JP2007244679A - Endoscope - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To start a perfusion operation of the bladder automatically when an endoscope is switched from a normal observation mode to NBI (narrow band imaging) mode and to secure a sufficient visual field by carrying out perfusion operation effectively. <P>SOLUTION: An endoscope apparatus 1 is provided which comprises a light source unit 3 which carries out selectively illumination for visual band observation and illumination for narrow band observation, an endoscope 2 which photographs a subject using illumination from the light source unit 3 by means of a photographing unit 20 of the endoscope 2 and acquires a visual band observation image or a narrow band observation image, a CCU (camera control unit) 4, a monitor 5, a water pump 6 for sending perfusion liquid to the bladder through a water conduit 16 of the endoscope 2, a suction device 8 for sucking the perfusion liquid, body liquid or urine from the bladder through a suction conduit 17 of the endoscope 2, and a control unit 60 which controls actuation of either the water pump 6 or the suction device 8 when an observation image is switched from a visible band observation image to a narrow band observation image. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an endoscope apparatus capable of observing the inside of a bladder by switching between a visible light band observation mode (normal observation mode) and a narrow band observation mode.

  Conventionally, endoscopes have been widely used in the medical field and the like. An endoscope, for example, observes an organ or the like in a body cavity by inserting an elongated insertion portion into the body cavity, or performs various treatments using a treatment instrument inserted into a treatment instrument insertion channel as necessary. be able to. In addition, the endoscope ejects gas or washing liquid toward the outer surface (observation window) of the observation optical system using an air / water supply channel as necessary, or uses a suction channel to enter a body cavity. The field of view of the observation optical system is secured by aspirating the liquid.

  An endoscope apparatus having such an endoscope can perform observation in a visible light band observation mode (hereinafter referred to as a normal observation mode) in which normal observation in the visible light band is performed, and also has a spectral characteristic of observation light. Some of them can be observed in a narrow band observation (NBI: Narrow Band Imaging, also referred to as NBI observation) mode that can improve the observation function by adjusting.

In the NBI observation mode, the observation function is improved by adjusting the spectral transmittance characteristics of the three RGB optical filter portions used in the field sequential illumination method in the normal observation mode. In other words, the B filter of the optical filter section uses the hemoglobin absorption maximum as the center wavelength (415 nm) and narrows the half-value width to about 30 nm so as to cut light on the longer wavelength side. By narrowing the band, the depth of light can be limited to the surface layer in the B channel image. Thereby, the contrast of the surface fine structure in the body cavity is improved, and for example, fine patterns such as capillaries can be clarified.
Since such an NBI observation mode can clarify fine patterns such as capillaries, it may be used for examination and treatment in the bladder.

  In general, in the inspection and treatment of the urinary bladder by an endoscope, recirculation is necessary for securing a visual field. In the conventional endoscope apparatus, the circulating fluid is fed into the bladder via the air / water feeding channel in the endoscope, and the sewage after the treatment and the treatment is sucked in the endoscope. It discharges to the outside through the channel.

An example of this type of conventional endoscope apparatus is disclosed in Patent Document 1. In this Patent Document 1, water supply means for feeding recirculation water into a body cavity via a water supply path provided in an endoscope main body, and discharge means for discharging recirculation water through a drainage path provided in the endoscope main body. And a detection means for detecting the pressure in the body cavity when injecting and discharging the circulating water, and further, based on the detection result of the body cavity pressure by the detection means by the water supply means and the control means for controlling the discharge means Thus, there is disclosed a technique related to an endoscope apparatus in which the amount of circulated water is adjusted and the amount of drainage is adjusted so that sewage does not collect near the endoscope tip and the inside of the visual field is kept clean.
Japanese Laid-Open Patent Publication No. 10-276980

  However, in the conventional technique, when observing the inside of the bladder in the NBI observation mode, for example, when hematuria is accumulated in the bladder, even if the light amount by the light source device is set to the maximum light amount, There is a problem that the image cannot be sufficiently secured, and the NBI observation image becomes dark, and as a result, the observation in the bladder cannot be performed satisfactorily.

  In addition, the conventional technique of Patent Document 1 is an endoscope apparatus that observes the inside of the bladder in the normal observation mode, not the inside of the bladder in the NBI observation mode. There is no mention of any means for doing this.

  Furthermore, the prior art of Patent Document 1 controls to keep the inside of the visual field clean so that sewage does not collect in the vicinity of the distal end portion of the endoscope in the bladder by the circulation operation by the water supply means and the discharge means. However, since the observation lens of the observation optical system, the water supply for circulation, and the discharge opening are arranged on the same plane at the distal end surface of the endoscope distal end, the hematuria in the bladder is sucked for discharge As a result, they gather in the field of view of the endoscope tip. For this reason, there exists a problem that recirculation | perfusion operation | movements, such as hematuria in a bladder, cannot be performed effectively.

  Therefore, the present invention has been made in view of the above circumstances, and can automatically start the perfusion operation in the bladder when the normal observation mode is switched to the NBI observation mode, and the perfusion operation can be effectively performed. Another object of the present invention is to provide an endoscope apparatus that can secure a sufficient visual field.

  The endoscope apparatus according to the present invention is an endoscope apparatus that can recirculate a circulating liquid into a body cavity, and selectively performs illumination for visible light band observation and illumination for narrow band observation. And an observation means for obtaining a visible light band observation image or a narrow band observation image by imaging a subject with an optical imaging means provided in an endoscope using illumination by the illumination means, Water supply means for sending a reflux liquid into the body cavity through a water supply pipe provided in the mirror body, and the reflux liquid and body fluid or excrement from the body cavity through a suction pipe provided in the endoscope body And when the observation image obtained by the observation means is switched from the visible light band observation image to the narrow band observation image, at least one of the water supply means and the suction means is started. Control hand to control And, the has.

