JP4382924B2 - Surgery support system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a surgical operation support system including a position detection display device having an optical receiving device and a surgical instrument to which a plurality of signal members are attached.
[0002]
[Prior art]
Along with the development of diagnostic imaging technology in recent years, it is possible to create a surgical plan before surgery using tomographic images based on diagnostic imaging, and to make safer surgery by effectively using the image information during surgery. Aiming to improve surgical instruments such as surgical microscopes.
[0003]
For example, in the field of neurosurgery, the observation position of the surgical microscope during operation is specified in a three-dimensional space, and integration with image information such as superimposing the position on the preoperative diagnostic image is planned. The tomographic image information for can be obtained.
[0004]
Normally, the position of a surgical instrument is detected using a position detection display device, and an optical position detection method is disclosed in Japanese Patent Laid-Open No. 5-305073 as an example. When the surgeon uses the surgical instrument at a desired position and posture, the position and posture of the surgical instrument are detected. This includes a plurality of (two or more signal members attached to the surgical instrument to be detected ( The image is picked up by a receiving member (a minimum number required for position detection).
[0005]
Further, in order to detect the position of the observation point of the surgical microscope, for example, the focal distance can be changed, the focal distance data is notified from the surgical microscope to the position detection display device by wired communication means such as RS-232C. An example is disclosed in GB 2288249.
[0006]
Further, when the position of the surgical instrument is detected, the operation signal and the setting information of the surgical instrument are notified to the position detection display device by wired communication means.
[0007]
Japanese Laid-Open Patent Publication No. 5-305073 and DE19639615 disclose an example of the position detection of the above-described surgical instrument. Japanese Patent Application No. 10-319190 proposes a method for detecting the three-dimensional position of a surgical instrument in a surgical microscope. Further, GB2288249 discloses a technique related to connection between a surgical microscope and peripheral devices such as a position detection display device.
[0008]
[Problems to be solved by the invention]
The prior art including the above-mentioned Japanese Patent Application Laid-Open No. 5-305073, DE19639615, Japanese Patent Application No. 10-319190, GB2288249 has the following drawbacks.
[0009]
That is, there are devices for maintaining the life of the patient in the operating room, and radio waves are not used to exchange data between surgical devices in order not to affect the devices, such as RS-232C. It was done by wired communication represented by
[0010]
However, many devices are installed in the operating room, and many wirings already exist on the operating room floor. As described in the prior art, it is necessary to connect to the position detection display device in order to detect the position of the surgical instrument. Had been worsening.
[0011]
Therefore, the surgeon and the operation staff have to pay attention to the scaffold when moving the operating room, which is a factor that prevents smooth operation and mental fatigue. In addition, wiring must be performed at the time of setup, resulting in a long setup time and an increase in the fatigue of surgical staff.
[0012]
Furthermore, the length of the cable connecting the surgical instrument and the position detection display device is limited. Depending on the length of the cable, the placement of the instrument in the operating room is limited, and the operating space in the limited operating room is limited. It was also a factor that hindered the effective use of.
[0013]
The present invention has been made paying attention to such a problem, and the object of the present invention is to provide a data communication cable between the position detection display device and the surgical instrument in the position detection of the surgical instrument using the position detection display device. An object of the present invention is to provide a surgical operation support system that can eliminate the need for wiring and reliably perform data communication in a state in which the position of the surgical instrument can be detected regardless of the position and posture of the surgical instrument.
[0014]
[Means for Solving the Problems]
  In order to achieve the above object, a surgery support system according to a first invention includes a surgical instrument, a plurality of signal members attached to the surgical instrument,Detecting at least positions of the plurality of signal membersHaving an optical receiver,Based on the position of the signal member detected by the optical receiverA position detection display device that detects and displays at least the position of the surgical instrument, and a transmission / reception unit for optical communication is provided to perform optical communication between the position detection display device and the surgical instrument. , Provided in the optical receiving device and a signal plate in which the plurality of signal members are integrally formed within a range surrounded by the plurality of signal members,The transmission unit of the transmission / reception unit is controlled to be lit with a predetermined light emission pattern based on data communicated between the position detection display device and the surgical instrument, and the reception unit of the transmission / reception unit includes the transmission The light emission pattern signal at the unit is detected and processed.
[0015]
Further, the surgery support system according to the second invention is a surgical instrument, a plurality of signal members attached to the surgical instrument,Detecting at least positions of the plurality of signal membersAn optical receiver,Based on the position of the signal member detected by the optical receiverA position detection display device that detects and displays at least the position of the surgical instrument, and a receiver for the optical communication is provided to perform optical communication between the position detection display device and the surgical instrument. Provided in the optical receiver, the transmitter for optical communication is provided in a range surrounded by the plurality of signal members or a signal plate integrally formed with the plurality of signal members,The transmission unit is controlled to be lit with a predetermined light emission pattern based on data communicated between the position detection display device and the surgical instrument, and the reception unit detects a light emission pattern signal in the transmission unit. And process.
  In the surgery support system according to the third invention, in the first invention or the second invention, at least one of the signal members also serves as a transmission unit of the surgical instrument.
  In the surgery support system according to the fourth invention, in the first invention or the second invention, the position detection unit of the optical reception device also serves as the reception unit of the position detection display device.
