JP5117976B2 - Imaging device - Google Patents

Description

  The present invention relates to an imaging apparatus that receives light from a labeled target substance distributed in a living body and generates an image.

  2. Description of the Related Art Conventionally, apparatuses that place a subject in a casing and shoot the subject by irradiating a living body with a light source provided in the casing have been used in various fields. In the fields of biochemistry and molecular biology, chemiluminescent substances and fluorescent substances are used as labeling substances, and by reading these luminescence and fluorescence, gene sequences, gene expression levels, protein separation, identification, or molecular weight There are known imaging apparatuses that perform characteristic evaluation and the like.

  In addition, a gene, protein, antibody, or pharmacological substance labeled with the above-described labeling substance is given to a living body such as a mouse or rat, and light from the labeling substance distributed in the body or body surface of the living body is photographed with a camera. 2. Description of the Related Art An imaging apparatus that performs so-called in vivo imaging for imaging gene expression, pharmacological action, and the like is known (for example, see Patent Document 1). In this photographing apparatus, for example, when labeling is performed with a fluorescent substance, the living body is irradiated with excitation light to excite the fluorescent substance, and the generated fluorescence is received by a camera to generate an image.

  In a conventional photographing apparatus, a halogen lamp, a white LED, or the like is used as a light source of excitation light, but the present applicant is considering using an inexpensive UV (ultraviolet) light source. When this UV light source is used, it is necessary to convert UV light (light having a wavelength in the ultraviolet region) generated by the UV light source into excitation light that is fluorescence of visible light or near infrared light. Therefore, as means for converting UV light into fluorescence, as described in Patent Documents 1 to 3, a wavelength conversion filter that converts UV light into visible light and a wavelength conversion material such as a phosphor are provided in the UV light source. The configuration is known.

US Pat. No. 5,736,744 JP-A-10-319877 Japanese Patent Laid-Open No. 2002-23160

  On the other hand, when exciting light by irradiating a living body with excitation light, the wavelength to be excited differs depending on the type of the living body and the fluorescent substance. Furthermore, since a plurality of types of fluorescent substances may be labeled on one living body, it is necessary to selectively irradiate a plurality of types of fluorescence accordingly. However, the above-mentioned Patent Document 1 is configured to include only one wavelength conversion filter that converts UV light into one type of visible light, and Patent Documents 2 and 3 include a plurality of wavelength conversion materials. It is not a configuration for selectively irradiating the fluorescence of the species, and there is no description suggesting this.

  The present invention has been made in view of the above-described problems, and the living body uses, as excitation light, one type selected from UV light irradiated from a UV light source and a plurality of excitation lights obtained by wavelength-converting the UV light. An object of the present invention is to provide an imaging device capable of irradiation.

In order to achieve the above-described problem, an imaging device that generates an image by irradiating a living body with excitation light to excite a fluorescent substance and receiving the generated fluorescence with a camera, a UV light source that emits UV light, A housing in which the UV light source is arranged and an opening for irradiating the living body with the UV light is formed. The housing is positioned above the opening, and converts the UV light into the excitation light to the living body. A plurality of wavelength conversion filters provided movably between a wavelength conversion position to be irradiated and a retreat position retracted from the wavelength conversion position, and a band-shaped wavelength conversion in which the wavelength conversion filters are arranged in the longitudinal direction. A wavelength conversion film is selectively positioned at the wavelength conversion position by winding and transferring the wavelength conversion film . The camera in the present invention may be any camera that generates an image from received fluorescence, such as a camera equipped with an image sensor such as a solid-state image sensor or a photographic camera that forms an image on a photographic film. Moreover, as excitation light which a wavelength conversion filter converts, visible light and near-infrared light are preferable.

Also, the wavelength conversion film, a plurality of areas arranged side by side along the longitudinal direction, the red fluorescence, green fluorescence, transparent filter that transmits without the wavelength conversion filter for converting each green fluorescence, and wavelength conversion Are preferably provided.

