JP7198184B2 - Endoscope, fluorescence measurement device and lens holding cylinder - Google Patents

Description

TECHNICAL FIELD The present invention relates to acquisition of fluorescence obtained by irradiating an irradiation target (for example, a sentinel lymph node) in which a fluorescent substance is accumulated with excitation light.

Endoscopy that recognizes lesions (e.g., malignant tumors, etc.) by observing the fluorescence obtained by irradiating excitation light onto irradiation targets (e.g., sentinel lymph nodes, etc.) that have accumulated fluorescent substances. mirrors are known.

For example, Patent Documents 1, 2, and 3 describe collimated light beams that are focused and applied to an optical fiber or light guide and then to an irradiation target. Further, unlike Patent Documents 1 to 3, Patent Document 4 describes that a collimated light beam is applied to an irradiation target.

Furthermore, Patent Document 5 describes cleaning the tip of an endoscope, Patent Document 6 describes an endoscope in which a large number of lenses are arranged in a lens barrel, and Patent Document 7 describes an endoscope. describes an endoscope in which the lens is heated by a heater to prevent fogging. Patent Document 8 describes an endoscope in which optical fibers are bundled.

JP 2016-120105 A WO2018-051558 WO2016-006371 JP-A-2007-303990 JP 2009-189496 A JP-A-5-297272 Japanese Unexamined Patent Application Publication No. 2006-282 JP 2010-158358 A

However, according to the conventional technology as described above, an optical element (for example, an objective lens) located at the distal end of the endoscope becomes dirty due to adherence of bodily fluids, which interferes with fluorescence observation.

Accordingly, an object of the present invention is to provide an endoscope in which the acquisition of fluorescence is less likely to be hindered by bodily fluids.

An endoscope according to the present invention includes an excitation light source that generates excitation light, an objective lens that receives fluorescence generated when an irradiation target receives the excitation light, and a cylindrical body that holds the objective lens, An objective lens is configured to be positioned inside the tubular body at a central portion of the tubular body.

According to the endoscope configured as described above, the excitation light source generates excitation light. The objective lens receives fluorescence generated when an irradiation target receives the excitation light. A cylindrical body holds the objective lens. The objective lens is arranged inside the tubular body at a central portion of the tubular body.

In addition, the endoscope according to the present invention may include a collimating section for collimating the excitation light.

In addition, in the endoscope according to the present invention, when the length of the cylindrical body is L, the central portion is L/3 or more and 2 L/3 or less from the end of the cylindrical body on the irradiation target side. may be the region of

The endoscope according to the present invention may include a visible light source that generates visible light and a combiner that combines the visible light and the excitation light.

In the endoscope according to the present invention, the collimating section may be a lens, and may include a mirror for changing the traveling direction of the excitation light transmitted through the collimating section to the direction toward the irradiation target. .

The endoscope according to the present invention includes a first polarizer that transmits the excitation light and a second polarizer that transmits the fluorescence, and the transmission axis of the first polarizer and the second polarized light You may make it orthogonal to the transmission axis of a child.

The endoscope according to the present invention includes a polarization-maintaining fiber that receives the excitation light and supplies it to the first polarizer. It may be made to coincide with the transmission axis.

In the endoscope according to the present invention, the excitation light source may have a fiber laser.

In the endoscope according to the present invention, the excitation light source may further have a wavelength conversion element for converting the wavelength of the fiber laser.

The endoscope according to the present invention includes an excitation light transmission optical fiber that is a single-mode fiber that transmits the excitation light, and the excitation light transmitted by the excitation light transmission optical fiber, and receives the excitation light and a polarization controller for providing the direction of the normal to the plane of polarization of the first polarizer by making the direction perpendicular to the transmission axis of the first polarizer.

The endoscope according to the present invention may include an infrared light source for generating infrared light, and the objective lens may absorb the infrared light.

In addition, the endoscope according to the present invention may include a coating that reflects the infrared light and transmits the excitation light and the fluorescence on the surface of the objective lens on the irradiation target side.

The endoscope according to the present invention includes a fluorescence transmission optical fiber that transmits the fluorescence that has passed through the objective lens, and a fluorescence transmission optical fiber that receives the fluorescence that has passed through the objective lens and supplies the fluorescence to one end of the fluorescence transmission optical fiber. A fluorescence transmitting lens may be provided.

In addition, in the endoscope according to the present invention, the lens arranged inside the cylindrical body may be only one objective lens.

A fluorescence measuring apparatus according to the present invention is configured to include an endoscope according to the present invention, and a fluorescence measuring section that measures the fluorescence transmitted through the objective lens.

A lens-holding tubular body according to the present invention comprises an objective lens for receiving fluorescence generated when an irradiation target receives excitation light, and a tubular body for holding the objective lens, wherein the objective lens is the tubular body. is arranged in the central portion of the tubular body, inside the .