  According to the endoscope apparatus of the present invention, when the normal observation mode is switched to the NBI observation mode, the perfusion operation in the bladder can be automatically started, and the perfusion operation can be effectively performed to obtain a sufficient visual field. There is an advantage that can be secured.

  Embodiments of the present invention will be described below with reference to the drawings.

Example 1
1 to 8 show a first embodiment of an endoscope apparatus according to the present invention, FIG. 1 is a block diagram showing a configuration of the entire system of the endoscope apparatus, and FIG. 2 is a diagram of a distal end portion of the endoscope of FIG. FIG. 3 is a block diagram showing a schematic configuration of the CCU of FIG. 1 and the light source device, and FIGS. 4 to 8 are for explaining the operation of the endoscope device. FIG. FIG. 5 is an explanatory view showing an insertion state of the endoscope insertion portion when the endoscope insertion portion is inserted transurethrally to perform an inspection inside the bladder, and FIG. 6 is an NBI observation mode. FIG. 7 is a diagram showing a state in the bladder immediately after the start of the perfusion operation in response to the switching, and FIG. 7 is a diagram showing a state in which the visual field is gradually secured by sucking hematuria and the like at the same time as the infusion fluid is injected. FIG. 8 is a diagram showing a state where the circulation operation is completed and the field of view near the distal end of the endoscope is well secured. It is shows.

As shown in FIG. 1, an endoscope apparatus 1 according to the present invention includes an endoscope 2 having an imaging unit in a distal end portion 10 constituting an endoscope insertion portion (hereinafter referred to as an insertion portion) 9. The light source device 3 that is detachably connected to the endoscope 2 and supplies illumination light to the light guide fiber 3a provided in the endoscope 2, and the endoscope 2 is detachably connected to the endoscope 2. The CCU (Camera Control Unit) 4 that controls the image pickup means and processes the image signal obtained from the image pickup means into a video signal, and the video signal processed by the CCU 4 is output to display an endoscopic image A monitor 5, a water feed pump 6 for feeding the circulating fluid into the body cavity via an air / water channel 16a provided in the endoscope body, a tank 7 for storing the circulating fluid, A suction channel 17a provided in the endoscope body To have fluid in the body cavity, and a suction device 8 for sucking and discharging a ring diverted solution, the.
The endoscope 2 and the CCU 4 constitute observation means, the water supply pump 6 constitutes water supply means, and the suction device 8 constitutes suction means. Further, the light source device 3 constitutes illumination means, and the CCU 4 constitutes control means.

  As the endoscope 2, an endoscope for urology, for example, a bladder is used. The endoscope 2 includes an elongated insertion portion 9, an operation portion 12 connected to the proximal end side of the insertion portion 9, and a signal cable extending from a side portion of the operation portion 12 and connected to an imaging unit. 42 and a universal cord 14 having a built-in light guide fiber 3a for transmitting illumination light from the light source device 3, and a connection portion provided at an end of the universal cord 14 and detachable from the light source device 3 and the CCU 4. And a connector portion (not shown). The endoscope 2 may be a rigid endoscope.

  The insertion portion 9 includes a rigid distal end portion 10 formed at the distal end and an elongated insertion portion main body 11 formed from the proximal end portion of the distal end portion 10 to the operation portion 12. In the endoscope 2, a bendable bending portion may be formed at the proximal end portion of the distal end portion 10.

  A light guide fiber 3 a that transmits illumination light is inserted into the insertion portion 9. The light guide fiber 3a is inserted into the universal cord 14 via the operation unit 12, and a base end portion is connected to a light guide connector (not shown) protruding from a connector portion (not shown).

  Further, the distal end portion of the light guide fiber 3 a is fixed in the distal end portion 10. Note that an illumination window (not shown) of an illumination unit that is an illumination optical system is disposed at the distal end portion of the distal end portion 10, and illumination light is emitted from the light guide fiber 3a via the illumination window (not shown). Is done. A tip cover 21 is provided on the tip surface of the tip portion 10.

  Although not shown, the light guide fiber 3a is branched in the operation unit 12, for example, and is divided into two at the insertion unit 9 and inserted. And the front end surface of each light guide fiber 3a divided | segmented into 2 is each arrange | positioned in the back surface vicinity of two illumination windows (not shown) provided in the front end cover 21. As shown in FIG.

  In addition, in the insertion portion 9, for example, an air / water supply channel 16 a that is a water supply pipe 16 for supplying the circulating liquid is provided. The front end of the air / water supply channel 16 a forms a water supply opening 18 that opens at the front end surface of the front end cover 21. In addition, an air / water supply nozzle (not shown) is provided in the vicinity of the water supply opening 18, and this air / water supply nozzle is provided on the outer surface (observation window) of the observation optical system, which will be described later, by a water supply operation during the circulation operation. The liquid for recirculation is ejected toward the tip lens 32 that forms the head.

Further, the air / water supply channel 16 a is inserted through the insertion portion 9 to a water supply connector portion (not shown) disposed in the operation portion 12. The water supply connector 16 (not shown) is connected to a water supply tube 16b that forms the water supply line 16. A proximal end portion of the water supply tube 16 b is connected to the water supply pump 6. As a result, the air / water supply channel 16a can supply the circulating liquid in the tank 7 into the body cavity (for example, in the bladder) through the water supply opening 18 by driving the water supply pump 6. Yes. The air / water supply channel 16 a and the water supply tube 16 b constitute a water supply pipe line 16.
In the present embodiment, the air / water supply channel 16a is used as a ring flow action, but is not limited to this, and is used for air supply for supplying conventional gas, or an operation unit. 12, a treatment instrument insertion port communicating with the air / water supply channel 16a may be provided and used as a treatment instrument channel for performing treatment by inserting a treatment instrument or the like through the treatment instrument insertion port.

