JP2008212717A - Body region illuminator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a body region illuminator which is easy to handle in regard to usage and maintenance, and which emits light in a tubule by being inserted into the tubule in the living body, so that an image of an illuminated region obtained from an endoscope or the like inserted into a body cavity can be visually recognized via a monitor, in terms of the position of the tubule and a traveling state, or so that a doctor or the like can visually recognize an illuminated region of a patient subjected to ventrotomy, by his/her naked eyes. <P>SOLUTION: This body region illuminator 1f which is designed to be inserted into and illuminate the tubule in the living body has: a main body 18 which is composed of a hollow or solid flexible light-transmittable tubular body with both sealed ends; at least one light emitting part 3 which is provided inside the main body; and electric light-emitting means 13 which makes the light emitting part emit light. The electric light-emitting means includes a semiconductor light-emitting element 16 as a light source, and a power source 14 and a power supply circuit 17 for supplying power to the semiconductor light-emitting element. A disposable power supply circuit is equipped with an irreversible switch 15 which disables disconnection once it is connected to the power source. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an in-vivo site light-emitting device that is inserted into a tubule in a human body or animal body to facilitate visual recognition of the position and running state of the tubule in a medical or veterinary field.

In general, in a laparotomy usually performed in abdominal surgery, doctors and veterinarians visually confirm or palpate the position of tubules in the body. The position and running state of a blood vessel can be visually confirmed by using a contrast medium, but tubules other than blood vessels are difficult to visually recognize. In particular, the ureter is mainly confirmed by palpation. In recent years, laparoscopic surgery that is minimally invasive has been performed in place of open surgery. In this laparoscopic surgery, an endoscope is inserted through a small hole opened in the affected area, and information on the body cavity from the endoscope is displayed on the monitor as an image. Do surgery.
Even in open surgery, in the case of a ureter with poor adhesion, skill is required for doctors and veterinarians to check the position and running state, but laparoscopic surgery is performed by judging from the monitor screen If there is not enough information to determine the position and running state of tubules such as ureters and fallopian tubes, doctors may be more advanced than laparotomy because there is a concern of damaging these tubules. Technology is required. In view of this, in order to perform these operations safely and reliably, an apparatus has been devised in which the position and running state of a thin tube in a living body can be easily visually confirmed.

For example, in Patent Document 1, a luminescent urine composed of a light source installed outside the body under the name of “luminescent ureteral probe” and a light guide fiber that is connected to the light source and includes a core layer and a clad layer and includes a light emitting portion. An invention relating to a tube probe is disclosed.
In the invention disclosed in Patent Document 1, when the light guide fiber is inserted into the ureter, the light guide fiber emits light by light from the light source, and the ureter appears to emit light from outside the body. Can be accurately viewed. The light guide fiber is composed of a core layer and a clad layer, and has a tip portion that is divided into two in the middle so that it can be inserted into both ureters via the urethra. Light from the power source is totally reflected by the core layer of the light guide fiber and guided to the tip, and leaks out from a groove provided in the cladding layer at the tip. The shape of the groove can be linear, spiral, or ring-shaped, and when the number of the grooves is increased, the amount of light leaking from the groove increases, making it easier to see from outside the body. It is said. Furthermore, when the groove area is formed so as to gradually increase from the light source toward the tip, the light emission state can be stably maintained without a decrease in the amount of light at the tip.

Patent Document 2 discloses, under the name “illuminator”, an insertion portion that can be inserted into a body cavity and includes a light emitting portion, a connector that is installed at a proximal end portion of the insertion portion and can be connected to illumination supply means, and an insertion portion. The invention relating to an illuminator is disclosed, which is comprised of a light transmission means which is installed in the light transmission means and transmits light from the illumination supply means to the light emitting section through a connector.
In the invention disclosed in Patent Document 2, when a light emitting illuminator insertion portion is inserted into the ureter during laparoscopic surgery, the urinary tract of the ureter appears bright and shiny in the abdominal cavity. The tube is not damaged.
The insertion portion is formed in the order of the core, the clad, and the outer skin from the central portion, and the optical transmission means is constituted by the core and the clad. The light supplied through the connector from the illumination supply means is transmitted to the tip side while being reflected at the interface between the core and the cladding, but a part of the transmitted light is not reflected but leaks out of the cladding and is transparent. The light is transmitted through the outer shell and leaks out of the insertion portion, and the light emitting portion is configured by this leakage. In addition, since a flexible acrylic polymer is used for the core, the bending property is good and the insertion is easy, and it is said that the core is not damaged like a conventional glass fiber.
JP-A-10-43205 JP-A-11-244233