1 is a diagram showing a configuration of a fluorescence measurement device 1 according to a first embodiment and optical paths of excitation light and visible light; FIG. 1 is a diagram showing a configuration of a fluorescence measurement device 1 according to a first embodiment and optical paths of fluorescence and reflected light; FIG. FIG. 2 is a diagram showing the configuration of a fluorescence measurement device 1 and optical paths of excitation light and visible light according to a second embodiment; FIG. 2 is a diagram showing the configuration of a fluorescence measurement device 1 according to a second embodiment and the optical paths of fluorescence and reflected light; FIG. 3 is a diagram showing the configuration of a fluorescence measurement device 1 according to a third embodiment and the optical paths of excitation light and visible light; FIG. 10 is a diagram showing the configuration of a fluorescence measurement device 1 according to a third embodiment and the optical paths of fluorescence and reflected light; FIG. 10 is a diagram showing the configuration of a fluorescence measurement device 1 according to a fourth embodiment and the optical paths of excitation light and visible light; FIG. 10 is a diagram showing the configuration of a fluorescence measurement device 1 according to a fourth embodiment and the optical paths of fluorescence and reflected light; FIG. 10 is a diagram showing the configuration of a fluorescence measurement device 1 and optical paths of excitation light and visible light according to a fifth embodiment; FIG. 10 is a diagram showing the configuration of a fluorescence measurement device 1 according to a fifth embodiment and the optical paths of fluorescence and reflected light; FIG. 11 is a schematic diagram showing light reflected and transmitted by coatings TF1 and TF2 of the objective lens L1 according to the fifth embodiment;

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

First Embodiment FIG. 1 is a diagram showing the configuration of a fluorescence measurement device 1 and optical paths of excitation light and visible light according to a first embodiment. FIG. 2 is a diagram showing the configuration of the fluorescence measurement device 1 according to the first embodiment and optical paths of fluorescence and reflected light.

A fluorescence measurement device 1 includes an endoscope 2 and a spectroscope (fluorescence measurement section) 4 . The endoscope 2 is, for example, a laparoscope. The spectroscope 4 is an example of a fluorescence measurement unit that measures fluorescence transmitted through the objective lens L1, and disperses the fluorescence.

The endoscope 2 includes a light source section 22 and a scope section 24 .

The light source unit 22 has an excitation light source 22a, a visible light source 22b, single mode fibers 22c and 22d, a WDM coupler (multiplexer) 22e, and an optical fiber 22m.

The excitation light source 22a generates excitation light. The excitation light is light for irradiating the sentinel lymph node (irradiation target) SLN where the fluorescent substance is present. When ICG (indocyanine green) is used as the fluorescent substance, the excitation light is laser light of 785 nm.

The visible light source 22b generates visible light (for example, laser light of 520 nm).

The single mode fiber 22c is connected to the excitation light source 22a and transmits excitation light. Single mode fiber 22d is connected to visible light source 22b and transmits visible light.

A WDM coupler (multiplexer) 22e is coupled to the single-mode fiber 22c and the single-mode fiber 22d, and multiplexes the excitation light and visible light. The WDM coupler 22e provides combined light obtained by combining the excitation light and visible light to the optical fiber 22m.

The optical fiber 22m transmits the multiplexed light.

The scope unit 24 includes a connector 242, a tubular body 244, a fluorescence transmission optical fiber 246, a connection end portion 246a, an objective lens L1, a fluorescence transmission lens L2, a collimating lens (collimating portion) L3, a dichroic mirror M1, It has a bandpass filter F1.

The fluorescence transmission optical fiber 246 transmits the fluorescence (see FIG. 2) that has passed through the objective lens L1. The connecting end 246a is attached near one end of the fluorescence-transmitting optical fiber 246. As shown in FIG. The fluorescence transmitting optical fiber 246 passes through the connecting end 246a. The other end of the fluorescence transmission optical fiber 246 is connected to the spectroscope 4 .

The connector 242 connects the optical fiber 22m, the cylindrical body 244 and the optical fiber 246 for fluorescence transmission. Connector 242 also accommodates dichroic mirror M1, bandpass filter F1, fluorescence transmission lens L2, and collimator lens L3.

The connector 242 has an opening 242a, an opening 242b, an opening 242c and a connecting end 242d. The optical fiber 22 m is inserted into the opening 242 a and connected to the connector 242 . A cylindrical body 244 is inserted into the opening 242 b and connected to the connector 242 . A connecting end 242d is attached to the opening 242c. A connection end portion 246 a is inserted into the connection end portion 242 d , and a fluorescence transmission optical fiber 246 is connected to the connector 242 .

The extending direction of the central axis (optical axis) of the cylindrical body 244 and the extending direction of the central axis (optical axis) of the fluorescence transmission optical fiber 246 match. The extending direction of the central axis (optical axis) of the optical fiber 22m and the extending direction of the central axis (optical axis) of the tubular body 244 are perpendicular to each other.

The cylindrical body 244 holds the objective lens L1. It should be noted that only one lens, the objective lens L1, is arranged inside the cylindrical body 244. As shown in FIG. Further, not only lenses but also optical elements such as cover glass are not arranged inside the cylindrical body 244 . In particular, it should be noted that no optical element is arranged at the end of the tubular body 244 on the sentinel lymph node SLN side. Furthermore, the objective lens L1 and the cylindrical body 244 are collectively referred to as a lens holding cylindrical body. WD is the distance between the sentinel lymph node SLN side end of the cylindrical body 244 and the sentinel lymph node SLN. WD is, for example, 20 to 50 mm.