  Further, the surgery support system according to a fifth invention is the surgery support system according to the first invention, wherein the data communicated between the position detection display device and the surgical instrument is a focus distance value, a zoom magnification value of the surgical instrument, A focal length automatic adjustment command to the surgical instrument is included.
  According to a sixth aspect of the present invention, in the surgery support system according to the second aspect of the present invention, the data communicated between the position detection display device and the surgical instrument includes a focus distance value and a zoom magnification value of the surgical instrument. Contains.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
First, an outline of an embodiment of the present invention will be described. The surgical operation support system of the present embodiment is attached to a surgical instrument such as a surgical microscope, a position detection display device having an optical receiver for detecting the position and posture of the surgical instrument, and the surgical instrument, The optical receiving device includes a plurality of signal members detected by the optical receiving device, and in order to perform optical communication between the position detection display device and the surgical instrument, a transmission / reception unit for the optical communication is provided in the optical receiving device. The device is provided in a range surrounded by the plurality of signal members or a signal plate in which the plurality of signal members are integrally formed.
[0017]
When detecting the position and posture of the surgical instrument with such a configuration, optical signals from a plurality of signal members attached to the surgical instrument are received by the optical receiver, and the position of the surgical instrument in the position detection display device And calculate the posture.
[0018]
Data communication from the surgical instrument to the position detection display device is performed as follows. In the transmission unit of the surgical instrument, a light emitting member provided in the vicinity of the signal member emits light based on the data of the surgical instrument. In the reception unit of the position detection display device, a light emission signal from the transmission unit is detected and processed by a reception member provided in the optical reception device. If the light emission signal is data related to position detection, communication can be reliably performed when position detection is possible.
[0019]
On the other hand, data communication from the position detection display device to the surgical instrument is performed as follows. The position detection display device causes a light emitting member provided in the optical receiving device to emit light according to data. In the surgical instrument, an optical signal from the light emitting member is received by a receiving member provided in the vicinity of the signal member, and a process according to the data is performed by a control device in the surgical instrument. In this case, if it is assumed that the position of the data is detected, it is possible to reliably communicate when the position can be detected, and the position detection display device can superimpose the image on the preoperative diagnostic image. To display.
Here, the vicinity of the signal member attached to the surgical instrument is an area of the surface formed by the plurality of signal members (enclosed by the plurality of signal members) on the signal plate integrally formed with the plurality of signal members. It becomes. Actually, in many cases, there are a plurality of surfaces formed by a plurality of signal members. When the signal member is formed in a ring shape, the data transmission unit may be provided in a ring shape of the signal member at regular intervals so that the data reception unit can receive the signal member.
[0020]
Needless to say, a weaker (wider) directionality of light emission by the light emitting member is more suitable for this embodiment. Further, the data receiving unit of the position detection display device may be a receiving member itself for position detection.
[0021]
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0022]
(First embodiment)
(Constitution)
1 is a diagram showing a schematic configuration of the entire surgical microscope, FIG. 2 is an enlarged view of a mirror part, FIG. 3 is a diagram showing an internal configuration of the mirror part, FIG. 4 is a functional block diagram of a surgery support system, FIG. FIG. 4 is a diagram illustrating an example of an image displayed on a monitor of a workstation.
[0023]
First, a schematic configuration of the surgical microscope 1 will be described with reference to FIG. A base 4 that can move on the floor and a support column 5 are erected on the base 4, and an upper end of the support column 5 has one end of a first arm 6 in which an illumination light source (not shown) is incorporated as an axis O 1. It is attached so that it can rotate freely.
[0024]
Further, one end of the second arm 7 is attached to the other end of the first arm 6 so as to be rotatable about the axis O2. The second arm 7 is a pantograph arm composed of a link mechanism and a spring member for balance adjustment in order to perform a vertical movement operation, and a third arm 8 is attached to the other end so as to be rotatable about an axis O3. ing. The mirror body 3 is provided at the other end of the third arm 8. The third arm 8 is an arm that enables the up-and-down direction of the mirror 3 with respect to the observation direction of the operator about the axis O4 and the up-and-down direction of the operator about the axis O5.
[0025]
Further, in order to adjust the position of the mirror body 3 freely and to fix the position, electromagnetic rotating brakes (not shown) are provided on the rotating portions of the rotating shafts O1 to O5. The electromagnetic brake is connected to an electromagnetic brake power supply circuit (not shown) built in the column 5, and the electromagnetic brake power supply circuit is connected to the microscope control unit 22 (FIG. 4).
[0026]
Next, the optical receiver 30 will be described. The optical receiver 30 is for detecting the position of a three-dimensional coordinate of three LEDs on a signal plate, which will be described later, and includes two infrared semiconductor cameras 31a and 31b as the receiving member and data receiver and the infrared semiconductor camera. The camera support member 32 and the stand 34 fix the positions of 31a and 31b, and are installed on the operating room floor. The infrared semiconductor cameras 31a and 31b are fixed by a camera support member 32 so that the two optical axes are orthogonal to each other at a constant distance. The infrared semiconductor cameras 31 a and 31 b are connected to the measuring device 20, and the measuring device 20 is connected to the workstation 29 via the A / D converter 33.