  An imaging apparatus according to the present invention is an imaging device that generates an image by irradiating a living body with excitation light to excite a fluorescent substance and receiving the generated fluorescence with a camera, and includes a UV light source that emits UV light, The UV light source is disposed in a housing having an opening for irradiating the living body with the UV light, and located above the opening, and the UV light is converted into the excitation light to irradiate the living body. A plurality of wavelength conversion filters provided movably between a wavelength conversion position to be moved and a retreat position retracted from the wavelength conversion position, and any one of the wavelength conversion filters provided on the housing. A switch that is pressed by the weight of the wavelength conversion filter when in position, and the type of the wavelength conversion filter is recognized by turning on and off the switch. .

  An imaging apparatus according to the present invention is an imaging device that generates an image by irradiating a living body with excitation light to excite a fluorescent substance and receiving the generated fluorescence with a camera, and includes a UV light source that emits UV light, The UV light source is disposed in a housing having an opening for irradiating the living body with the UV light, and located above the opening, and the UV light is converted into the excitation light to irradiate the living body. And a plurality of wavelength conversion filters provided movably between a wavelength conversion position to be moved and a retreat position retracted from the wavelength conversion position, and each wavelength conversion filter is provided with unique information of the wavelength conversion filter. It is characterized by comprising stored storage means and reading means for reading and recognizing the unique information from the storage means of the wavelength conversion filter at the wavelength conversion position.

According to the present invention, by winding and transporting a band-shaped wavelength conversion film in which a plurality of wavelength conversion filters that convert UV light into excitation light and irradiate a living body are arranged along the longitudinal direction, The wavelength conversion filter is selectively located at a wavelength conversion position. When any one of the wavelength conversion filters is at the wavelength conversion position, the type of the wavelength conversion filter is recognized by turning on and off the switch pressed by the weight of the wavelength conversion filter. Furthermore, the unique information is read and recognized from the storage means storing the unique information of the wavelength conversion filter at the wavelength conversion position. Thereby, it is possible to irradiate the living body with one type selected from the UV light irradiated from the UV light source and a plurality of excitation lights obtained by wavelength-converting the UV light as the excitation light.

  FIG. 1 shows the appearance of a photographing system embodying the present invention. The imaging system 2 receives light from a labeling substance distributed on the body surface of a living body 3 (see FIG. 2) such as a mouse or a rat (see FIG. 2) or a labeling substance distributed in the body (hereinafter referred to as an image of the labeling substance distributed on the living body 3) (Distributed image) is taken (generated) and displayed. In this embodiment, a case where a fluorescent substance that emits fluorescence by irradiating excitation light as a labeling substance is administered to the living body 3 and a distribution image of the fluorescent substance distributed in the living body 3 is generated will be described. The same applies to the case of generating a distribution image of a tissue that emits, for example, a tumor tissue.

  The photographing system 2 generates a distribution image, performs various settings on the photographing device 5 and performs various image processing on the distribution image generated by the photographing device 5 and displays the distribution image on the monitor 6a. It is composed of a PC (Personal Computer) 6 that performs recording on a medium. The PC 6 realizes a setting function, an image processing function, and the like for the photographing apparatus 5 by installing predetermined software.

  In FIG. 2, the photographing apparatus 5 includes a housing 11, a camera unit 12, a photographing stage 13, an upper light source 14, and a bottom light source 15. The casing 11 has a hollow, substantially rectangular parallelepiped shape, and is provided with a lid 16 (see FIG. 1) attached to the front face so as to be freely opened and closed. When the lid 16 is opened, the imaging room 17 provided inside the housing 11 is exposed so that the living body 3 can be accommodated, and the living body 3 can be taken out from the imaging room 17. When the lid 16 is closed, the inside of the photographing room 17 is shielded, and light other than fluorescence emitted from the living body 3 is prevented from entering the camera unit 12 during photographing.