  Further, in the insertion portion 9, a suction channel 17a, which is a suction conduit 17 for sucking excrement such as urine in a body cavity (for example, in the bladder) or body fluid and fluid for circulation, is provided. The tip of the suction channel 17 a forms a suction opening 19 provided on the side surface of the tip 10. The suction opening 19 is not provided on the same front end surface as the water supply opening 18 but is provided on the side surface of the front end 10 so as to be arranged on a surface orthogonal to the surface of the water supply opening 18. It has been. The specific configuration of the tip 10 having the water supply opening 18 and the suction opening 19 will be described later.

  Further, the suction channel 17 a is inserted through the insertion portion 9 to a suction connector portion (not shown) disposed in the operation portion 12. A suction tube 17b that forms a suction conduit 17 is connected to the suction connector portion (not shown). The proximal end portion of the suction tube 17b is connected to the suction device 8. As a result, the suction channel 17a sucks excretion such as urine in the body cavity (for example, in the bladder), a substance or body fluid, and the circulating fluid through the suction opening 19 by suction by driving the suction device 8. Can be discharged to the outside. The suction tube 17a and the suction tube 17b constitute a suction pipe line 17.

  An imaging unit 20 constituting an observation optical system of the endoscope 2 is disposed inside the distal end portion 10. The imaging unit 20 constitutes an imaging unit, and the configuration will be described later.

  On the proximal side of the operation unit 12 of the endoscope 2, a mode switching button 13 for switching between a normal light observation mode and an NBI observation mode, which will be described later, for example, an endoscope image is recorded in a recording unit (not shown). And an operation button 13a is provided. When the insertion portion 9 is provided with a bending portion, a bending operation knob for bending the bending portion is provided. Further, the operation button 13a may be assigned a function for zooming operation for performing a zooming operation in the imaging unit 20.

  In this embodiment, the mode switching button 13 generates a mode switching signal for performing observation in one of the normal observation mode and the NB1 observation mode by performing a switch operation. The signal is output to the CCU 4 via a signal line that is not.

Based on the supplied operation signal, the CCU 4 controls the imaging unit 20 that is an imaging unit of the endoscope 2 and processes an image signal obtained from the imaging unit into a video signal.
Further, when the mode switching signal is supplied, the CCU 4 controls the light source device 3 so that illumination light necessary for executing the observation mode based on the mode switching signal is emitted. At the same time, when the NBI observation mode is executed, the CCU 4 controls the water pump 6 and the suction device 8 to start driving. That is, the CCU 4 starts driving the water supply pump 6 and the suction device 8, thereby injecting the circulating fluid into the body cavity (for example, the bladder) through the water supply opening 18 (for example, the bladder) A recirculation operation is performed in which excreta such as urine and hematuria, body fluid, and recirculation fluid are aspirated through the suction opening 19.

  The CCU 4 is electrically connected to the light source device 3 through the signal line 4a, and can control the light source device 3 through communication with a light source control unit 50 of the light source device 3 described later. Further, the CCU 4 is electrically connected to the water pump 6 and the suction device 8 via the signal line 15, and can control the drive of the water pump 6 and the suction device 8.

Further, the CCU 4 is electrically connected to an imaging unit 20 described later via a signal cable 42 in the universal cord 14.
The monitor 5 outputs an image signal processed by the CCU 4 and displays an endoscopic image.

  The drive of the water pump 6 is controlled by the CCU 4. When the water pump 6 starts to be driven, the circulating fluid stored in the tank 7 is fed into the body cavity (for example, in the bladder) through the water pipe 16 and the water opening 18. The tank 7 is connected to the water pump 6 through a connecting tube 7a. The tank 7 stores a circulating liquid such as normal saline.

  The driving of the suction device 8 is controlled by the CCU 4. When the suction device 8 starts driving, the urine in the body cavity (for example, in the bladder), excrement such as hematuria, body fluid, and fluid for circulation are sucked through the suction conduit 17 and the suction opening 19. , Discharge to the outside. The suction device 8 is connected to a discharge tank (not shown) for storing discharged excrement, body fluid, and circulating fluid.

Next, the configuration of the distal end portion 10 of the endoscope 2 that has been improved to effectively perform the reflux operation will be described with reference to FIG.
As shown in FIG. 2, the distal end cover 21 disposed in the distal end portion 10 includes an observation window 32 that is an optical system member of the imaging unit 20, two illumination windows (not shown), an air / water supply nozzle, and a water supply And an opening 18 for operation.

  The distal end cover 21 of the distal end portion 10 is provided with a cylindrical member 22 formed of a hard conductive material, for example, metal, and formed with a plurality of, for example, five holes (not shown) in this embodiment. It is installed. An annular reinforcing ring 25 and an exterior member 24 are fixed to the base end side of the cylindrical member 22.

  The exterior member 24 disposed on the outer periphery of the cylindrical member 22 and the reinforcing ring 25 is covered with an outer cover 23 so as to cover the outer periphery thereof. The outer skin 23 is coated so as to be integrated over the entire length of the insertion portion 9 including the distal end portion 10 and the insertion portion main body 11 via the proximal end side of the distal end cover 21.

  For example, one of the five holes formed in the cylindrical member 22 in the distal end portion 10 forms the water supply opening 18, and the remaining four holes include the imaging unit 20, illustrated. Two lighting units that are not used and an air supply / water supply nozzle are respectively arranged.

  In this case, an illumination unit (not shown) is fitted into two of the five holes from the distal end side, and a distal end portion of a light guide fiber (not shown) is fitted to the proximal end portion of the illumination unit. Has been. Two illumination units (not shown) are the forefront of each illumination lens and each have an illumination lens that constitutes an illumination window.