  However, in both of the conventional techniques described in Patent Document 1 and Patent Document 2, the position and running state of the ureter can be easily visually recognized, but a light source device is separately required, and this light source device is included. There is a problem that the entire apparatus becomes expensive. In addition, since the light guide fiber inserted into the patient is connected to the light source device, the doctor has a problem that the degree of freedom is reduced during the operation. Furthermore, since these devices are reused after sterilization, doctors must pay close attention to sterilization treatment and storage, and there is a concern that inadequate sterilization will cause infection. In the technique disclosed in Patent Document 2, since an acrylic polymer is used for the core, there is a low risk of breakage like a glass fiber, but there is still an insufficient bending property. Due to an error, there was a possibility of damaging the affected part (living body) through a body cavity such as the urethra.

  The present invention has been made in response to such conventional circumstances, and is easy to handle in use and management, and is inserted into a thin tube in a living body to emit light in the thin tube, and the position and running state of the thin tube are related. To provide an in-vivo site light-emitting device capable of visually recognizing an image of a light-emitting region obtained from an endoscope inserted into a body cavity through a monitor, or visually recognizing a light-emitting region of an opened patient with the naked eye of a doctor or the like With the goal.

In order to achieve the above object, an in-vivo site light-emitting device according to claim 1 is an in-vivo site light-emitting device that is inserted into a thin tube in a living body to emit light, and is sealed at both ends and is hollow or solid. A main body part made of a tubular body having flexibility and light transmission, at least one light emitting part provided in the main body part, and electric light emitting means for causing the light emitting part to emit light, The electric light emitting means includes a semiconductor light emitting element as a light source, a power source for supplying power to the semiconductor light emitting element, and a power supply circuit. The power supply circuit is irreversible that cannot be disconnected once connected to the power source. The switch is provided and is disposable.
In the in-vivo part light-emitting device having the above configuration, the light emitting part emits light by the electric light emitting means inside the main body part, and when the main body part is inserted into the narrow tube in the living body in this state, the thin tube appears to shine from inside the body cavity. There is an effect. Further, since the main body is flexible, it has the effect of bending and bending well. Furthermore, the light emitting unit has an effect that when power is supplied to the semiconductor light emitting element, the semiconductor light emitting element serves as a light source and emits light. The role of the irreversible switch has the effect of preventing interruption of the power supplied from the power source to the power supply circuit, enabling disposable use and preventing reuse of the light emitting unit.
In addition, in this claim, it is described as an in-vivo site light-emitting device that is inserted into a tubule in a living body and emits light. However, it does not mean that light is emitted after that, and either insertion or light emission may be performed first or later, and the time is not limited.

Further, the internal body light-emitting device according to the second aspect of the present invention is the internal-part light-emitting device according to the first aspect, wherein the power source of the electrical light emitting means is separated from the main body and is connected via the power supply circuit. It is connected to the main body.
In addition to the operation of the invention according to claim 1, the body part light-emitting device having the above-described configuration has an effect of making the main body part mainly inserted into the body compact by providing the power source part separately from the main body part.

Furthermore, the in-vivo body light-emitting device which is invention of Claim 3 WHEREIN: The internal-body light-emitting device of Claim 1 or Claim 2 is formed in the peripheral part of a main-body part, and the outer periphery smaller than the outer periphery of a main-body part. At least one constricted portion is provided.
In the in-vivo region light-emitting device having the above-described configuration, in addition to the operation of the invention according to claim 1 or 2, the main body portion has an operation of freely bending even at the constricted portion.

Finally, the in-vivo site light-emitting device according to claim 4 is an in-vivo site light-emitting device according to any one of claims 1 to 3, wherein the in-vivo site light-emitting device is connected to one end of the main body. The drawer part which consists of consists of.
In addition to the operation of the invention according to any one of claims 1 to 3, the in-vivo region light-emitting device having the above-described configuration has an effect that the main body portion is pulled out by the pull-out portion.