The objective lens L1 receives fluorescence generated when the sentinel lymph node (irradiation target) SLN receives excitation light. The objective lens L1 is arranged inside the tubular body 244 and at the central portion of the tubular body 244 . The central portion is an area of L/3 or more and 2 L/3 or less from the end of the cylinder 244 on the sentinel lymph node SLN side, where the length of the cylinder 244 is L (for example, 300 mm). .

The central portion is shown in FIGS. 1 and 2 and is omitted in the other figures. However, in any embodiment, the objective lens L1 is arranged in the central portion.

The fluorescence transmission lens L2 receives the fluorescence transmitted through the objective lens L1 and supplies it to one end of the fluorescence transmission optical fiber 246 (see FIG. 2).

A collimating lens (collimating portion) L3 is arranged in a portion slightly recessed from the opening 242a, receives the excitation light emitted from one end of the optical fiber 22m, and collimates the excitation light.

The dichroic mirror M1 is arranged at the intersection of the central axis (optical axis) of the cylindrical body 244, the central axis (optical axis) of the optical fiber for fluorescence transmission 246, and the central axis (optical axis) of the optical fiber 22m. It is The dichroic mirror M1 is inclined (downward to the right) by 45 degrees with respect to the central axis (optical axis) of the tubular body 244 and the central axis (optical axis) of the optical fiber 22m.

The dichroic mirror M1 changes the direction of travel of the excitation light and visible light transmitted through the collimating lens L3 by 45 degrees to the direction toward the sentinel lymph node SLN (see FIG. 1). Note that the dichroic mirror M1 allows the fluorescence that has passed through the objective lens L1 to pass therethrough (see FIG. 2).

The band-pass filter F1 transmits fluorescence that has passed through the objective lens L1, but does not transmit reflected light (excitation light and visible light reflected by the sentinel lymph node SLN).

Next, operation of the first embodiment will be described.

First, referring to FIG. 1, excitation light is generated from the excitation light source 22a and visible light is generated from the visible light source 22b. . The combined light (excitation light and visible light) is collimated by collimating lens L3, reflected by dichroic mirror M1, and directed toward sentinel lymph node SLN. The excitation light and visible light pass through the objective lens L1 and irradiate the sentinel lymph node SLN.

The excitation light and visible light collimated by the collimating lens L3 are almost parallel light, and although they are not completely parallel light due to manufacturing errors of the collimating lens L3 and the effects of light diffraction, they are regarded as parallel light. (The same applies to other embodiments).

Next, referring to FIG. 2, since the sentinel lymph node SLN contains a fluorescent substance, it emits fluorescence when irradiated with excitation light. The sentinel lymph node SLN reflects excitation light and visible light (reflected light). The fluorescent light and the reflected light travel through the cylindrical body 244, are received by the objective lens L1, and pass through the objective lens L1. The fluorescence further passes through the dichroic mirror M1 and reaches the fluorescence transmitting lens L2. The reflected light is reflected by the dichroic mirror M1, and part of the reflected light passes through the dichroic mirror M1 and reaches the fluorescence transmission lens L2. The fluorescence transmission lens L2 receives fluorescence and provides it to one end of the fluorescence transmission optical fiber 246 . However, the reflected light that has passed through the fluorescence transmission lens L2 is cut by the bandpass filter F1 and is not given to one end of the fluorescence transmission optical fiber 246. FIG. The fluorescence transmission optical fiber 246 transmits the fluorescence to the spectroscope 4 . The fluorescence is spectroscopically separated by the spectroscope 4 and measured.

However, the reflected visible light is also acquired by another endoscope (not shown) to acquire a video image of the sentinel lymph node SLN. This makes it easier to understand the range irradiated with the excitation light (the same applies to other embodiments).

According to the first embodiment, the objective lens L1 is placed in the central portion of the tubular body 244 and thus far away from the sentinel lymph node SLN. For this reason, the objective lens L1 is hardly soiled by bodily fluids in the vicinity of the sentinel lymph node SLN, so that acquisition of fluorescence is less likely to be hindered by bodily fluids. The end of the cylindrical body 244 on the side of the sentinel lymph node SLN is easily soiled by the body fluid near the sentinel lymph node SLN, but since no optical element is arranged at that end, the acquisition of fluorescence is less likely to be hindered by the body fluid. .

If the objective lens L1 is further removed from the sentinel lymph node SLN than the central portion of the cylindrical body 244, the solid angle of the objective lens L1 when viewed from a point on the sentinel lymph node SLN becomes too small. and the efficiency of acquiring fluorescence is too low. Therefore, by arranging the objective lens L1 in the central portion of the cylindrical body 244, a decrease in the efficiency of acquiring fluorescence is suppressed. Since the diameter of the objective lens L1 is the same as the inner diameter of the cylindrical body 244 and is considerably large, even if the objective lens L1 is far away from the sentinel lymph node SLN, the solid angle is large and fluorescence is efficiently acquired.