  In addition, a first lens frame 26 for fixing a front end lens (corresponding to an observation window) 32 of the imaging unit 20 from the front end side is fitted in one of the five holes, and this front end is fitted. The lens 26 is disposed so as to be exposed on the front end surface.

  The imaging unit 20 includes a lens unit 20 </ b> A, an imaging element 38 such as a CCD (Chage Coupled Device) or a CMOS (Complementary Metal-Oxide Semiconductor), and a circuit board 39.

As shown in FIG. 2, the lens unit 20 </ b> A includes first to fourth lens groups 33 to 36 and first to fourth lens frames 26 to 29.
A first lens group 33 including four objective lenses including a front lens (corresponding to an observation window) 32 is held by the first lens frame 26, and a second lens 34 including one objective lens is used as the second lens frame 27. Is held in. A third lens group 35 composed of two objective lenses is held by the third lens frame 28, and a fourth lens group 36 composed of three objective lenses is held by the fourth lens frame 29. The second lens frame 27 that holds the second lens 34 is a moving lens frame that constitutes a moving member that can move forward and backward with respect to the photographing optical axis direction for zooming.

  The image pickup element 38 is provided with a cover lens 37 arranged in parallel on the base end side of the objective lens at the most base end of the fourth lens frame 29 on the light receiving surface side, and outputs an electric signal corresponding to the optical image to the circuit board 39. To do. The circuit board 39 has electrical components and wiring patterns, photoelectrically converts an optical image from the image sensor 38 into an electrical image signal, and outputs the image signal to the signal cable 42. The circuit board 39 is connected to a plurality of signal lines 42a of the signal cable 42 by means such as soldering.

  The outer peripheral portions of the cover lens 37, the image sensor 38, the circuit board 39, and the signal cable 42 are integrally covered with adhesive portions 40, 41 such as insulating sealing resin, and the reinforcing annular portion 30 is provided. And an insulating tube 31. The insulating tube 31 includes a fourth lens frame 29 and a reinforcing annular portion over the entire length of the connecting tube through which the signal cable 42 is inserted from the proximal end side of the first lens frame 26 at the distal end of the imaging unit 20. 30 etc. are covered.

  Further, the signal cable 42 transmits an image signal acquired by the imaging element 38 and the circuit board 39 of the imaging unit 20 to a signal processing circuit (see FIG. 3) in the CCU 4 via a connector unit (not shown).

  In this embodiment, the suction opening 19 of the distal end portion 10 is not on the same distal end surface as the water supply opening 18 in order to effectively perform the circulation operation in the body cavity (for example, in the bladder), It is provided in the side part of the front-end | tip part 10 so that it may distribute on the surface orthogonal to the surface of the opening part 18 for water supply.

  That is, the annular connecting member 46 is fixed to the proximal end portion of the reinforcing ring 25 of the distal end portion 10 so as to form the suction opening 19. The connection member 46 is formed in an arc shape, and the base end portion is arranged in a direction along with the air / water supply channel 16a. A suction tube 47 that forms a suction channel 17 a is connected to the base end portion of the connection member 46.

  An annular connecting member 43 is fixed to the proximal end portion of the columnar member 22 that forms the water supply opening 18. The connection member 43 is formed in a bent shape so as not to contact the connection member 46, for example, and a water supply tube 45 forming an air / water supply channel 16a is connected to the base end portion. . In the insertion portion 9, the water supply tube 45 and the suction tube 47 are inserted in parallel.

  With such a configuration, since the water supply opening 18 is provided in the vicinity of the observation window 32 on the distal end surface of the distal end portion 10, the visual field of the observation window 32 can be ensured by water supply of the circulating liquid. Further, since the suction opening 19 is provided on the side surface of the distal end portion 10, for example, when hematuria is accumulated in the bladder, the hematuria is sucked from the side surface direction of the distal end portion 10. It is possible to prevent hematuria from collecting near the window 32.

  Thus, the perfusion operation can be performed effectively, so that the visual field in the bladder can be kept good, and as a result, a good NBI observation image can be obtained even when the NBI observation mode is executed. ing.

Next, specific configurations and operations of the light source device 3 and the CCU 4 will be described with reference to FIG.
As shown in FIG. 3, the light source device 3 generates illumination light necessary to execute the normal observation mode or the NBI observation mode, and transmits the generated illumination light through the light guide fiber 3a. The illumination light transmitted by the light guide fiber 3a is emitted from two illumination windows (not shown) provided on the distal end side of the distal end portion 10, and is in the body cavity (for example, in the bladder) on the examination target tissue side. Is supposed to illuminate.

  Specifically, for example, as shown in FIG. 3, the light source device 3 switches the light from the light source control unit 50, the light source unit 51 that emits light, and the light from the light source unit 51 to the normal observation mode or the NBI observation mode. Based on the filter section 52 of the optical system that converts to suitable illumination light, the trap filter driving section 53 that drives the filter section 52, and the driving state of the filter driving section 53, the observation mode that is being executed is usually And a determination unit 54 that determines whether the mode is the observation mode or the NBI observation mode.

  The light source control unit 50 is electrically connected to the control unit 60 of the CCU 4 described later via the communication cable 4a, and can communicate with the control unit 60 of the CCU 4. The light source control unit 50 controls the entire light source device 3 based on a control signal from the control unit 60. The light source control unit 50 supplies the determination result of the determination unit 54 to the control unit 60 of the CCU 4 by communication.