  The imaging room 17 is provided with a camera unit 12 at the top. The camera unit 12 generates a distribution image of the living body 3 set on the imaging stage 13. The camera unit 12 includes an image sensor 18, a photographing lens 19, a camera side filter 20, a cooling unit 21, and the like. The image sensor 18 is the same as that used in a digital camera or the like, and a large number of light receiving elements are arranged in a matrix on the light receiving surface thereof. Specifically, a solid-state imaging device such as a CCD is used as the image sensor 18.

  In the case of generating a distribution image, as will be described later, the image sensor 18 is maintained in a state where photoelectric conversion is performed by a light receiving element and charges are accumulated, while fluorescence is received from a fluorescent substance, and the light is used as charges. Exposure is performed by accumulating.

  The taking lens 19 images the fluorescence from the living body 3 on the image sensor 18. The camera-side filter 20 is a filter that blocks excitation light from the upper light source 14 and the bottom light source 15 and transmits fluorescence from the fluorescent material distributed in the living body 3. As the camera-side filter 20, for example, a long-pass filter that cuts light having a shorter wavelength than the fluorescence from the fluorescent material is used, and only the fluorescence from the living body 3 is received by the image sensor 18. The cooling unit 21 reduces the dark current by cooling the image sensor 18 and suppresses noise in the generated distribution image.

  As the image sensor 18, various types such as a CCD type and a CMOS type can be used. Further, an image sensor using an organic photoelectric conversion film may be used in addition to a semiconductor that performs photoelectric conversion. Further, not only a single color but also a received light may be separated into a plurality of colors and photographed. The image sensor 18 is driven by the driver 23 under the control of the timing control unit 22.

  A shooting stage 13 is arranged directly below the camera unit 12. The photographing stage 13 has a box shape including a transparent stage plate 24 on which the living body 3 is placed and a lower housing 25. A bottom light source 15 is disposed in the hollow interior of the photographing stage 13.

  An upper light source 14 is disposed obliquely above the photographing stage 13. The upper light source 14 and the bottom light source 15 are excitation light sources that irradiate the living body 3 with excitation light for exciting and emitting the fluorescent material distributed in the living body 3. Various light sources such as a halogen lamp, a strobe discharge tube, a laser, and a light emitting diode can be used as the upper light source 14, but in this example, the wavelength range of the fluorescence from the white LED and the fluorescent material and a longer wavelength than that. It is composed of a short pass filter or the like that cuts the side light.

  The upper light source 14 is a so-called epi-illumination type excitation light source, which emits excitation light from the upper side of the living body 3, and the bottom light source 15 irradiates excitation light from the lower side of the living body 3. The upper light source 14 and the bottom light source 15 are driven by the corresponding upper light source driver 26 and bottom light source driver 27, respectively, under the control of the timing control unit 22.

  FIG. 3 shows the configuration of the imaging stage 13 and the bottom light source 15. The present invention uses a UV (ultraviolet) light source as the bottom light source 15. The UV light source emits UV light (light having a wavelength in the ultraviolet region). The housing 25 has a hollow box shape and is formed with an opening 25a penetrating the upper surface. A transparent stage plate 24 on which the living body 3 is placed is fitted into the opening 25a.

  The transparent stage plate 24 is made of, for example, quartz glass or plastic. The UV light emitted from the bottom light source 15 passes through the opening 25a, that is, the transparent stage plate 24, and is irradiated to the living body 3. The housing 25 is opaque so as to block the UV light from the bottom light source 15 and prevents UV light from being emitted from other than the transparent stage plate 24.

  The housing 25 is provided with wavelength conversion filters 28 to 30 and recognition switches 31 and 32. The wavelength conversion filters 28 to 30 convert the UV light emitted from the bottom light source 15 into red, blue, and green fluorescence, respectively. In the present embodiment, the UV light is directly used as excitation light without wavelength conversion, along with red, blue, and green fluorescence obtained by wavelength conversion of the UV light.