Furthermore, according to the first embodiment, only one lens, the objective lens L1, is arranged inside the cylindrical body 244, so the lens holding cylindrical body (the objective lens L1 and the cylindrical body 244) can lower the cost of Therefore, it is possible to replace the lens holding cylinder each time the endoscope 2 is used in terms of cost. Since the structure of the lens holding cylinder is simple, autoclave sterilization can be performed.

Furthermore, according to the first embodiment, since the excitation light is collimated by the collimating lens L3 and applied to the sentinel lymph node SLN, the power of the excitation light applied to the sentinel lymph node SLN is can be kept almost constant. That is, even if the WD increases, the power of the excitation light applied to the sentinel lymph node SLN does not become too small, and even if the WD decreases, the power of the excitation light applied to the sentinel lymph node SLN does not become too large.

Second Embodiment A fluorescence measurement apparatus 1 according to a second embodiment includes single-mode fibers 22c and 22d in that it includes a first polarizer PBS1, a second polarizer PBS2, and polarization-maintaining fibers 22f and 22g. It differs from the fluorometer 1 according to the first embodiment.

FIG. 3 is a diagram showing the configuration of the fluorescence measurement device 1 according to the second embodiment and optical paths of excitation light and visible light. FIG. 4 is a diagram showing the configuration of the fluorescence measurement device 1 according to the second embodiment and optical paths of fluorescence and reflected light. Hereinafter, parts similar to those of the first embodiment are denoted by similar reference numerals, and descriptions thereof are omitted.

The endoscope 2 includes a light source section 22 and a scope section 24 .

The light source unit 22 has an excitation light source 22a, a visible light source 22b, polarization maintaining fibers 22f and 22g, a polarization maintaining WDM coupler (multiplexer) 22e1, and a polarization maintaining fiber 22m1.

The excitation light source 22a and the visible light source 22b are the same as those in the first embodiment, and descriptions thereof are omitted.

A polarization-maintaining WDM coupler (multiplexer) 22e1 is similar to the WDM coupler (multiplexer) 22e of the first embodiment, but is of a polarization-maintaining type and includes a polarization-maintaining fiber 22f and a polarization-maintaining fiber. 22g. The polarization-maintaining fiber 22m1 is similar to the optical fiber 22m of the first embodiment, except that it is of a polarization-maintaining type.

The polarization maintaining fiber 22f is connected to the excitation light source 22a. The polarization-maintaining fiber 22f receives pumping light from the pumping light source 22a and provides it to the first polarizer PBS1 via the polarization-maintaining WDM coupler 22e1 and the polarization-maintaining fiber 22m1. Note that the slow axis or fast axis of the polarization maintaining fiber 22f and the transmission axis of the first polarizer PBS1 match.

The polarization maintaining fiber 22g is connected to the visible light source 22b. The polarization-maintaining fiber 22g receives excitation light from the visible light source 22b and provides it to the first polarizer PBS1 via the polarization-maintaining WDM coupler 22e1 and the polarization-maintaining fiber 22m1. Note that the slow axis or fast axis of the polarization maintaining fiber 22g and the transmission axis of the first polarizer PBS1 match.

The scope unit 24 includes a connector 242, a tubular body 244, a fluorescence transmission optical fiber 246, a connection end portion 246a, an objective lens L1, a fluorescence transmission lens L2, a collimating lens (collimating portion) L3, a dichroic mirror M1, It has a bandpass filter F1, a first polarizer PBS1 and a second polarizer PBS2.

The connector 242, the cylindrical body 244, the fluorescence transmission optical fiber 246, the connection end portion 246a, the objective lens L1, the fluorescence transmission lens L2, the collimating lens (collimating portion) L3, the dichroic mirror M1, and the bandpass filter F1 are , is the same as the first embodiment, and the description thereof is omitted. However, connector 242 also accommodates first polarizer PBS1 and second polarizer PBS2.

A first polarizer PBS1 is arranged between the collimating lens L3 and the dichroic mirror M1. The first polarizer PBS1 transmits excitation light and visible light (see FIG. 3).

The second polarizer PBS2 is arranged between the bandpass filter F1 and one end of the optical fiber 246 for fluorescence transmission. The second polarizer PBS2 is transparent to fluorescence (see FIG. 4). More precisely, the fluorescence incident on the second polarizer PBS2 is randomly polarized, and the polarized component (component orthogonal to the polarization plane of the excitation light) that passes through the second polarizer PBS2 of the fluorescence is the It is transmitted through the dual polarizer PBS2.

However, the transmission axis of the first polarizer PBS1 and the transmission axis of the second polarizer PBS2 are orthogonal.

Next, the operation of the second embodiment will be explained.

First, referring to FIG. 3, excitation light is generated from excitation light source 22a, visible light is generated from visible light source 22b, polarization maintaining fiber 22f and polarization maintaining fiber 22g (either slow axis or fast axis are ), are combined by a polarization-maintaining WDM coupler 22e1, and supplied to a collimator lens L3 through a polarization-maintaining fiber 22m1. The combined light (excitation light and visible light) is collimated by collimating lens L3, linearly polarized by first polarizer PBS1, reflected by dichroic mirror M1, and directed toward sentinel lymph node SLN. The excitation light and visible light pass through the objective lens L1 and irradiate the sentinel lymph node SLN.