The filter unit 52 generates illumination light necessary for executing the normal observation mode or the NBI observation mode, and transmits the generated illumination light through the light guide fiber 3a.
Specifically, the filter unit 52 is not illustrated, but in the normal observation mode, the light from the light source unit 51 is converted into RGB light through the three RGB first optical filter units used in the field sequential illumination method. Convert and emit. In the NBI observation mode, the filter unit 52 includes a second optical filter unit (not shown) that performs band limitation for blocking (cutting) light in the emission wavelength band of the B filter of the first optical filter unit. The light from the light source unit 51 is converted into RGB light with a narrow band and emitted.

  In this case, the RGB three first optical filter units (not shown) and the second optical filter unit of the filter unit 52 are controlled in the normal observation mode or the NBI observation mode by controlling the drive of the filter drive unit 53. The illumination light for use is generated and emitted.

  Based on a control signal from the light source control unit 50, the filter drive unit 53 rotates and drives first and second optical filter units (not shown) of the filter unit 52. At the same time, the filter drive unit 53 always supplies the drive state of the filter unit 52 to the determination unit 54.

  The detection of the driving state of the filter unit 52 by the filter driving unit 53 is performed by the rotation state of the first optical filter unit that is driven in the normal observation mode and the first and second optical units that are driven in the NIB observation mode. This is possible by using, for example, a pulse signal indicating the respective states of the filter rotation state.

  Accordingly, the determination unit 54 determines whether the observation mode currently being executed is the normal observation mode or the NBI observation mode based on the driving state of the filter unit 52 from the filter driving unit 53, for example, a pulse signal. And the determination result is output to the light source control unit 50. And the light source control part 50 outputs the determination result from the determination part 54 to the control part 60 of CCU4 by communication.

  That is, by providing the filter driving unit 53 and the determination unit 54 in the light source device 3, it is automatically performed regardless of the switch operation by the mode switching button 13 provided in the operation unit 12 of the endoscope 2. The observation mode being executed by the mirror 2 can be detected. For this reason, the control unit 60 of the CCU 4 can detect that the normal observation mode has been switched to the NBI observation mode.

Next, a specific configuration of the CCU 4 will be described with reference to FIG.
As shown in FIG. 3, the imaging device 38 of the endoscope 2 is connected to a CCD driving unit 61 and a preamplifier 62 in the CCU 4 through a signal cable 42. The drive of the CCD drive unit 61 is controlled by the control unit 60 described later according to the characteristics of the image sensor 38 incorporated in the endoscope 2.

  The image sensor 38 outputs a signal photoelectrically converted to the preamplifier 62 by a CCD drive signal supplied from the CCD drive unit 61 in the CCU 4. The signal amplified by the preamplifier 62 is input to the AGC circuit 63 and also input to the dimming unit 64.

The signal amplified by the AGC circuit 63 is converted into a digital signal (image data) by the A / D converter 65, and then a plurality of memories (for example, normal observation memory) in the memory unit 67 through the multiplexer 66. , And NBI observation memory).
In this case, the image data is temporarily stored in, for example, the normal observation memory and the NBI observation memory or a part of the memory under the control of the control unit 60 corresponding to the observation mode.

  Further, the image data temporarily stored in each of the normal observation memory and the NBI observation memory of the memory unit 67 or a part thereof is subjected to processing such as color conversion by the image processing unit 68, and It is output to the A converter 69. The D / A converter 69 converts the input digital image data into an analog image signal (video signal), and then outputs the analog image signal (video signal) to the monitor 5. A mirror image is displayed.

  The dimming unit 64 integrates the signal input from the preamplifier 62 at a predetermined period to generate a dimming signal in which the average of one frame corresponds to the brightness, and the dimming signal has an appropriate brightness. And the difference signal is output to the light source controller 50 as a dimming signal. The light source control unit 50 controls the light emission amount of the light source unit 51 so that the dimming signal matches the reference level.

  The operation of the CCD drive unit 61, AGC circuit 63, multiplexer 66, memory unit 67, and image processing unit 68 is controlled by the control unit 60.

The image processing unit 68 performs normal image processing such as γ correction and contour enhancement in the normal observation mode (also referred to as RGB mode). In contrast, in the NBI observation mode, the image processing unit 68 performs color conversion processing in addition to normal image processing such as γ correction and edge enhancement in the RGB mode.
For example, in the NBI observation mode, an NBI observation memory (not shown) in the memory unit 67 is used, and G and B1 image data captured by illumination light based on the NBI observation mode is written. These image data are simultaneously read out, and G, B, B1 image data are input to the RGB channels in the image processing unit 68. By doing in this way, the image obtained by NBI observation mode can be color-converted from a color image as it is, and can be displayed with a color image with better visibility.

  When the mode switching signal is supplied from the mode switching button 13 of the operation unit 12, the control unit 60 emits light so that illumination light necessary for executing the observation mode based on the mode switching signal is emitted. The apparatus 3 is controlled.

  In this case, when the mode switching signal is a signal indicating that the mode switching signal is switched from the normal observation mode to the NBI observation mode, or when the determination signal from the light source control unit 50 of the light source device 3 is the NBI observation mode. Is controlled to start driving the water pump 6 and the suction device 8.

  That is, the control unit 60 starts driving the water supply pump 6 and the suction device 8, thereby injecting the circulating fluid into the body cavity (for example, the bladder) through the water supply opening 18 (in the body cavity ( For example, a circulatory operation is performed in which excreta such as urine in the bladder, hematuria, body fluid, and circulating fluid are sucked through the suction opening 19.

In this embodiment, as a means for determining that the mode has been switched from the normal observation mode to the NBI observation mode, as described above, the mode switching signal from the mode switching button 13 or the determination unit 54 of the light source device 3 is used. Although it determined by the control part 60 based on the determination result, it is not limited to this.
For example, using the dimming level signal from the dimming unit 64 that performs dimming according to the observation mode, or the amplification factor from the AGC circuit 63 that adjusts the amplification of the video signal with the amplification factor according to the observation mode, You may make it determine with the determination process of the control part 60 having switched to NBI observation mode from normal observation mode. The determination may be made based on the processing contents of the memory unit 67 and the image processing unit 68.