  The bottom light source 15 has a configuration shown in detail in FIG. The bottom light source 15 includes a plurality of UV fluorescent lamps 40, a reflecting plate 41, a connector 42, an exhaust fan 43, and a frame 44 that supports them. The UV fluorescent lamps 40 are arranged in parallel to each other, and a reflection plate 41 is disposed below. The reflection plate 41 is a reflection member that reflects the UV light emitted from the UV fluorescent lamp 40 upward. Thereby, the UV light emitted from the UV fluorescent lamp 40 is irradiated toward the upper transparent stage plate 24.

  The connector 42 is connected to the socket of the UV fluorescent lamp 40 and to the bottom light source driver 27 and the cable. A drive signal from the bottom light source driver 27 based on the control of the timing control unit 22 is sent to the UV fluorescent lamp 40 via the connector 42. The frame 44 has a rectangular frame shape surrounding the UV fluorescent lamp 40. A vent hole 44a is formed at a position facing the peripheral surface of the UV fluorescent lamp 40, and an exhaust fan 43 is disposed on the opposite side of the vent hole 44a. Has been. The outside air sucked from the vent hole 44a passes around the UV fluorescent lamp 40 and is discharged from the exhaust fan to cool the UV fluorescent lamp 40.

  Returning to FIG. 3, the wavelength conversion filters 28 to 30 are attached to the housing 25 via rotation shafts 28 a, 29 a, and 30 a, respectively. These wavelength conversion filters 28 to 30 have rigidity, are positioned above the transparent stage plate 24, convert UV light into red, blue, and green fluorescence (excitation light), respectively, and irradiate the living body. The rotary shafts 28a, 29a, and 30a are rotatable around the wavelength conversion position and the retracted position retracted from the wavelength conversion position. The rotary shafts 28 a, 29 a, and 30 a are attached to three different sides among the four sides that form the top plate of the housing 25. Accordingly, the wavelength conversion filters 28 to 30 are similarly positioned above the transparent stage plate 24 at the wavelength conversion position, but rotate in different directions around the rotation shafts 28a, 29a, and 30a, and are retracted differently. Move to position (state shown in FIG. 3).

The wavelength conversion filters 28 to 30 are formed by dispersing red, blue, and green fluorescent pigments and fluorescent dyes in a transparent material that transmits UV light, such as quartz glass and plastic materials. Specific examples of fluorescent pigments and fluorescent dyes include the phosphors described in Patent Document 2 above. For example, Y ₂ O ₂ S: Eu, which emits red light, emits blue light. as it shall become the, (Sr, Ca, Ba, Eu) 10 (PO 4) 6 · Cl 2, as those resulting green light emission, 3 (Ba, Mg, Eu , Mn) O · 8Al 2 O 3 , etc. Can be mentioned. Organic phosphors can also be used. Alternatively, rhodamine (RHODAMINE640), coumarin (COUMARIN540A, COUMARIN460) and the like can also be used.

  Further, the wavelength conversion filters 28 and 29 are provided with cutout portions 28b and 29b at positions corresponding to the recognition switches 31 and 32, respectively, so that the wavelength conversion filters 28 to 30 are recognized by the recognition switches 31 and 32 described later. Used for.

  The recognition switches 31 and 32 are disposed on the top surface of the housing 25 and in the vicinity of the transparent stage plate 24. The recognition switches 31 and 32 are turned on when pressed on the top surface and pressed into the housing 25, and released from the press to protrude from the housing 25. Then it turns off. The PC 6 recognizes one of the wavelength conversion filters 28 to 30 set at the wavelength conversion position based on the on / off signal output from the recognition switches 31 and 32. Table 1 below shows recognition patterns of the wavelength conversion filters 28 to 30 that are determined by the PC 6.