[0027]
The workstation 29 is connected to a monitor 43, and in a recording unit (not shown) inside the workstation 29, the tomographic image data by an image diagnostic device (not shown) such as CT or MRI and the tomographic image data are processed in advance in three dimensions before surgery. The reconstructed data is recorded.
[0028]
FIG. 2 is an enlarged view of the part of the mirror body 3. The switch 10 provided on the grip 9 integrally fixed to the mirror body 3 is connected to the microscope control unit 22 (FIG. 4).
[0029]
In FIG. 2, 17 is a signal plate for the optical receiving device 30 to detect the three-dimensional coordinates of the mirror body 3. Three infrared light emitting diodes (LEDs) 18a, 18b, and 18c are integrally fixed to the signal plate 17 as a signal member and data transmission unit. Each of the LEDs 18a, 18b, and 18c is connected to an LED control device 27 (FIG. 4) built in the support column 5, respectively. Reference numeral 15 denotes a focal position of the mirror body 3. Reference numerals 35a, 35b, and 35c are mark members attached to the patient 37 to be treated. Ob-XbYbZb is a biological coordinate system defined on the basis of the mark members 35a, 35b, and 35c.
[0030]
As shown in FIG. 3, the mirror body 3 includes an objective lens 11, a variable magnification optical system 12, a pair of imaging lenses 13a and 13b, and a pair of eyepieces 14a and 14b. The three-dimensional observation optical system is configured in order on the observation optical axis. The imaging planes formed by the imaging lenses 13a and 13b are arranged so as to be the focal positions of the eyepieces 14a and 14b, respectively. The objective lens 11 is connected to a motor (not shown) and is configured to be movable in the optical axis direction. The position sensor 16 can detect the lens position. The variable magnification optical system 12 is also connected to a motor (not shown) and is configured to be movable in the optical axis direction. The position sensor 21 can detect the lens position.
[0031]
FIG. 4 is a functional block diagram of the surgery support system. Each of the position sensors 16 and 21 is connected to the microscope control unit 22. The microscope control unit 22 is connected to the LEDs 18a, 18b, and 18c described above via the data conversion unit 19 and the LED control device 27.
[0032]
The infrared semiconductor cameras 31 a and 31 b of the optical receiver 30 are connected to the monitor 43 via the measuring device 20, the A / D converter 33, and the workstation 29, respectively.
[0033]
FIG. 5 is a diagram showing an example of an image displayed on the monitor screen. The focal position 15 of the surgical microscope 1 is superimposed along with the three-dimensionally reconstructed image based on the preoperative tomographic image of the patient 37. 45 is an operation part.
[0034]
(Function)
The operation of the above configuration will be described below. Before the operation, mark members 35a, 35b, and 35c are attached to the head of the patient 37, and three tomographic images such as CT and MRI apparatuses that have been taken in advance are used so that a tomographic image in which the three points enter the same cross section becomes a reference. Reconstructed into dimensional image data and recorded in the workstation 29. When starting the operation, calibration (memory of the biological coordinate system Ob-XbYbZb) is performed using the mark members 35a, 35b, and 35c in order to correlate the tomographic image data in the workstation 29 and the coordinates in the actual surgical site. Do. Through the above operation, the living body coordinate system is stored in the workstation 29, and the three-dimensional image data of the monitor 43 is displayed on the living body coordinate system in the image on the monitor 43.
[0035]
In the operation, the operator 44 grasps the grip 9 and presses the switch 10 to release the lock by the electromagnetic brake built in the shafts O1 to O5, and moves the lens body 3 to focus on the observation site of the surgical section 45. 15 is positioned.
[0036]
46 is one of the surgical staffs mainly for operating the workstation. The light beam emitted from the surgical part 45 enters the mirror body 3. The light beam incident on the mirror body 3 from the objective lens 11 is observed through the variable magnification optical system 12, the imaging lenses 13a and 13b, and the eyepieces 14a and 14b, and the operator 44 moves the surgical part 45 at a desired magnification. Observe. When the focus position of the observation image does not match, the objective lens 11 is driven by the motor (not shown) and focused.
[0037]
Further, the position sensors 16 and 21 transmit lens position information of the objective lens 11 and the variable magnification optical system 12 to the microscope control unit 22, respectively. The lens position information is transmitted to the data converter 19 and converted into a focus distance value and a zoom magnification value of the observation point 15. Further, the data conversion unit 19 creates a light emission pattern signal having a cycle that can be sampled with respect to the imaging cycle of the infrared semiconductor cameras 31 a and 31 b according to the focus distance value and the zoom magnification value, and outputs the light emission pattern signal to the LED control device 27. .
[0038]
The LED control device 27 adds the individual light emission pattern signals of the LEDs 18a, 18b, and 18c to the light emission pattern signal, and performs lighting control in a time-sharing manner (for example, a communication format similar to the RS-232C asynchronous type).