  Note that, as described above, the method using the determination result from the determination unit 54 of the light source device 3 performs the determination based on the driving state of the filter driving unit 53 that drives the filter unit 52, and thus has switched to the NBI observation mode. This is a desirable method for reliably determining and detecting with high accuracy.

  Further, in this embodiment, when driving the reflux operation, the NBI observation mode is executed by the control unit 60 based on the mode switching signal from the mode switching button 13 or the determination result from the determination unit 54 of the light source device 3. However, in the NBI observation mode or in the normal observation mode, when the surgeon determines that the visual field has deteriorated while looking at the endoscopic image of the monitor 5, the reflux operation is driven. May be. In this case, it is necessary to assign a switch function for giving a surgeon's instruction for executing the circulation operation to the operation button 13a.

Next, the operation of the present embodiment will be described with reference to FIGS.
As shown in FIGS. 1 and 3, after the endoscope 2 is connected to the CC 4 and the light source device 3 and further connected to the water supply pump 6 and the suction device 8, the power supply of the endoscope device 1 (not shown) Is input.

  Then, the control part 60 of CCU4 reads the bladder observation start program shown, for example in FIG. 4 from the memory which is not illustrated, and starts it. That is, in step S1, the controller 60 inserts the insertion portion 9 through the urethra 70 and inserts the distal end portion 10 so as to reach the bladder 71 in step S1. The light source device 3 and the like are controlled so that observation can be performed in the normal observation mode.

  In the initial state when the power is turned on, the light source device 3 and the CCU 4 are operated in the normal observation mode.

  In addition, as shown in FIG. 5, for example, the operator inserts the distal end portion 10 of the insertion portion 9 into the urethra 70 and the distal end portion 10 becomes the prostate gland. This process is performed until reaching the bladder 71 through the urethra 70a near 72.

Then, the control unit 60 determines whether or not the mode has been switched to the NBI observation mode by the determination process in step S3 while the observation is performed in the normal observation mode in step S2.
When it is determined in this determination process that the mode has been switched to the NBI observation mode, the control unit 60 proceeds to the subsequent step S4, and when it is opposite to the mode that has not been switched to the NBI observation mode, the control unit 60 performs the process. It returns to S2 and repeats determination until it switches to NBI observation mode.

The determination process in this case is performed based on the mode switching signal from the mode switching button 13 or the determination result from the determination unit 54 of the light source device 3 as described above.
In addition, the control unit 60 performs the process when an operation signal is supplied from the operation button 13a that is pressed when the surgeon determines that the visual field has deteriorated while viewing the endoscopic image on the monitor 5, in step S4. Control may be performed so as to shift to.

  In the process of step S4, the control unit 60 starts driving the water pump 6 and the suction device 8 to execute the recirculation operation in the bladder 71, and at the same time, the observation in the NBI observation mode is performed in the process of step S5. The light source device 3 and the like are controlled so that they can be performed.

  The state in which the visual field near the distal end portion 10 in the bladder 71 is improved by performing the reflux operation by the process of step S4 is shown in FIGS.

  That is, immediately after the start of the recirculation operation, as shown in FIG. 6, the recirculation liquid 7b is fed from the water supply opening 18 of the front end portion 10 in the forward direction of the front end portion 10 (for example, in the direction of arrow A in FIG. 6). At the same time, excreta 71a such as hematuria accumulated in the bladder 71 is sucked from the suction opening 19 disposed on the side surface of the distal end portion 10. In this state, excrement 71a such as hematuria still remains in the bladder 71, which is not preferable for observation in the NBI observation mode.

  Thereafter, when the recirculation operation is continued further, as shown in FIG. 7, the visual field is gradually secured on the front side of the tip portion 10 by the water supply of the recirculation liquid 7b from the water supply opening 18. It will be. In this case, the circulating liquid 7b supplied from the water supply opening 18 is supplied in the directions of arrows B and C in FIG.

  At the same time, excreta 71 a such as hematuria in the bladder 71 is sucked from the side surface direction of the distal end portion 10 through the suction opening 19 of the distal end portion 10. That is, excreta 71a such as hematuria is sucked by the suction opening 19 so as to be pushed out in the direction of arrow D in FIG. 7 through the wall portion in the bladder 71 by the water supply of the circulating liquid 7b. .

  For this reason, in the present embodiment, since the suction opening 19 is provided on the side surface instead of the distal end surface of the distal end portion 10, excreta such as hematuria may collect near the observation window 32 in the bladder 71. Therefore, the recirculation operation can be effectively performed so as to suck the outside.

  The control unit 60 may control the water pump 6 and the suction device 8 to perform the operation at the same time or to perform the operation while repeating alternately after the start of the recirculation operation.

  When the circulation operation is completed, the bladder 71 is filled with the circulation liquid 7b as shown in FIG. For this reason, the observation window 32 of the inserted distal end portion 10 can be observed in the field-of-view range θ that is originally possessed, that is, a good field of view can be secured.

  Thus, the operator can obtain a color image with good visibility reflecting the surface layer portion in the bladder 71 (a fine pattern such as a capillary of the surface tissue) more remarkably in this NIB observation mode. , Observation can be performed smoothly.

  When the observation in the NIB observation mode is completed from the endoscope 2, the operator removes the insertion portion 9 from the bladder 71 in step S6.

  Thereafter, when the control section 60 finishes removing the insertion section 9 from the bladder 71 in step S6, the control section 60 completes this program and enters a standby state for the next treatment.