  As shown in Table 1 and FIG. 5A, when the wavelength conversion filter 28 for red fluorescent light is set at the wavelength conversion position, the notch 28b avoids the recognition switch 31, so that the recognition switch 31 is pressed. The recognition switch 32 is turned on by its own weight of the wavelength conversion filter 28. As shown in FIG. 5B, when the blue fluorescent wavelength conversion filter 29 is set at the wavelength conversion position, the recognition switch 31 is turned on by its own weight, and the recognition switch 32 is turned off. It is avoided by the notch 29b and turned off without being pressed. As shown in FIG. 5C, when the green fluorescence wavelength conversion filter 30 is set at the wavelength conversion position, the recognition switches 31 and 32 are both turned on by the weight of the wavelength conversion filter 30. Furthermore, when none of the wavelength conversion filters 28 to 30 is set at the wavelength selection position, the recognition switches 31 and 32 are both turned off. In this way, the on / off signals of the recognition switches 31 and 32 are output, and the PC 6 can recognize the types of the wavelength conversion filters 28 to 30. When the PC 6 recognizes the type of the wavelength conversion filters 28 to 30 based on the on / off signals of the recognition switches 31 and 32, any one of red, blue, and green fluorescence corresponding to the recognized type of the wavelength conversion filters 28 to 30 is biological. 3, or when none of the wavelength conversion filters 28 to 30 is recognized, the monitor displays that the living body 3 is irradiated with UV light.

  Next, the operation of the above configuration will be described. First, the user opens the lid 16 and selects one of the wavelength conversion filters 28 to 30 so as to correspond to the excitation light suitable for observation, or sets the wavelength conversion position at the wavelength conversion position, or the wavelength conversion filter 28. It is set as the state which none of 30 is set. Then, the living body 3 pre-administered with the fluorescent substance is placed on the imaging stage 13 on the imaging stage in which any one of the wavelength conversion filters 28 to 30 is set or in a state where none of them is set. After the user closes the lid 16 and the photographing room 17 is in a light-shielded state, the user operates the PC 6 to select and set which of the upper light source 14 and the bottom light source 15 is used, and instructs to start photographing. Hereinafter, a case where the bottom light source 15 according to the present invention is selected will be described in detail. When the start of photographing is instructed, the timing control unit 22 sends an exposure start signal to the driver 23 and activates the recognition switches 31 and 32 to output one of on / off signals.

  When the driver 23 receives the exposure start signal, the image sensor 18 starts to operate, and the light received by each light receiving element is photoelectrically converted into electric charge and accumulated. On the other hand, the timing control unit 22 starts processing for generating a timing signal. Each timing signal generated in this process is sequentially sent to the driver of the selected light source. When the selected light source is the bottom light source 15, each timing signal is sequentially sent to the bottom light source driver 27.

  When the timing signal is input to the bottom light source driver 27, the bottom light source 15 is turned on in response to the input of the timing signal, and UV light is emitted. The UV light emitted from the bottom light source 15 passes through any one of the wavelength conversion filters 28 to 30 and is wavelength-converted into one of red, blue, and green fluorescence, or the wavelength of UV light is not converted. The living body 3 is irradiated as excitation light. Then, the fluorescence emitted from the fluorescent material by the irradiation is received by the image sensor 18 through the camera-side filter 20 and the photographic lens 19, and the charge due to the received light is gradually accumulated. The charge accumulated in the image sensor 18 is photoelectrically converted to generate an image, which is sent to the PC 6. At this time, the PC 6 displays an image photographed by the image sensor 18 on the monitor, and at the same time, the type of the wavelength conversion filters 28 to 30 set on the photographing stage by the ON / OFF signals of the recognition switches 31 and 32, or the wavelength conversion filter 28. Recognizing that none of -30 is set, it is displayed on the monitor that any one of red, blue and green fluorescence or UV light corresponding to this recognition is being used as excitation light.