[0039]
The optical receiver 30 detects light from the LEDs 18a, 18b, 18c. The detected light is signal-processed by the measuring device 20 and the A / D converter 33 and transmitted to the workstation 29. In the workstation 29, the individual light emission pattern signal of the LED is extracted from the light emission pattern signal of each LED, and the position and orientation of the signal plate 17 in the biological coordinate system are calculated by correlating with the pre-recorded LED array. . Since the signal plate 17 on which the LEDs 18a, 18b, and 18c are integrally fixed is attached to a predetermined position of the mirror body 3, the position and orientation of the mirror body 3 with respect to the living body coordinate system are calculated by calculation at the workstation 29. The
[0040]
Further, the workstation 29 extracts a light emission pattern signal related to the focus distance value and the zoom magnification value from the light emission pattern signals of the LEDs 18a, 18b and 18c, and calculates the focus distance value and the zoom magnification value. Further, the relative position of the focal position 15 with respect to the mirror body 3 is calculated from the position information of the objective lens 11 recorded in advance on the workstation 29.
[0041]
Further, the focal position 15 in the biological coordinate system is calculated from the position and posture of the mirror 3 in the biological coordinate system and the relative position of the focal position 15 with respect to the mirror 3. On the monitor 43, the three-dimensional image data and the focal position 15 are superimposed and displayed on the biological coordinate system on the image.
[0042]
As described above, the focus position 15 is superimposed on the image based on the three-dimensional image data and displayed on the monitor 43 as shown in FIG. 5, so that the operator 44 can easily set the observation position of the microscope on the image based on the three-dimensional image data. Can be recognized.
A method related to three-dimensional position detection is disclosed in detail in the above-mentioned Japanese Patent Application Laid-Open No. 05-305073.
[0043]
(effect)
According to the present embodiment, since it is not necessary to provide a new transmission / reception member, the effect of the present embodiment can be obtained without particularly increasing the size of the signal plate in the surgical instrument and without impairing the original operability of the surgical instrument.
[0044]
In this embodiment, for example, by placing the focus distance value and the zoom magnification value on different signal members, data communication can be performed in a shorter time, and the time lag in communication can be reduced. In this case, depending on the position and posture that can be taken by the surgical device, the data is arranged so that different data is placed on the receiving member that must be imaged at least by position detection.
[0045]
(Second Embodiment)
(Constitution)
6 is an enlarged view of the body portion, FIG. 7 is an enlarged view of the signal plate portion, FIG. 8 is an enlarged view of the optical receiving device portion, and FIG. 9 is a functional block diagram of the surgery support system.
[0046]
Here, only different parts from the first embodiment will be described. As shown in FIG. 6, the signal plate 17 'has a support on a sphere, and the reflecting members 18a', 18b ', 18c' whose exterior is covered with a paint capable of reflecting infrared light as a signal member form a predetermined shape. And fixed together. Predetermined shapes formed by the reflecting members 18a ', 18b', 18c 'are recorded in advance on the workstation 29 as shape data.
[0047]
As a data transmission unit, an LED 23 which is an infrared light emitting member is integrally fixed to a central portion of the signal plate 17 ′. The LED 23 is connected to an LED control device 27.
[0048]
Further, as shown in FIG. 8, an infrared light irradiation device 28 for irradiating the optical receiving device 30 ′ with infrared light to be reflected by the reflecting members 18a ′, 18b ′, and 18c ′ includes an infrared semiconductor camera 31a. , 31b, and is provided integrally with the camera support member 32. Further, the infrared light irradiation device 28 is connected to an infrared light emitting device 36.
[0049]
Further, the infrared light receiving member 24 is provided integrally with the camera support member 32 so as to face an imaging space common to the infrared semiconductor cameras 31a and 31b. The infrared light receiving member 24 is connected to an infrared light receiving processing device 25, and the infrared light receiving processing device 25 is connected to a workstation 29.
[0050]
(Function)
As for the operation of the second embodiment, only the parts different from the first embodiment will be described. The infrared light emitting member 28 is turned on by the infrared light emitting device 36 to irradiate infrared light. Infrared light emitted from the infrared light emitting member 28 is reflected by the reflecting members 18a, 18b and 18c, and the reflected light is imaged by the infrared semiconductor cameras 31a and 31b, respectively, and transmitted to the workstation 29 as position data. The In the workstation 29, the correlation with the shape data recorded in advance is taken, the position and orientation of the signal plate 17 'in the biological coordinate system are calculated, and the position and orientation of the mirror 3 in the biological coordinate system are further calculated.
[0051]
Further, based on the signal converted by the data conversion unit 19 according to the focus distance value and zoom magnification value of the observation point 15, the LED control device 27 lights the LED 23 with a predetermined light emission pattern.
[0052]
Infrared light emitted from the LED 23 is received by the infrared light receiving member 24, converted into a focus distance value and a zoom magnification value according to the light emission pattern by the infrared light receiving processing device 25, and transmitted to the workstation 29. The In the workstation 29, the position and orientation of the mirror body 3 in the living body coordinate system, the focus distance value, and the zoom magnification value are superimposed on the three-dimensional image data on the monitor 43 as in the first embodiment, and are used for surgery. The position of the observation point 15 of the microscope 1 is displayed.
[0053]
(effect)
According to this embodiment, the communication function part in the existing surgery support system can be made to correspond to optical communication from a wired method, and the transmission / reception unit can be easily added to the position detection display device and the surgical instrument.