Next, referring to FIG. 4, since the sentinel lymph node SLN contains a fluorescent substance, it emits fluorescence when irradiated with excitation light. The sentinel lymph node SLN reflects excitation light and visible light (reflected light). The fluorescent light and the reflected light travel through the cylindrical body 244, are received by the objective lens L1, and pass through the objective lens L1. The fluorescence further passes through the dichroic mirror M1 and reaches the fluorescence transmitting lens L2. The reflected light is reflected by the dichroic mirror M1, and part of the reflected light passes through the dichroic mirror M1 and reaches the fluorescence transmitting lens L2. The fluorescence transmission lens L2 receives fluorescence and provides it to one end of the fluorescence transmission optical fiber 246 . However, the reflected light that has passed through the fluorescence transmission lens L2 is cut by the bandpass filter F1. The reflected light that has passed through the bandpass filter F1 is linearly polarized by the first polarizer PBS1 as described above, but cannot pass through the second polarizer PBS2 (the first polarizer PBS1 and the transmission axis of the second polarizer PBS2 are perpendicular to each other), it is not applied to one end of the optical fiber 246 for fluorescence transmission. The fluorescence transmission optical fiber 246 transmits the fluorescence to the spectroscope 4 . The fluorescence is spectroscopically separated by the spectroscope 4 and measured.

Thus, reflection (reflected light) of the excitation light and visible light by the sentinel lymph node SLN is not provided to one end of the optical fiber for fluorescence transmission 246 by the dichroic mirror M1, the bandpass filter F1 and the second polarizer PBS2. It's like Some of the excitation light and visible light are also reflected by the objective lens L1, but they are also reflected by the dichroic mirror M1 and the bandpass filter F1, as well as the reflection of the excitation light and visible light by the sentinel lymph node SLN (reflected light). and the second polarizer PBS2 to prevent it from being applied to one end of the fluorescence-transmitting optical fiber 246 .

According to the second embodiment, the same effects as those of the first embodiment are obtained. Moreover, according to the second embodiment, by linearly polarizing the excitation light and the visible light by the first polarizer PBS1, the reflected light that has passed through the bandpass filter F1 (the excitation light and the visible light are The light reflected by the sentinel lymph node SLN) is not transmitted by the second polarizer PBS2 (the transmission axis of the first polarizer PBS1 and the transmission axis of the second polarizer PBS2 are orthogonal), and the fluorescence transmission can be avoided at one end of the optical fiber 246 for use.

Third Embodiment The fluorescence measurement apparatus 1 according to the third embodiment differs from the fluorescence measurement apparatus 1 according to the second embodiment in that the excitation light source 220 has a fiber laser 222 and a PPLN (wavelength conversion element) 224. different.

FIG. 5 is a diagram showing the configuration of the fluorescence measurement device 1 according to the third embodiment and optical paths of excitation light and visible light. FIG. 6 is a diagram showing the configuration of the fluorescence measurement device 1 according to the third embodiment and optical paths of fluorescence and reflected light. Hereinafter, parts similar to those of the second embodiment are denoted by similar reference numerals, and descriptions thereof are omitted.

The endoscope 2 includes a light source section 22 and a scope section 24 .

The light source unit 22 has an excitation light source 220, a visible light source 22b, polarization maintaining fibers 22f and 22g, a polarization maintaining WDM coupler (multiplexer) 22e1, and a polarization maintaining fiber 22m1. A visible light source 22b, a polarization-maintaining WDM coupler (multiplexer) 22e1, a polarization-maintaining fiber 22g, and a polarization-maintaining fiber 22m1 are the same as those in the second embodiment, and description thereof is omitted.

The polarization maintaining fiber 22f is connected to the excitation light source 220. As shown in FIG.

The excitation light source 220 has a fiber laser 222 and a PPLN (wavelength conversion element) 224 .

The fiber laser 222 is an Er-doped continuous wave laser with an oscillation wavelength of 1570 nm. It should be noted that the fiber laser has a favorable characteristic that the output is high at the oscillation wavelength, and that the output sharply drops when the oscillation wavelength deviates even slightly.

A PPLN (wavelength conversion device) 224 is a nonlinear optical device that converts the wavelength of the fiber laser 222 to 1/2 and supplies it to the polarization maintaining fiber 22f as excitation light of 785 nm. The PPLN 224 converts the wavelength by a factor of 2 by generating a second harmonic.

The scope unit 24 is the same as that of the second embodiment, and its description is omitted.

Next, the operation of the third embodiment will be explained.

First, referring to FIG. 5, laser light with a wavelength of 1570 nm is output from fiber laser 222 and applied to PPLN 224 . The PPLN 224 generates a second harmonic wave of a laser beam with a wavelength of 1570 nm, converts the wavelength to 1/2, outputs a laser beam with a wavelength of 785 nm, and gives it to the polarization-maintaining fiber 22f as excitation light.