  As described above, the living body 3 is irradiated with one selected from the plurality of fluorescences obtained by wavelength conversion of the UV light emitted from the bottom light source 15 by the wavelength conversion filters 28 to 30 and the UV light not subjected to wavelength conversion as excitation light. be able to. Thereby, the excitation light most suitable for the labeling substance of the living body 3 is selected to generate fluorescence, and a clear observation image from the living body 3 can be obtained. Further, since the user can observe the living body 3 by displaying on the monitor and can confirm the type of excitation light being used, the imaging device can be used when a desired result cannot be obtained depending on the observation content or the sharpness of the image. 5 is stopped once, and the selection of the wavelength conversion filters 28 to 30 is changed, or the observation with the excitation light different from the previous one is performed only by changing to the state where none of the wavelength conversion filters 28 to 30 is set. Can do.

  In the above-described embodiment, a plurality of wavelength conversion filters 28 to 30 are rotatably attached to the housing 25, and either one is set at the wavelength conversion position, or none is set in the excitation state. Although the structure which changes the kind of light is illustrated, it is not restricted to this, In 2nd Embodiment of this invention demonstrated below, the wavelength conversion filter provided along with the longitudinal direction of the strip | belt-shaped wavelength conversion film was provided. And the structure which moves the transparent filter and changes the kind of excitation light is shown. A bottom light source and an imaging stage to which this configuration is applied are shown in FIG. In addition, in FIG. 6, what uses the same components and member as the said embodiment attaches | subjects the same code | symbol, and abbreviate | omits description. In this case, the imaging stage 50 includes a transparent stage plate 24, a housing 25, a wavelength conversion film 51, and winding rollers 52a and 52b.

  The wavelength conversion film 51 has a band shape with a width dimension matched to the transparent stage plate 24, and converts into red fluorescence, blue fluorescence, and green fluorescence in a plurality of areas arranged side by side along the longitudinal direction. 55 and a transparent filter 56 that transmits UV light without wavelength conversion, and both ends thereof are fixed to the winding rollers 52a and 52b. The areas of the wavelength conversion filters 53 to 55 and the transparent filter 56 are each sized according to the transparent stage plate 24. The wavelength conversion filter is formed by applying a red, blue, or green fluorescent pigment or fluorescent dye to a transparent material that transmits UV light, for example, a plastic film. The fluorescent pigment or fluorescent dye is the same as that used in the first embodiment.

  By rotating the winding rollers 52a and 52b, the wavelength conversion film is wound and transferred, and any one of the wavelength conversion filters 53 to 55 and the transparent filter 56 is set at the wavelength conversion position on the transparent stage plate 24, The other wavelength conversion filters 53 to 55 and the transparent filter 56 are retracted positions that are retracted from the wavelength conversion position. By adopting such a configuration, the living body 3 is selected by the user selecting either one of the fluorescence wavelength-converted by the wavelength conversion filters 53 to 55 or the UV light that is transmitted without being wavelength-converted by the transparent filter 56. Can be irradiated as excitation light.

  In the above embodiment, the type of the wavelength conversion filter is recognized by the notch and the switch formed in the wavelength conversion filter, but the present invention is not limited to this, as shown in FIG. The plurality of wavelength conversion filters 60 are provided with storage means for storing respective unique information, for example, an IC tag 61, and the imaging stage 62 is provided with a tag reader 63 as reading means. The IC tag 61 is in a position where it can be read by the tag reader 63 when the wavelength conversion filter 60 is at the wavelength conversion position on the transparent stage plate 24, and the tag reader 63 that has read the specific information of the wavelength conversion filter 60 from the IC tag 61 is The unique information can be sent to the PC 6 to recognize the type of the wavelength conversion filter 60. When the IC tag 61 cannot be read, it may be recognized that none of the wavelength conversion filters is set at the wavelength conversion position.