[0054]
In this embodiment, the reflecting member is used as the signal member. However, as shown in Japanese Patent Laid-Open No. 5-305073, a color marker may be used and a CCD camera may be used as the optical receiving member. When the color marker is used, in addition to the shape recognition by the arrangement of the signal member, it is possible to identify by color, so that more surgical instruments can be detected at the same time, and the same effect as in this embodiment can be obtained.
[0055]
(Third embodiment)
(Constitution)
FIG. 10 is an enlarged view of the mirror body part, FIG. 11 is an enlarged view of the optical receiver, FIG. 12 is a display image on the monitor, and FIG. 13 is a functional block diagram of the surgery support system.
[0056]
While the first embodiment is communication from the surgical instrument to the position detection display device, the present embodiment shows an example in which communication means from the position detection display device to the surgical instrument is added to the configuration of the first embodiment. .
[0057]
Only portions different from the first embodiment will be described below. A configuration in which an infrared light receiving member 26 is integrally fixed as a data receiving unit at the center of the signal plate 17 is referred to as a signal plate 17 ″ (FIG. 10). The infrared light receiving member 26 is an infrared light receiving processing device 40. The infrared light reception processing device 40 is connected to the data conversion unit 19.
[0058]
As shown in FIG. 11, the optical receiver 30 ″ is provided with an LED 28 as a data transmission unit with its light emitting unit facing the imaging range common to the infrared semiconductor cameras 31a and 31b. Connected to the device 24, the LED control device 24 is connected to a workstation 29.
[0059]
In the display image on the monitor 43 shown in FIG. 12, reference numeral 41 denotes an optical axis from the objective lens 11 to the observation point 15, and the optical axis 41 is extended from the observation point 15 in the opposite direction of the objective lens 11 by a certain length. This line is referred to as an optical axis auxiliary line 41 ′. Reference numeral 38 denotes a mouse pointer, and reference numeral 39 denotes a target 39 input by the mouse pointer 38.
[0060]
(Function)
In the present embodiment, a means for automatically setting the focus distance of the surgical microscope in particular based on an instruction from the position detection display device will be described. The current observation point 15 by the surgical microscope is superimposed on the three-dimensional image data from the position and posture of the mirror body 3 in the living body coordinate system, the focus distance value, and the zoom magnification value in the same manner as in the first embodiment. The position of the observation point is displayed.
[0061]
When the surgical staff (operator) 46 designates an arbitrary position on the optical axis 41 or the optical axis auxiliary line 41 ′ with the mouse pointer 38 on the monitor 43, the point is recorded on the workstation 29 as the target 39. Further, when the operator 46 operates a predetermined key of the workstation 29 (not shown), the workstation 29 calculates the distance in the living body coordinate system between the current observation point 15 and the target 39 and calculates it as a focus distance value at the target 39. . Further, the workstation 29 converts the focus distance value into a signal of a predetermined light emission pattern and outputs it to the LED control device 24. The LED control device 24 controls the lighting of the LED 28 based on the signal of the light emission pattern.
[0062]
In the surgical microscope 1, the infrared light receiving member 26 receives light emitted from the LED 28. The received light emission pattern is converted into a signal by the infrared light receiving processor 40 and transmitted to the data converter 19.
[0063]
The data converter 19 converts the light emission pattern into a focus distance value according to a predetermined format, and further converts it into a position information value for the position sensor 16. The position information value is transmitted to the microscope control unit 22. The microscope control unit 22 drives a focus drive motor (not shown) and stops the focus drive motor when it coincides with the position information value by feedback from the position sensor 16.
[0064]
As described above, the observation point 15 can be aligned with the position designated by the constructed three-dimensional image data on the monitor 43.
[0065]
(effect)
According to the present embodiment, in addition to the effects of the first embodiment, a new cable is provided for communication from the position detection display device to the surgical microscope when transmitting data from the position detection display device to the surgical microscope. There is no need. Therefore, the surgeon and the operation staff do not need to take time for preparation before the operation, which is effective in reducing fatigue.
[0066]
In the above embodiment, the optical system data is used as the data to be notified from the surgical microscope to the position detection display device. However, the operation signal of the surgical microscope may be notified in the same manner as the data. .
[0067]
Specifically, as shown in this embodiment, when the focal length of the surgical microscope is automatically moved based on the data from the position detection display device, a switch for that purpose is provided in the surgical microscope, and the operation of the switch is performed in the present embodiment. By performing the data communication according to the invention, the wiring for that is not necessary.
[0068]
In addition, the signal member is often arranged in a plurality of planes so that the possible positions and postures of the surgical instrument can be detected as much as possible. In such a case, by providing a plurality of data transmission / reception units attached to the surgical instrument, it is possible to reliably perform data communication with the position detection display device when position detection is possible.
[0069]
An example is briefly shown below. FIG. 14 is an enlarged view of the mirror body portion to which the signal plate is attached, and FIG. 15 is a functional block diagram of the surgery support system.
[0070]
The signal board 117 is composed of two planes 117a and 117b that form surfaces perpendicular to each other. LEDs 118a, 118b, 118c, and 118d are integrally fixed to the four corners of the plane 117a on the plane 117a, and are connected to the LED control device 27, respectively. An infrared light receiving member 26a is integrally fixed to the central portion of the plane 117a, and the infrared light receiving member 26a is connected to the infrared light receiving processing device 40.