In the in-vivo site light-emitting device according to claim 1 of the present invention, when the main body portion is caused to emit light and inserted into a narrow tube such as a ureter in a living body, or after the main body portion is inserted into the thin tube, light is emitted from within the body cavity. Since tubules appear to shine, doctors and veterinarians can accurately see the position and running state of tubules in laparoscopic surgery, etc., and perform diagnosis and treatment safely and reliably without damaging the tubules be able to. Further, since the main body portion is flexible, it can be easily deformed along the shape of the narrow tube that bends in the body, and can be easily inserted into the narrow tube. And since the light emission part and the electroluminescent means are integrally formed, the connection of a light source and a light guide fiber becomes unnecessary like the conventional apparatus, and the freedom degree at the time of a doctor's operation can be improved.
In addition, by using a semiconductor light-emitting element that can be downsized and mounted, and that consumes less power, as a light-emitting light source, the body part light-emitting device maintains a necessary and sufficient amount of light emission while maintaining a small power supply unit. In addition, since the capacity can be easily adjusted while maintaining the light emission, it is possible to provide an economical apparatus with a simple configuration capable of maintaining the light emission even during a long-time operation.
Furthermore, since the irreversible switch prevents the power supply supplied from the power supply to the power supply circuit from being interrupted, the switch once turned on is not released, and the light emission by the electroluminescent means is not interrupted during the examination or treatment. . In addition, since the irreversible switch cannot be reused once it is used, it is possible to make the body part light emitting device more sanitary and eliminate the possibility of contamination infection.

  In the in-vivo body light-emitting device according to claim 2 of the present invention, by providing the power supply section apart from the main body section, the main body section, which is a section to be inserted into the body, can be further reduced in weight and inserted into a delicate section. Therefore, this weight reduction can further reduce the burden on the patient during the operation. Furthermore, because of the length of the wiring connecting the main body part and the power supply part, especially during the operation, the power supply part can be easily operated by a doctor or a veterinarian, such as an operating table or the skin of a patient (subject). By placing and sticking, it is possible to provide more ease of surgery.

  Furthermore, in the in-vivo body light-emitting device according to claim 3 of the present invention, since the main body portion is freely bent even at the constricted portion, the rigidity of the main body portion is adjusted, and the intubation into the bent narrow tube in the body is further performed. It can be done easily.

  Finally, in the in-vivo site light-emitting device according to claim 4 of the present invention, the in-vivo site light-emitting device inserted in the narrow tube in the living body can be easily taken out of the body by pulling the drawer connected to the main body. be able to.

In the following, the best embodiment of the internal body light-emitting device according to the present invention will be described with reference to FIGS.
FIG. 1 is a conceptual diagram of an internal body light-emitting device according to a first embodiment of the present invention.
In FIG. 1, an in-vivo site light-emitting device 1 a according to the present embodiment includes a tube 2 having flexibility and light transmission as a main body, a light emitting unit 3 provided therein, and light emission of the light emitting unit 3. It comprises two kinds of medicines 4 and 5 arranged as means and a partition wall 6 that separates these medicines 4 and 5.
The drug 4 is sealed in a plastic transparent container, and the drug 5 is sealed in an interior partitioned by a partition wall 6 such as a glass ampoule provided inside the transparent container. The medicine 4 and the medicine 5 are chemical substances that emit light when mixed, and the doctor or veterinarian bends the tube by hand before work, or breaks the partition wall 6 using a dedicated jig or existing tool. And the drug 5 can be mixed to generate light emission by a chemiluminescence reaction. The light from the light emitting unit 3 passes through the light-transmitting container in which the medicine 4 is sealed and the light-transmitting tube 2 to illuminate the entire outside of the tube 2.
For the drug 4, for example, a reactive substance such as an oxalic acid derivative and a fluorescent substance excited by the reaction of the reactive substance can be used, while for the drug 5, a catalyst, hydrogen peroxide, or the like can be used. . Of course, the components of the drug 4 and the drug 5 may be reversed. Further, the medicine 4 may be used as long as it can be directly enclosed in the tube 2 without being enclosed in a plastic light-transmitting container as described above.