  In the above-described embodiment, the wavelength conversion filter enumerates a configuration for converting UV light into red, blue, and green fluorescence. However, the present invention is not limited to this, and UV light other than red, blue, and green fluorescence is listed. It may be converted into visible light or near infrared light. Moreover, although the structure which applied this invention to the top light source is enumerated, you may apply not only to this but to a bottom light source. Further, although the UV fluorescent lamp 40 is used as the UV light source, the present invention is not limited to this, and a semiconductor light emitting element that emits UV light may be used.

  In the above-described embodiment, the configuration of a camera provided with an image sensor is exemplified as a camera used in the photographing apparatus. However, the present invention is not limited to this, and a photographic camera that generates an image on received photographic film on a photographic film is provided. It may be used.

It is a perspective view which shows the structure of the imaging | photography system which implemented this invention. It is a block diagram which shows the outline of a structure of an imaging device. It is a perspective view which shows the structure of an imaging | photography stage and a light source. It is a perspective view which shows the structure of a light source. It is explanatory drawing which shows the recognition pattern of a wavelength conversion filter. It is a perspective view which shows the structure of the imaging | photography stage and light source of 2nd Embodiment. It is a perspective view which shows an example provided with the reading means which reads the specific information of a wavelength conversion filter.

Explanation of symbols

DESCRIPTION OF SYMBOLS 2 Imaging system 3 Living body 5 Imaging device 12 Camera part 13,50 Imaging stage 14 Upper light source 15 Bottom light source 28-30, 53-55 Wavelength conversion filter 31, 32 Recognition switch 51 Wavelength conversion film 52a, 52b Winding roller

Claims (4)

An imaging device that generates an image by irradiating a living body with excitation light to excite a fluorescent substance and receiving the generated fluorescence with a camera,
A UV light source that emits UV light, a housing in which the UV light source is arranged, and an opening for irradiating the living body with the UV light is formed;
A plurality of positions provided above the opening and movably provided between a wavelength conversion position for converting the UV light into the excitation light and irradiating the living body, and a retreat position for retreating from the wavelength conversion position and the wavelength conversion filter,
A band-shaped wavelength conversion film provided with the wavelength conversion filters arranged along a longitudinal direction, and the wavelength conversion film is selectively transferred to the wavelength conversion position by winding and transferring the wavelength conversion film. An imaging device characterized by being located in The wavelength conversion film is provided with a plurality of areas arranged side by side along the longitudinal direction, the wavelength conversion filter that converts red fluorescence, blue fluorescence, and green fluorescence, respectively, and a transparent filter that transmits without wavelength conversion. The photographing apparatus according to claim 1 , wherein the photographing apparatus is provided.   An imaging device that generates an image by irradiating a living body with excitation light to excite a fluorescent substance and receiving the generated fluorescence with a camera,
  A UV light source that emits UV light, a housing in which the UV light source is arranged, and an opening for irradiating the living body with the UV light is formed;
  A plurality of positions provided above the opening and movably provided between a wavelength conversion position for converting the UV light into the excitation light and irradiating the living body, and a retreat position for retreating from the wavelength conversion position A wavelength conversion filter of
  A switch that is provided on the housing and is pressed by the weight of the wavelength conversion filter when any one of the wavelength conversion filters is in the wavelength conversion position. An imaging device characterized by recognizing the image.   An imaging device that generates an image by irradiating a living body with excitation light to excite a fluorescent substance and receiving the generated fluorescence with a camera,
  A UV light source that emits UV light, a housing in which the UV light source is arranged, and an opening for irradiating the living body with the UV light is formed;
  A plurality of positions provided above the opening and movably provided between a wavelength conversion position for converting the UV light into the excitation light and irradiating the living body, and a retreat position for retreating from the wavelength conversion position A wavelength conversion filter of
  Storage means provided in the wavelength conversion filter, each storing unique information of the wavelength conversion filter,
  An imaging apparatus comprising: a reading unit that reads and recognizes the unique information from the storage unit of the wavelength conversion filter at the wavelength conversion position.

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