[0071]
Similarly, LEDs 118e, 118f, 118g, and 118h are integrally fixed to the four corners of the plane 117b on the plane 117b, and are connected to the LED control device 27, respectively. An infrared light receiving member 26b is integrally fixed to a central portion of the plane 117b, and the infrared light receiving member 26b is connected to the infrared light receiving processing device 40. The signal plate 117 is integrally fixed at a predetermined position of the mirror body 3.
[0072]
(Function)
As in the first embodiment, the data transmission unit from the surgical microscope 1 to the optical receiver 30 ″ is performed by the LEDs 118a to 118h, and is received by the infrared semiconductor cameras 31a and 31b of the optical receiver 30 ″.
[0073]
Further, data reception from the optical receiver of the surgical microscope 1 is performed by both or one of the infrared light receiving members 26a and 26b by the same method as shown in the third embodiment.
[0074]
(effect)
According to the present embodiment, position detection based on the position and posture of the surgical instrument can be performed in a wider range than in the first embodiment, and the data transmission / reception unit is expanded as the detection range is expanded. Since the person can concentrate on the surgery without worrying about the position and posture of the surgical instrument, it is effective in shortening the operation time and reducing the operator's fatigue.
[0075]
(Fourth embodiment)
(Constitution)
FIG. 16 is a block diagram of the endoscope and signal board, FIG. 17 is a block diagram of the endoscope and signal board, and FIG. 18 is an overall view of the present embodiment. In the present embodiment, a case where a rigid endoscope is used as an endoscope will be described as an example based on the first embodiment.
[0076]
As shown in FIG. 16, an endoscope 50 as a rigid endoscope includes an insertion portion 51, a camera head 52, and an adapter 53 that connects the insertion portion 51 and the camera head 52.
[0077]
The insertion portion 51 includes an insertion portion distal end 51a provided with an objective lens (not shown) for capturing an image, and an adapter connection portion 51b for relaying a light beam captured from the objective lens to the camera head side.
[0078]
A cable 57 for connecting to a camera control unit 63 (described later) is attached to the camera head 52, and a CCD 59 (FIG. 17) is built therein. The CCD 59 is connected to the camera control unit 61 via the cable 57. The camera control unit 61 is connected to the control unit 58. Further, contacts 66 a, 66 b and 66 c for specifying the connected adapter 53 are provided at the fitting portion with the adapter 53. The contacts 66a, 66b, 66c are connected to the control unit 58, respectively.
[0079]
The adapter 53 is positioned at a fitting portion with the camera head 52 and is configured to be detachable. Further, contacts 67a, 67b, and 67c are provided at positions where they come into contact with the contacts 66a, 66b, and 66c, respectively, and are connected to contacts 68a, 68b, and 68c provided at a fitting portion with the insertion portion 51, respectively. .
[0080]
The insertion portion 51 is positioned at a fitting portion with the adapter 53 and is configured to be detachable. Further, contacts 69a, 69b, and 69c are provided at positions where they come into contact with the contacts 68a, 68b, and 68c, respectively, and the contacts 69a and 69b are connected.
[0081]
An imaging lens (not shown) is arranged in the imaging surface optical axis direction of the CCD 59 so as to form an image on the CCD 59 surface. Further, in the optical axis direction, a focusing optical system (not shown) for changing the focal length of an objective lens (not shown) attached to the insertion portion distal end 51a is sequentially arranged on the optical axis and rotates along the outer periphery of the camera head 52. The focal length can be varied by a possible focus knob 54. The focusing optical system is connected to a position sensor 60 for detecting the lens position in conjunction with the movement of the lens in the optical axis direction. The position sensor 60 is controlled in the camera control unit 63 via the cable 57. Connected to the unit 58. The control unit 58 is connected to the data conversion unit 62.
[0082]
The camera head 52 and the insertion portion 51 are detachably connected to each other by an adapter 53 configured to be able to relay the light beam taken into the insertion portion 51 to the camera head 52.
[0083]
The signal board 55 is integrally fixed with LEDs 56 a, 56 b, 56 c, and 56 d as infrared light emitting members, and the LEDs 56 a, 56 b, 56 c, and 56 d are each connected to an LED control device 64 in the camera control unit 63. The LED control device 64 is connected to the data conversion unit 62. The signal plate 55 is positioned at a predetermined position of the camera head 52 and is detachably fixed.
[0084]
(Function)
Here, only the newly added contents will be described based on the first embodiment. By attaching the insertion portion 51 to the adapter 53, the contact 69a and the contact 69b are connected and notified to the control portion 58. Based on the notification, the control unit 58 specifies the length of the attached insertion unit 51 and outputs it to the data conversion unit 62.
[0085]
In the workstation 29, information on the mounting position of the signal plate 55 with respect to the camera head 52, the relative position of the distal end portion 51a of the insertion portion 51, and the distal end portion of the insertion portion having a different length (not shown) are recorded.
[0086]
The position of the tip 51a is specified as follows in the same manner as in the case of the surgical microscope shown in the first embodiment.
[0087]
The position of the signal plate 55 is specified from the three-dimensional position of the LEDs 56a to 56d in the living body coordinate system, and further the position of the camera head 52 is specified. Further, the position of the distal end portion 51a in the biological coordinate system is calculated from the relative position between the predetermined attachment position of the signal plate 55 of the camera head 52 recorded in advance on the workstation 29 and the distal end portion 51a.