Visible light is generated from the visible light source 22b. The excitation light and visible light are transmitted through the polarization-maintaining fiber 22f and the polarization-maintaining fiber 22g (both slow and fast axes are aligned with the transmission axis of the first polarizer PBS1) through polarization-maintaining WDM. The light is multiplexed by the coupler 22e1 and applied to the collimator lens L3 via the polarization maintaining fiber 22m1. The combined light (excitation light and visible light) is collimated by collimating lens L3, linearly polarized by first polarizer PBS1, reflected by dichroic mirror M1, and directed toward sentinel lymph node SLN. The excitation light and visible light pass through the objective lens L1 and irradiate the sentinel lymph node SLN.

Next, referring to FIG. 6, since the sentinel lymph node SLN contains a fluorescent substance, it emits fluorescence when irradiated with excitation light. The sentinel lymph node SLN reflects excitation light and visible light (reflected light). The operation after this is the same as the operation of the second embodiment described with reference to FIG. 4, and the description is omitted.

According to the third embodiment, the same effects as those of the second embodiment are obtained. Moreover, according to the third embodiment, the output of the excitation light is high at the oscillation wavelength, and the output sharply decreases when the oscillation wavelength is deviated even slightly. For this reason, the excitation light is reflected by the sentinel lymph node SLN (referred to as "reflected light of excitation light") and reaches the bandpass filter F1. . Therefore, even if the reflected light of the excitation light is not transmitted by the band-pass filter F1, the fluorescence to be measured is not largely cut, and it is easy to prevent the reflected light of the excitation light from being transmitted. becomes.

When an LED or a semiconductor laser is used as the excitation light source, even if the wavelength is slightly off the oscillation wavelength, the output does not decrease so much. Therefore, it is difficult to prevent the reflected light of the excitation light from being transmitted by the band-pass filter F1. If the band-pass filter F1 is used to sufficiently cut the reflected light of the excitation light that is slightly off the oscillation wavelength, the wavelength of the excitation light and the fluorescence wavelength are close to each other. This is because some fluorescence will also be largely cut.

However, as described above, according to the third embodiment, since the fiber laser 222 is used as the excitation light source, it becomes easy to prevent the reflected light of the excitation light from being transmitted by the band-pass filter F1. .

Fourth Embodiment The fluorescence measurement apparatus 1 according to the fourth embodiment includes the polarization controllers 22j and 22k, but does not include the polarization maintaining fibers 22f and 22g. Differs from device 1.

FIG. 7 is a diagram showing the configuration of the fluorescence measurement device 1 according to the fourth embodiment and optical paths of excitation light and visible light. FIG. 8 is a diagram showing the configuration of the fluorescence measurement device 1 according to the fourth embodiment and optical paths of fluorescence and reflected light. Hereinafter, parts similar to those of the second embodiment are denoted by similar reference numerals, and descriptions thereof are omitted.

The endoscope 2 includes a light source section 22 and a scope section 24 .

The light source unit 22 has an excitation light source 22a, a visible light source 22b, single mode fibers 22c, 22d, 22h and 22i, a WDM coupler (multiplexer) 22e, polarization controllers 22j and 22k, and an optical fiber 22m.

The excitation light source 22a, the visible light source 22b, and the WDM coupler 22e are the same as those in the first embodiment, and their description is omitted.

A single mode fiber (optical fiber for pumping light transmission) 22h is connected to the pumping light source 22a and transmits pumping light. The polarization controller 22j receives the excitation light transmitted by the single-mode fiber 22h, and makes the direction of the normal to the plane of polarization of the excitation light orthogonal to the transmission axis of the first polarizer PBS1 (the polarized excitation light is transmitted through the first polarizer PBS1), and supplied to the first polarizer PBS1 via the WDM coupler 22e and the optical fiber 22m.

A single mode fiber 22i is connected to a visible light source 22b and transmits visible light. The polarization controller 22k receives the visible light transmitted by the single-mode fiber 22i, and makes the direction of the normal to the plane of polarization of the visible light orthogonal to the transmission axis of the first polarizer PBS1 (the polarized visible light is transmitted through the first polarizer PBS1), and supplied to the first polarizer PBS1 via the WDM coupler 22e and the optical fiber 22m.

The single mode fiber 22c is connected to a polarization controller 22j and transmits pump light. Single mode fiber 22d is connected to polarization controller 22k and transmits visible light.

The scope unit 24 is the same as that of the second embodiment, and its description is omitted.

Next, operation of the fourth embodiment will be described.

First, referring to FIG. 7, excitation light is generated from excitation light source 22a, and visible light is generated from visible light source 22b. The polarization controller 22j and the polarization controller 22k make the direction of the normal to the plane of polarization of the excitation light and the visible light orthogonal to the transmission axis of the first polarizer PBS1. The outputs of the polarization controllers 22j and 22k are combined by the WDM coupler 22e and applied to the collimating lens L3 via the optical fiber 22m. The combined light (excitation light and visible light) is collimated by collimating lens L3, linearly polarized by first polarizer PBS1, reflected by dichroic mirror M1, and directed toward sentinel lymph node SLN. The excitation light and visible light pass through the objective lens L1 and irradiate the sentinel lymph node SLN.

Next, referring to FIG. 8, since the sentinel lymph node SLN contains a fluorescent substance, it emits fluorescence when irradiated with excitation light. The sentinel lymph node SLN reflects excitation light and visible light (reflected light). The operation after this is the same as the operation of the second embodiment described with reference to FIG. 4, and the description is omitted.