As described above, in the first embodiment, when the light emitting unit 3 is made to emit light in advance and is inserted into a tubule such as a ureter or an oviduct in a living body, the in-vivo body light-emitting device 1 a Illuminated, the position of the tubule and the running state can be viewed through a monitor on the image of the luminescent part obtained from an endoscope inserted into the body cavity, or the luminescent part of the opened patient can be seen with the naked eye of a doctor or the like. Visible. Therefore, doctors can perform diagnosis and treatment safely and promptly without damaging the tubules in laparoscopic surgery or the like.
In addition, the light emitting means using the drugs 4 and 5 reach the maximum illuminance as soon as the light is emitted once, and if the current technology is used, the light emission can be continued for about 6 hours. Luminescence never stops. This luminescence reaction is a chemiluminescence phenomenon due to the mixing of drugs, and the light-emitting part 3 is not extinguished or re-emitted once emitted, and the in-vivo site light-emitting device 1a cannot be reused.
Therefore, by disposing the in-vivo site light-emitting device 1a in a disposable manner, it is possible to reliably prevent infections caused by poor sterilization treatment when reusing medical instruments. In addition, complicated sterilization treatment and management work can be eliminated, and the burden on doctors and veterinarians can be reduced. Furthermore, since the internal body light-emitting device 1a has a structure in which the tube 2 and the light-emitting unit 3 are integrated, it can be provided after being sterilized before use. In addition, the integrated structure eliminates the need for connection of a light guide fiber as in the conventional apparatus, and can ensure the degree of freedom during surgery by a doctor or the like. In addition, since a power supply circuit, a power supply, and the like are unnecessary, the configuration is simple and the cost of the apparatus can be reduced.
The tube 2 may have an outer diameter of 10 mm or less, preferably 6 mm or less in order to be easily inserted into a thin tube in a living body. In addition, since the tube 2 is flexible, it can be deformed along the shape of a narrow tube that is bent in the body and can be easily intubated. Further, both ends of the tube 2 are rounded, Finishing with a smooth finish increases safety.
The material of the tube 2 is not particularly limited as long as it is harmless to the living body. For example, general-purpose plastics such as polyethylene, polypropylene, nylon, Teflon (registered trademark), and silicon can be used. It is even more preferable if the material is high.
Further, the light emission time and illuminance of the light emitting means using the drugs 4 and 5 can be changed by adjusting the amounts of the drugs 4 and 5 in advance according to the purpose of use such as the type of target tubule and the operation to be performed. Therefore, it is preferable to prepare a light emitting means for which such adjustment is performed in advance.

Next, a first modification of the in-vivo region light-emitting device according to the first embodiment will be described as Example 1 with reference to FIG.
FIG. 2 is a conceptual diagram of the internal body light-emitting device according to the present embodiment. 2, the same parts as those shown in FIG. 1 are denoted by the same reference numerals, and the description of the configuration is omitted.
In FIG. 2, the in-vivo site light-emitting device 1 b has a structure in which a plurality of light-emitting units 3 each having a light-emitting means including drugs 4 and 5 and a partition wall 6 are arranged in a tube 2. It is divided. In this way, by having a structure including a plurality of light emitting units 3, even if a single failure of the light emitting unit 3 is covered by the illumination of the other light emitting units 3, the entire body part light emitting device 1 b can be prevented from malfunctioning. be able to. In addition, by forming the light emitting unit 3 in small portions, it is easy to enclose the drugs 4 and 5 in the tube 2 and the productivity can be improved. Moreover, by subdividing, the quantity of the whole chemical | medical agents 4 and 5 can be suppressed, and the cost reduction in a material surface can be aimed at.
Moreover, in the internal body light-emitting device 1b, although it is a structure which may produce the dispersion | variation in lightness among the some light emission parts 3, in-vivo site | part is used to illuminate the position or site | part of a thin tube in a living body, and its running state. What is required for the light emitting device 1b is light emission of the entire tube 2 and not light emission uniformity. Therefore, the variation in brightness between the light emitting portions 3 is not particularly problematic, but in order to emit light from the entire tube 2, the distance between the light emitting portions 3 may be 3 cm or less, preferably 1 cm or less. The length of the light emitting unit 3 may be 3 cm or less. The distance between the light emitting parts 3 means the part where the drugs 4 and 5 do not exist, that is, the thickness of the partition wall 7, and the length of the light emitting part 3 indicates the part where the drugs 4 and 5 exist, that is, the part. It means the distance between the wall 7 and the partition wall 7. The outer diameter of the tube 2 is the same as that described in FIG.