[0088]
When the observation position by the endoscope is indicated on the monitor 43, information on the focal length is required in the workstation 29, but the information on the focal length is notified to the workstation 29 as follows.
[0089]
First, the operator 44 operates the focus knob 54 to set the focal length to a desired value. A lens position of a focusing optical system (not shown) is read by the position sensor 60 as lens position information and transmitted to the data conversion unit 62 via the camera control unit 61. The data conversion unit 62 controls the lighting of the LEDs 56a to 56d with a predetermined light emission pattern similar to that of the first embodiment, according to the length information of the insertion unit and the lens position information value.
[0090]
The optical receiver 30 receives the light emission patterns of the LEDs 56 a to 56 d of the signal plate 55, and the signals are processed by the measuring device 20 and the A / D converter 33 and converted into corresponding focal length values by the workstation 29. From the position of the distal end portion 51a of the endoscope in the living body coordinate system, the lens position information value, and the length information of the connected insertion portion 51, the workstation 29 and the observation point of the insertion portion 51a. 42 can be calculated and shown on the monitor 43.
[0091]
Further, when the insertion portion is replaced with a different length, for example, the contact 69a and the contact 69c of the insertion portion 51 are connected, so that the attached insertion portion can be specified, and the workstation 29 is notified of the insertion portion. The positions of the mirror tip and the observation point are shown on the monitor 43.
[0092]
(effect)
The length of the insertion section is automatically detected along with the focal length of the endoscope and notified to the position detection device, so that position detection can be performed without any setting even if the insertion section is replaced with a different length during surgery. This can be done continuously.
[0093]
According to this embodiment, not only a surgical microscope but also a surgical instrument such as an endoscope can reliably notify information required for position detection (in this embodiment, the length of the insertion portion). It becomes.
[0094]
In recent years, combined surgery using a surgical microscope and an endoscope is increasing. When the number of surgical instruments that require position detection is increased in this way, the effect of the present invention becomes even greater.
[0095]
The invention having the following configuration is extracted from the specific embodiment described above.
[0096]
1. Surgical equipment,
A position detection display device that has an optical receiver and detects and displays at least the position of the surgical instrument;
A plurality of signal members attached to the surgical instrument and detected by the optical receiver;
Comprising
In order to perform optical communication between the position detection display device and the surgical instrument, a transmission / reception unit for the optical communication is within a range surrounded by the optical receiving device and the plurality of signal members or the plurality of signal members. A surgery support system, wherein a signal member is provided on a signal board integrally formed.
[0097]
2. Surgical equipment,
A position detection display device that has an optical receiver and detects and displays at least the position of the surgical instrument;
A plurality of signal members attached to the surgical instrument and detected by the optical receiver;
Comprising
In order to perform optical communication between the position detection display device and the surgical instrument, a receiving unit for the optical communication is provided in the optical receiving device, and the transmitting unit for the optical communication is provided with the plurality of signals. An operation support system, characterized in that it is provided within a range surrounded by members or a signal plate in which the plurality of signal members are integrally formed.
[0098]
3. The surgical operation support system according to Configuration 1 or 2, wherein at least one of the signal members also serves as a transmission unit of the surgical instrument.
[0099]
4). The surgery support system according to Configuration 1 or 2, wherein the position detection unit of the optical receiving device also serves as the receiving unit of the position detection display device.
[0100]
5). The surgical operation support system according to any one of configurations 1, 2, and 3, wherein the transmission unit of the surgical instrument includes an infrared light emitting member.
[0101]
6). The surgery support system according to Configuration 4, wherein the position detection unit of the optical receiver is an infrared semiconductor camera.
[0102]
7. The surgical operation support system according to Configuration 1 or 2, wherein the surgical instrument is a surgical microscope.
[0103]
8). The surgical operation support system according to Configuration 1 or 2, wherein the surgical instrument is a rigid endoscope.
[0104]
9. The surgery support system according to Configuration 1 or 2, wherein the signal member is arranged to constitute a plurality of surfaces, and a transmission / reception unit is provided on each of the plurality of surfaces.
[0105]
10. The surgery support system according to any one of configurations 1, 2, and 3, wherein a plurality of the transmission / reception units are provided, and the plurality of transmission / reception units transmit different data.
[0106]
【The invention's effect】
According to the present invention, when the position of the surgical instrument is detected, the wiring between the position detection display device and the surgical instrument can be eliminated, so that there is no need to worry about the feet when moving in the operating room.
[0107]
In addition, since data communication can be performed reliably in a state where the position of the surgical instrument can be detected regardless of the position and posture of the surgical instrument, the fatigue of the operator and the surgical staff can be reduced, and the limited space in the operating room can be effectively used. Useful.
[0108]
In addition, since the wiring during setup is reduced, the setup time can be shortened and the fatigue of the surgical staff can be reduced.
[Brief description of the drawings]
FIG. 1 is a diagram showing a schematic configuration of an entire surgical microscope.
FIG. 2 is an enlarged view of a mirror part of the first embodiment.
FIG. 3 is a diagram illustrating an internal configuration of a mirror unit.