According to the fourth embodiment, the same effects as those of the second embodiment are obtained.

Fifth Embodiment A fluorescence measurement apparatus 1 according to a fifth embodiment is different from the fluorescence measurement apparatus 1 according to the first embodiment in that it includes an infrared light source 6 and the objective lens L1 has a coating TF1.

FIG. 9 is a diagram showing the configuration of the fluorescence measurement device 1 according to the fifth embodiment and the optical paths of excitation light and visible light. FIG. 10 is a diagram showing the configuration of the fluorescence measurement device 1 according to the fifth embodiment and optical paths of fluorescence and reflected light. Hereinafter, parts similar to those of the first embodiment are denoted by similar reference numerals, and descriptions thereof are omitted.

The endoscope 2 includes a light source section 22 , a scope section 24 and an infrared light source 6 .

The light source part 22 is the same as that of the first embodiment, and the description thereof is omitted.

The infrared light source 6 generates infrared light.

The scope unit 24 includes a connector 242, a tubular body 244, a fluorescence transmission optical fiber 246, a connection end portion 246a, an infrared light transmission optical fiber 248, a connection end portion 248a, an objective lens L1, and a fluorescence transmission lens. It has L2, a collimating lens (collimating section) L3, a collimating lens L4, dichroic mirrors M1 and M2, and a bandpass filter F1.

The infrared light transmission optical fiber 248 transmits infrared light (see FIG. 9). The connecting end 248a is attached near one end of the optical fiber 248 for transmitting infrared light. The optical fiber 248 for infrared light transmission passes through the connecting end 248a. The other end of the infrared light transmission optical fiber 248 is connected to the infrared light source 6 .

The connector 242, the cylindrical body 244, the fluorescence transmission optical fiber 246, the connection end portion 246a, the fluorescence transmission lens L2, the collimating lens (collimating portion) L3, the dichroic mirror M1, and the bandpass filter F1 are the first Since it is the same as the embodiment, the description is omitted.

However, connector 242 also accommodates collimating lens L4 and dichroic mirror M2, and has aperture 242e. A connecting end portion 248 a is inserted into the opening 242 e , and an optical fiber 248 for transmitting infrared light is connected to the connector 242 .

The collimating lens L4 is arranged in a portion slightly recessed from the opening 242e, receives the infrared light from the infrared light transmission optical fiber 248, and collimates the infrared light. The infrared light collimated by the collimating lens L4 is almost parallel light, and although it cannot be said to be perfectly parallel light due to manufacturing errors of the collimating lens L4 and the effects of light diffraction, it can be regarded as parallel light. It is possible.

The extending direction of the central axis (optical axis) of the optical fiber for infrared transmission 248 and the extending direction of the central axis (optical axis) of the optical fiber for fluorescence transmission 246 are parallel. Therefore, the extending direction of the central axis (optical axis) of the optical fiber 22m is orthogonal to the extending direction of the central axis (optical axis) of the optical fiber 248 for infrared light transmission.

The dichroic mirror M2 is arranged at the intersection of the central axis (optical axis) of the optical fiber 248 for transmitting infrared light and the central axis (optical axis) of the optical fiber 22m. The dichroic mirror M2 is inclined at 45 degrees (downward to the right) with respect to the central axis (optical axis) of the infrared light transmission optical fiber 248 and the central axis (optical axis) of the optical fiber 22m.

The dichroic mirror M2 transmits the excitation light and the visible light (provided from the optical fiber 22m), and adjusts the travel direction of the infrared light (given from the infrared light transmission optical fiber 248) to the travel direction of the excitation light and the visible light. Orient (see Figure 9).

The objective lens L1 is similar to the first embodiment, but additionally absorbs infrared light and is provided with coatings TF1, TF2.

FIG. 11 is a schematic diagram showing light reflected and transmitted by the coatings TF1 and TF2 of the objective lens L1 according to the fifth embodiment.

The objective lens L1 has a coating TF1 that reflects infrared light and transmits excitation light, visible light, fluorescent light, and reflected light on the surface on the irradiation target (sentinel lymph node SLN) side. The objective lens L1 further has a coating TF2 on the surface opposite to the irradiation target side, which transmits infrared light, excitation light, visible light, fluorescent light and reflected light.

Next, the operation of the fifth embodiment will be explained.

Operations for excitation light and visible light (see FIG. 9) are the same as those in the first embodiment (see FIG. 1), and descriptions thereof are omitted. The operation of fluorescent light and reflected light (see FIG. 10) is also the same as in the first embodiment (see FIG. 2), and the description is omitted. Operation for infrared light is described below.

First, referring to FIG. 9, infrared light is generated from the infrared light source 6, collimated by the collimating lens L4, reflected by the dichroic mirror M2, directed toward the dichroic mirror M1, reflected by the dichroic mirror M1, Head to the sentinel lymph node SLN. Although the infrared light passes through the coating TF2 of the objective lens L1, it is absorbed by the objective lens L1 and the temperature of the objective lens L1 rises. Infrared light is reflected by coating TF1 of objective lens L1 and is not directed to sentinel lymph node SLN. The infrared light reflected by the coating TF1 of the objective lens L1 is absorbed by the objective lens L1, further increasing the temperature of the objective lens L1. A part of the infrared light reflected by the coating TF1 of the objective lens L1 is not absorbed by the objective lens L1 and travels toward the fluorescence transmission optical fiber 246, but cannot pass through the bandpass filter F1. It does not enter the optical fiber 246 .