  Therefore, according to Example 1, when the normal observation mode is switched to the NBI observation mode, the perfusion operation in the bladder can be automatically started, and the perfusion operation is effectively performed to ensure a sufficient visual field. It is possible to realize the endoscope apparatus 1 that can be used.

  In the present embodiment, for example, physiological saline is used as the circulation liquid for performing the circulation operation, but the present invention is not limited to this, and other fluids may be used. In this case, the fluid is desirably optically transparent.

  Further, the fluid may be a liquid having high clayiness and optical transparency without being dissolved in excrement such as urine. In this case, the liquid may have a clay property that is changed by illumination light irradiated from an illumination window (not shown) of the distal end portion 10 or heat generated by the illumination light. That is, by using such a liquid, it is possible to prevent excrement such as urine from accumulating in the vicinity of the observation window 32 of the distal end portion 10. Therefore, a good visual field can be obtained with a simple configuration, and observation can be performed smoothly.

(Example 2)
FIG. 9 is a cross-sectional view of the distal end portion of the endoscope showing the second embodiment of the endoscope apparatus of the present invention. In FIG. 9, the same components as those of the first embodiment are denoted by the same reference numerals, description thereof is omitted, and only different portions are described.

  In the second embodiment, the cost can be reduced by improving the water supply pipe 16 and the suction pipe 17 provided in the endoscope apparatus 1 of the first embodiment, and the small diameter of the insertion portion 9 can be reduced. It is comprised so that it can achieve.

  Specifically, as shown in FIG. 9, in the distal end portion 10 of the endoscope 2, the air supply / water supply channel 16 </ b> A is formed at the proximal end portion of the reinforcing ring 25 as in the first embodiment. A connecting member 43A is provided. The connection member 43A is formed in a T shape so as to form the suction opening 19 at the same position as in the first embodiment. That is, the suction pipe 16B for forming the suction opening 19 is provided on the side surface (lower part) of the connection member 43A.

  That is, by providing the connecting member 43A, the water supply opening 18 and the suction opening 19 can be disposed at the same position as in the first embodiment.

  A single water / suction tube 45A having both an air / water feeding tube and a suction tube is connected to the base end of the connection member 43A. The proximal end side of the water / suction tube 45A is branched into two in the operation portion 12, one is connected to the water feed tube 16b via a water feed connector portion (not shown), and the other is a suction connector portion ( It is connected to the suction tube 17b via a not-shown).

  Further, since the insertion portion 9 of the endoscope 2 has one water supply / suction tube 45A on the proximal end side of the connection member 43A, the water supply opening 18 is used for suction. When excretion such as hematuria is aspirated from, hematuria collects in the field of view. For this reason, a check valve 80 is provided in front of the suction pipe line 16B in the connection member 43A.

  The check valve 80 allows the circulating liquid supplied through the water / suction tube 45A forming the water supply line 16A to pass therethrough while the circulating liquid is supplied by the water supply opening 18, while the suction opening is provided. At the time of suction of the circulating fluid or the like by 19, the circulating fluid sucked from the suction pipe 16 </ b> B is stopped and sucked into the water supply / suction tube 45 </ b> A.

  By adopting such a configuration, the first embodiment is configured with two tubes of the air / water feeding tube 45 and the suction tube 47. However, the internal view in which the recirculation operation is performed with only one water / suction tube 45A. A mirror 2 can be constructed.

However, in the second embodiment, it is not possible to simultaneously perform the water feeding operation of the circulating fluid and the suction operation of excrement such as hematuria and the circulating fluid. Therefore, the control unit 60 performs control so that the water pump 6 and the suction device 8 are alternately and repeatedly driven. That is, the controller 60 alternately performs the operation of supplying the circulating liquid through the water supply opening 18 and the operation of sucking excrement such as hematuria and the circulating liquid through the suction opening 19. To control. This acts in substantially the same manner as in Example 1, and the same effect is obtained.
The time for turning on / off the water pump 6 and the suction device 8 may be arbitrarily operated by the operator, or may be controlled based on a preset timing.
Other configurations and operations are the same as those in the first embodiment.

  Therefore, according to the second embodiment, substantially the same effect as in the first embodiment can be obtained, and the endoscope 2 that performs the recirculation operation with only one water / suction tube 45A can be configured, thereby reducing the cost. Of course, this greatly contributes to the reduction in the diameter of the insertion portion 9 of the endoscope 2.

  By the way, the endoscope apparatus 1 according to the present invention can also perform a reflux operation based on a bladder observation procedure described later. FIG. 10 shows a basic bladder observation procedure used in such an endoscope apparatus 1.

FIG. 10 is a flowchart showing a basic bladder observation procedure used in the endoscope apparatus of the present invention.
The control unit 60 of the CCU 4 reads and starts, for example, a bladder observation start program shown in FIG. 10 from a memory (not shown). That is, in step S11, the controller 60 inserts the insertion portion 9 through the urethra 70 and inserts the distal end portion 10 so as to reach the bladder 71 in step S11. Then, driving of the suction device 8 is started, and excreta such as hematuria and residual urine collected in the bladder 71 is sucked.

  Then, in the subsequent step S12, the control unit 60 starts driving the water supply pump 6 to supply and inject the circulating fluid into the bladder 71.

  Thereafter, the control unit 60 determines whether or not the inside of the bladder 71 is sufficiently inflated by the recirculation fluid. If it is determined that the bladder 71 is inflated, the process proceeds to step S14. If it is determined that the bladder 71 is not inflated, the process is performed. Return to S12 and repeat until the bladder expands.

  Note that the determination process in step S12 can be performed, for example, by providing a sensor or the like for detecting the pressure in the bladder 71 on the outer peripheral portion of the distal end portion 10 and comparing the detection value by this sensor with a preset threshold value. is there. Alternatively, the operator may determine that the inside of the bladder 71 has been swollen with the circulating fluid while viewing the endoscopic image.