FIG. 4 is a functional block diagram of the surgery support system.
FIG. 5 is a diagram illustrating an example of an image displayed on a monitor of a workstation.
FIG. 6 is an enlarged view of a mirror part of the second embodiment.
FIG. 7 is an enlarged view of a signal plate portion.
FIG. 8 is an enlarged view of an optical receiving device portion.
FIG. 9 is a functional block diagram of the surgery support system.
FIG. 10 is an enlarged view of a mirror part of the third embodiment.
FIG. 11 is an enlarged view of the optical receiver.
FIG. 12 is a diagram illustrating an example of a display image on a monitor.
FIG. 13 is a functional block diagram of the surgery support system.
FIG. 14 is an enlarged view of a mirror body portion to which a signal plate is attached.
FIG. 15 is a functional block diagram of the surgery support system.
FIG. 16 is a configuration diagram of an endoscope and a signal plate according to a fourth embodiment.
FIG. 17 is a block diagram of an endoscope and a signal board.
FIG. 18 is an overall view of a fourth embodiment.
[Explanation of symbols]
1 ... surgical microscope,
2 ... Position detection display device,
3 ... Mirror body,
4 ... Base,
5 ... posts
6 ... first arm,
7 ... second arm,
8 ... Third arm,
9 ... Grip,
10 ... switch,
11 ... objective lens,
12 ... Variable magnification optical system,
13a, 13b ... imaging lens,
14a, 14b ... eyepieces,
15 ... Focus position,
16: Position sensor (for objective lens),
17 ... Signal board,
18a, 18b, 18c ... signal members,
19: Data conversion unit,
20 ... measuring device,
21 ... Position sensor (for variable magnification optical system),
22 ... Microscope control unit,
27 ... LED control device,
29 ... Workstation,
30: Optical receiver,
31a, 31b ... Infrared semiconductor camera,
32. Camera support member,
33 ... A / D converter,
34 ... Stand,
35a, 35b, 35c ... mark members,
37 ... Patient,
43 ... Monitor,
44 ... Surgeon,
45 ...
46 ... Surgery staff,
17 '... signal board,
18a ', 18b', 18c '... reflective member,
23 ... LED,
25. Infrared light receiving processing device,
28. Infrared light irradiation device,
30 '... optical receiver,
36. Infrared light emitting device,
17 "... Signal board,
24 …… LED control device,
26a ... Infrared light receiving member,
26b ... Infrared light receiving member (2),
28 ... LED,
30 "... optical receiver,
40. Infrared light receiving and processing device,
50 ... Endoscope,
51 ... Insertion part,
51a ... tip of the insertion part,
51b ... adapter connection part,
52 ... Camera head,
53 ... Adapter,
54 ... Focus knob,
55 ... Signal board,
56a, 56b, 56c, 56d ... LED,
57 ... Cable,
59 ... CCD,
60: Position sensor,
61 ... Camera control unit,
62 ... Data conversion unit,
63 ... Camera control unit,
64 ... LED control device,
65 ... detection part,
66a, 66b, 66c ... contact points.

Claims (6)

Surgical equipment,
A plurality of signal members attached to the surgical instrument;
A position detection unit that includes an optical receiving device that detects at least positions of the plurality of signal members, and that detects and displays at least the position of the surgical instrument based on the position of the signal member detected by the optical receiving device. A display device;
Comprising
In order to perform optical communication between the position detection display device and the surgical instrument, a transmission / reception unit for the optical communication is within a range surrounded by the optical receiving device and the plurality of signal members or the plurality of signal members. The signal member is provided on the signal plate integrally formed,
Based on data communicated between the position detection display device and the surgical instrument, the transmission unit of the transmission / reception unit is controlled to be lit with a predetermined light emission pattern,
The operation support system according to claim 1 , wherein the reception unit of the transmission / reception unit detects and processes a light emission pattern signal from the transmission unit . Surgical equipment,
A plurality of signal members attached to the surgical instrument;
A position detection display that includes an optical receiving device that detects at least the positions of the plurality of signal members, and detects and displays at least the position of the surgical instrument based on the positions of the signal members detected by the optical receiving device. Equipment,
Comprising
In order to perform optical communication between the position detection display device and the surgical instrument, a receiving unit for the optical communication is provided in the optical receiving device, and the transmitting unit for the optical communication is provided with the plurality of signals. Provided in the signal board in which the plurality of signal members are integrally formed within a range surrounded by the members,
The transmission unit is controlled to be lit with a predetermined light emission pattern based on data communicated between the position detection display device and the surgical instrument,
The operation support system , wherein the reception unit detects and processes a light emission pattern signal from the transmission unit .   The surgery support system according to claim 1 or 2, wherein at least one of the signal members also serves as a transmission unit of the surgical instrument.   The surgical operation support system according to claim 1 or 2, wherein a position detection unit of the optical receiving device also serves as a receiving unit of the position detection display device. The data communicated between the position detection display device and the surgical instrument includes a focus distance value, a zoom magnification value of the surgical instrument, and an automatic focal length adjustment command to the surgical instrument. The surgical operation support system according to 1. The operation support system according to claim 2, wherein data communicated between the position detection display device and the surgical instrument includes a focus distance value and a zoom magnification value of the surgical instrument.

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