According to the fifth embodiment, dew condensation on the objective lens L1 can be prevented. The abdominal cavity in which the endoscope 2 is used has a temperature of 36° C. and a humidity of 100%. If the temperature of the objective lens L1 falls below the dew point (approximately 36° C.), dew condensation will occur on the objective lens L1. Therefore, by warming the objective lens L1 with infrared light, dew condensation on the objective lens L1 can be prevented.

Note that coating TF1 prevents infrared light from going toward the sentinel lymph node SLN, thereby preventing side effects (such as damage to the sentinel lymph node SLN) due to infrared light. In addition, the coating TF1 allows infrared light to reciprocate through the objective lens L1, so that the temperature of the objective lens L1 can be raised to a higher level. Furthermore, since the objective lens L1 does not need to be provided with electrical wiring for warming the objective lens L1, the cost of the lens holding tubular body (objective lens L1 and tubular body 244) can be reduced.

1 fluorescence measurement device 4 spectroscope (fluorescence measurement unit)
6 infrared light source SLN sentinel lymph node (irradiation target)
L length of cylindrical body 244 2 endoscope 22 light source unit 22a excitation light source 22b visible light source 22c, 22d single mode fiber 22e WDM coupler (multiplexer)
22e1 polarization-maintaining WDM coupler (multiplexer)
22f, 22g polarization maintaining fiber 22h single mode fiber (optical fiber for pumping light transmission)
22i single mode fiber 22j, 22k polarization controller 22m optical fiber 22m1 polarization maintaining fiber 220 excitation light source 222 fiber laser 224 PPLN (wavelength conversion element)
246 Optical fiber for fluorescence transmission 248 Optical fiber for infrared transmission 24 Scope section 242 Connector 242a, 242b, 242c, 242e Opening 242d End for connection 244 Cylindrical body 246 Optical fiber for fluorescence transmission L1 Objective lens L2 For fluorescence transmission Lens L3 Collimating lens (collimating part)
L4 collimating lens M1, M2 dichroic mirror F1 bandpass filter PBS1 first polarizer PBS2 second polarizer

Claims (12)

an excitation light source that generates excitation light;
an objective lens that receives fluorescence generated when an irradiation target receives the excitation light;
a cylindrical body that holds the objective lens;
an infrared light source that generates infrared light;
with
The objective lens is arranged inside the tubular body at a central portion of the tubular body,
When the length of the cylindrical body is L, the central portion is a region of L / 3 or more and 2 L / 3 or less from the end of the cylindrical body on the irradiation target side,
the objective lens absorbs the infrared light,
An endoscope comprising a coating that reflects the infrared light and transmits the excitation light and the fluorescence on the surface of the objective lens on the irradiation target side . The endoscope according to claim 1,
An endoscope comprising a collimator for collimating the excitation light. The endoscope according to claim 1,
a visible light source that generates visible light;
a combiner for combining the visible light and the excitation light;
endoscope with. The endoscope according to claim 2,
the collimator is a lens,
An endoscope comprising a mirror for changing the traveling direction of the excitation light transmitted through the collimator to the direction toward the irradiation target. The endoscope according to claim 1,
a first polarizer that transmits the excitation light;
a second polarizer that transmits the fluorescence;
with
An endoscope in which the transmission axis of the first polarizer and the transmission axis of the second polarizer are orthogonal. An endoscope according to claim 5 ,
A polarization-maintaining fiber that receives the excitation light and provides it to the first polarizer,
An endoscope in which the slow axis or fast axis of the polarization-maintaining fiber and the transmission axis of the first polarizer are aligned. The endoscope according to claim 6 ,
An endoscope wherein the excitation light source comprises a fiber laser. An endoscope according to claim 7 ,
The endoscope, wherein the excitation light source further includes a wavelength conversion element for converting the wavelength of the fiber laser. An endoscope according to claim 5 ,
an optical fiber for pumping light transmission, which is a single-mode fiber that transmits the pumping light;
receiving the pumping light transmitted by the pumping light transmitting optical fiber, and polarizing the pumping light to the first polarizer by making the direction of the normal to the plane of polarization of the pumping light orthogonal to the transmission axis of the first polarizer a wave controller;
endoscope with. The endoscope according to claim 1,
a fluorescence transmission optical fiber that transmits the fluorescence transmitted through the objective lens;
a fluorescence transmission lens that receives the fluorescence transmitted through the objective lens and applies it to one end of the fluorescence transmission optical fiber;
endoscope with. The endoscope according to claim 1,
An endoscope, wherein the lens arranged inside the cylindrical body is only one of the objective lenses. an endoscope according to any one of claims 1 to 11 ;
a fluorescence measurement unit that measures the fluorescence transmitted through the objective lens;
A fluorometer with

Images