  And in the process of step S14, the control part 60 stops the drive of the water supply pump 6, stops the injection | pouring of the recirculation liquid into the bladder 71, and transfers to step S15.

  In step S15, the control unit 60 controls the light source device 3 and the like so that observation can be performed in the normal observation mode or the NIB mode.

In this case as well, as in the first embodiment, a good visual field can be ensured, so that observation can be performed smoothly.
When the observation in the normal observation mode or the NIB observation mode by the endoscope 2 is finished, the insertion portion 9 is removed from the bladder 71 by the operator in step S16.

  Thereafter, when the control section 60 finishes removing the insertion section 9 from the bladder 71 in step S16, the control section 60 completes this program and enters a standby state for the next treatment.

  Therefore, even when such a bladder observation procedure is used, the same effect as in Example 1 can be obtained.

  The invention described in the above embodiments is not limited to the embodiments and modifications, and various modifications can be made without departing from the scope of the invention in the implementation stage. Further, the embodiments include inventions at various stages, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent elements.

  For example, even if some constituent elements are deleted from all the constituent elements shown in the embodiment, the problems described in the column of problems to be solved by the invention can be solved, and the effects described in the effects of the invention can be obtained. In such a case, a configuration in which this configuration requirement is deleted can be extracted as an invention.

1 is a block diagram illustrating a configuration of an entire system of an endoscope apparatus according to a first embodiment of the present invention. Sectional drawing of the front-end | tip part of the endoscope of FIG. The block diagram which shows schematic structure of CCU of FIG. 1, and a light source device. The flowchart which demonstrates the effect | action of an endoscope apparatus and shows the example of control by the control part of CCU. Explanatory drawing which shows the insertion state of the endoscope insertion part when inserting an endoscope insertion part transurethrally and inspecting the bladder. The figure which shows the state in the urinary bladder immediately after a perfusion operation start in response to switching of NBI observation mode. The figure which shows the state from which hematuria etc. are attracted | sucked simultaneously with the infusion fluid, and a visual field is ensured gradually. The figure which shows the state which the circulation operation | movement was completed and the visual field of the endoscope front-end | tip part vicinity was ensured favorably. Sectional drawing of the front-end | tip part of the endoscope in Example 2 of this invention. The flowchart which shows the basic bladder observation procedure used for the endoscope apparatus of this invention.

Explanation of symbols

1 ... Endoscopic device,
2. Endoscope,
3a: Light guide fiber,
3 ... light source device,
5 ... Monitor,
6 ... Water pump,
7 ... Tank,
7b ... recycle liquid,
8 ... suction device,
9 ... Insertion part,
10 ... tip part,
11 ... Insert body,
12 ... operation part,
13. Mode switching button,
16a ... air / water channel,
16b ... water supply tube,
16 ... water supply pipeline,
17a ... suction channel,
17b ... suction tube,
17 ... suction line,
18 ... opening for water supply,
19 ... opening for suction,
20: Imaging unit,
21 ... tip cover,
22 ... Cylinder member,
32 ... Observation window,
38. Image sensor,
42 ... Signal cable,
43 ... connecting member,
43A ... connecting member,
45A ... suction tube,
45 ... Air / water tube,
46: connecting member,
47 ... suction tube,
50: Light source control unit,
51 ... Light source part,
52. Filter section,
53. Filter drive unit,
54. Determination unit,
60 ... control unit,
64 ... light control part,
67 ... Memory part,
68. Image processing unit,
70 ... urethra,
71a ... excrement,
71 ... Bladder,
72. Prostate.

Claims (5)

In an endoscope apparatus capable of refluxing a reflux liquid in a body cavity,
Illumination means for selectively performing illumination for visible light band observation and illumination for narrow band observation,
An observation means for imaging a subject with an optical imaging means provided in an endoscope using illumination by the illumination means to obtain a visible light band observation image or a narrow band observation image;
A water supply means for supplying a reflux liquid into the body cavity through a water supply pipe provided in the endoscope body;
A suction means for sucking the fluid for reflux, and the body fluid or excrement from the body cavity through the suction conduit provided in the endoscope body;
Control means for controlling to start at least one of the water supply means and the suction means when the observation image obtained by the observation means is switched from the visible light band observation image to the narrow band observation image;
An endoscope apparatus characterized by comprising: Switching from the visible band observation image to the narrow band observation image,
By a mode switching button for switching between a visible light band observation mode for obtaining the visible light band observation image and a narrow band observation mode for obtaining the narrow band observation image provided in the operation unit of the endoscope The endoscope apparatus according to claim 1, wherein the endoscope apparatus is performed. The illumination means includes
An optical filter unit for selectively performing the illumination for visible band observation and the illumination for narrow band observation, and the observation mode being executed based on the operating state of the optical filter unit is the visible light. A determination unit that determines whether the visible light band observation mode using illumination for band observation and the narrow band observation mode using illumination for narrow band observation; and
Switching from the visible light band observation image to the narrow band observation image,
The endoscope apparatus according to claim 1, wherein the endoscope apparatus is performed when the determination unit of the illuminating unit determines that the narrowband observation mode is set. The control means includes
4. The control unit according to claim 1, wherein after the start of the operation, the water supply unit and the suction unit are controlled to perform the operation at the same time or alternately while repeating the operation. The endoscope apparatus described in 1. The water supply conduit has a water supply opening on the distal end surface of the distal end portion of the endoscope,
The endoscope according to any one of claims 1 to 4, wherein the suction conduit has a suction opening in a side surface portion of the distal end portion of the endoscope. apparatus.

Images