that performs image processing according to the luminance and color of the video signal in addition to the video signal generation unit. Endoscopic surgical device.
[0073]
(Additional Item 15) The endoscopic surgical apparatus according to Additional Item 14, wherein the camera control unit can generate a signal for controlling an output of the ultrasonic knife or electric knife by the processing unit.
[0074]
(Additional Item 16) The endoscopic surgical apparatus according to Additional Item 15, wherein the output of the processing unit of the camera control unit can be input to an ultrasonic knife or an electric knife.
[0075]
(Additional Item 17) In an endoscopic surgical apparatus having observation means capable of monitoring and displaying an image of tissue in a living body and treatment means for performing treatment such as excision and coagulation on the living body, the observation means or the treatment means A detecting means for detecting at least one biological information provided on at least one of the above and a biological information display means for displaying the biological information obtained by the detecting means as image information on the monitor. An endoscopic surgical apparatus characterized in that an image of the in-vivo tissue and the biological information can be displayed.
[0076]
(Prior Art of Additional Items 1 to 17) The present application relates to an endoscopic surgical apparatus. For the prior art, see JP-A-6-269391.
(Problems to be Solved by Additional Items 1 to 17) In the embodiment of Japanese Patent Application Laid-Open No. 6-269391, a tactile sensor is provided at the distal end of a treatment instrument, and the tactile information obtained by the treatment instrument is displayed on the inside of the TV monitor An intra-body-cavity diagnostic treatment apparatus that is displayed superimposed on a mirror image is disclosed. The intra-body-cavity diagnostic treatment apparatus having such a configuration can easily recognize the obtained tactile information, but lacks information to confirm whether an appropriate treatment is being performed or what kind of treatment should be performed. Yes. This is because, in the above embodiment, the tactile information is superimposed on the endoscopic image, so that the visual information (color, brightness, etc.) of the original endoscopic image is lost to some extent. In traditional laparotomy, the affected area is directly confirmed by the eyes, and the operation is proceeded by confirming the touch of the affected area by the sense of touch of the hand. However, since the visual information of the affected area is lost as described above in the above embodiment, there is a drawback that it is difficult for the operator to make an accurate determination regarding the treatment of the affected area. In addition, in order to make a more accurate determination, information related to an affected part is not only visual information and tactile information, but also other information (such as bioimpedance and MRI).
[0077]
(Purpose of Supplementary Items 1 to 17) Information for determining whether or not the affected part has been appropriately excised or coagulated is displayed in an easily understandable manner by the operator.
(Means for Solving the Problems of Additional Items 1 to 17) In order to eliminate the above disadvantages, the present application relates to an observation system capable of displaying an in-vivo image on a monitor, and a treatment tool for applying treatment such as excision and coagulation to the living body. In an endoscopic surgical apparatus comprising: a sensor for detecting at least one biological information is provided in at least one of an observation system or a treatment tool, and an in-vivo image and biological information obtained by the sensor are displayed on the monitor. The converted image can be displayed, and the image displayed on the monitor is configured such that the image inside the living body and the image converted from the biological information are arranged at different positions on the same monitor. With this configuration, the operator can obtain all information necessary for proceeding with the treatment from one monitor.
[0078]
(Effects of Supplementary Items 1 to 17) By the supplementary item of the present application, information for determining whether or not the affected part has been appropriately excised or coagulated is displayed in an easy-to-understand manner. It can be easily determined whether or not the treatment is appropriate, and the operation can proceed safely and reliably.
[0079]
【The invention's effect】
According to the present invention, as described above, according to the present invention, at least one of observation means and treatment means is provided with detection means for detecting biological information, and the biological information obtained by this detection means is displayed by the biological information display means. Displayed as image information on the monitor screen, and the display area dividing means divides the display area of the endoscopic image of the in vivo tissue and the display area of the image information of the biological information on the monitor screen. Therefore, information for determining whether the affected part is excised or coagulated properly is displayed on the screen of one monitor in an easy-to-understand manner. Therefore, all information necessary for the surgeon to proceed with the procedure can be obtained from one monitor, the surgeon can easily determine whether or not the procedure currently being performed is appropriate, and the surgery can be performed safely and reliably. Can proceed.
[Brief description of the drawings]
1A and 1B show a first embodiment of the present invention, in which FIG. 1A is a schematic configuration diagram of an entire endoscopic surgical apparatus, and FIG. 1B is a display of an image displayed on a monitor screen; The front view which shows a state.
FIG. 2 is a longitudinal sectional view showing a main configuration of a second embodiment of the present invention.
3A is a front view showing a display state of an image displayed on the monitor screen of the second embodiment, and FIG. 3B is a modification of the display state of the image displayed on the monitor screen. The front view which shows an example.
FIG. 4 is a front view showing a display state of an image displayed on a screen of a monitor according to a third embodiment of the present invention.
FIG. 5 is a schematic configuration diagram of an entire endoscopic surgical apparatus according to a fourth embodiment of the present invention.
FIG. 6 is a schematic configuration diagram of an entire endoscopic surgical apparatus according to a fifth embodiment of the present invention.
7A and 7B show a sixth embodiment of the present invention, in which FIG. 7A is a schematic configuration diagram of an entire endoscopic surgical apparatus, and FIG. 7B is a schematic configuration diagram of a camera control unit.
[Explanation of symbols]
2 Ultrasonic knife (treatment method)
4 Hardness detection unit (biological information display means)
5 Impedance detection unit (biological information display means)
6 Camera control unit (display area dividing means)
7 Monitor
9 Endoscope (observation means)
22 Hardness sensor (detection means)
23 Impedance detection unit (detection means)
26 Main screen (display area for observation images of in vivo tissues)
27a First sub-screen (display area for image information of biological information)
27b Second sub-screen (display area for image information of biological information)

Claims (7)

An observation means capable of displaying an image of in vivo tissue on a monitor screen;
In an endoscopic surgical apparatus having a treatment means for performing treatment such as excision and coagulation on a living body,
The treatment means is provided with a treatment portion having a pair of blades sandwiching a biological tissue at a distal end portion of an elongated insertion portion to be inserted into the body, and is disposed at a contact portion with the biological tissue on one blade of the treatment portion , Detection means comprising: first biological information detection means for detecting biological information; and second biological information detection means that is disposed at a contact portion of the other blade of the treatment section with the biological tissue and detects biological information. As well as
Biological information display means for displaying biological information obtained by the detection means as image information on the screen of the monitor;
The display area dividing means for dividing the display area of the observation image of the tissue in the living body by the observation means and the display area of the image information of the biological information display means are provided on the screen of the monitor. Endoscopic surgical device. The endoscopic surgical apparatus according to claim 1 , wherein the treatment means is an ultrasonic knife or an electric knife. Said sensing means, wherein said first biological information detection means Ri sensor der to detect tactile information, said second living body information detecting means and said sensor der Rukoto for detecting the electrical information of a living body The endoscopic surgical apparatus according to Item 1 . The endoscopic surgical apparatus according to claim 3 , wherein the sensor that detects the tactile information is a hardness sensor or a pressure sensor. The endoscopic surgical apparatus according to claim 3 , wherein the sensor that detects the electrical information is an impedance detection sensor. It said sensing means, endoscopic surgical apparatus according to claim 1, wherein the first biological information detection means is a temperature sensor for measuring the temperature of a living body. The endoscopic surgical apparatus according to claim 6 , wherein the temperature sensor is a thermocouple or an infrared temperature sensor.

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