Next, a second modification of the in-vivo region light-emitting device according to the first embodiment will be described as Example 2 with reference to FIG.
FIG. 3 is a conceptual diagram of the internal body light-emitting device according to the present embodiment. In FIG. 3, the same parts as those shown in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted.
In FIG. 3, in the internal body light emitting device 1 c, a plurality of light emitting units 3 using the drug 4 and the drug 5 are installed, and the outer diameter of the tube 2 between the light emitting units 3 is the tube 2. A constriction 8 smaller than the outer diameter is formed. In these constricted portions 8, the tube 2 can be bent more freely. Therefore, since the in-vivo site light-emitting device 1c can be bent more easily along the shape of the narrow tube that is bent in the living body, there is an advantage that intubation is facilitated and the thin tube is not damaged. The intervals between the constrictions 8 do not have to be equal as shown in FIG. 3, and the constrictions 8 can be narrowed closer to the end on the inserted side or vice versa. . This interval may be determined so as to conform to the shape of the narrow tube.
Further, in the present embodiment shown in FIG. 3, the position of the medicine 2 is fixed using, for example, a solid light-transmitting and flexible resin as the tube 2 while the medicine 4 is sealed in a container such as a capsule. Therefore, it is not necessary to provide the partition wall 7. However, even the tube 2 having the constriction 8 shown in FIG. 3 may be hollow.
In the present application, not only the hollow tube 2 disclosed in FIGS. 1 and 2 but also the existence of the solid tube 2 disclosed in FIG. 3 is considered. This is considered to mean that the tube is essentially tubular and hollow, but in this application, when the drug is placed inside, the part of the drug is solid although the tube will be hollow. The wax is excluded from the tube material and the drug is present, and the portion is considered tubular. Therefore, the term tubular is a concept that includes not only a hollow tube but also a solid tube.

Next, a third modification of the in-vivo region light-emitting device according to the first embodiment will be described as Example 3 with reference to FIG.
FIG. 4 is a conceptual diagram of the internal body light-emitting device according to the present embodiment. 4, the same parts as those shown in FIG. 1 are denoted by the same reference numerals, and description of the configuration is omitted.
In FIG. 4, the in-vivo region light-emitting device 1 d has a structure in which a plurality of light emitting units 3 installed are connected by a connecting unit 9. Since the connecting portion 9 is thinner than the outer diameter of the tube 2, the in-vivo body light emitting device 1 d has high flexibility, and therefore, as in the case of the second embodiment, it is easy without damaging the bending narrow tube. Intubation can be performed.
In the present embodiment, the material of the tube 2 and the connecting portion 9 may be different, but the connectivity must be secured to such an extent that it can withstand the insertion work into the narrow tube. The connecting portion 9 has a shape in which the constriction 8 shown in FIG. 3 is thinly stretched, and by reconsidering the shape and material of the constriction 8, flexibility to be inserted in a form along the internal tubule is given. A modification is shown. Moreover, this connection part 9 is not provided so that attachment or detachment is possible, but is formed previously. Therefore, the number of the connecting portions 9 cannot be freely changed, and the total length (that is, equivalent to the number of connecting portions) is a length determined in advance such as for humans, for animals, for urethra, for ureters, and for fallopian tubes. It is manufactured with.

Next, a fourth modification of the in-vivo region light-emitting device according to the first embodiment will be described as Example 4 with reference to FIG. (In particular, corresponding to claim 4)
FIG. 5 is a conceptual diagram of the internal body light-emitting device according to the present embodiment. In FIG. 5, the same parts as those shown in FIG. 1 are denoted by the same reference numerals, and description of the configuration will be omitted.
In FIG. 5, the internal body light emitting device 1 e is omitted in the drawing, but has a structure in which a plurality of light emitting portions 3 are installed inside the tube 2, and a string 12 is provided as an extraction portion at one end of the tube 2. It is connected. The string 12 can pull the tube 2, and after inserting the in-vivo site light-emitting device 1e into a narrow tube in the living body, pulling the string 12 pulls the tube 2 so that the in-body-part light-emitting device 1e is It can be easily pulled out of the body. In addition, the material of the string 12 should just be harmless to a biological body, and is not specifically limited. Moreover, although the length and intensity | strength are not limited, after inserting the in-vivo site | part light-emitting device 1e in the thin tube | vessel in the living body, it is necessary for it to be a thing which can be pulled without breaking.
In the present embodiment, the light emitting unit 3 is composed of two types of drugs 4 and 5 and a partition wall 6 that separates these drugs 4 and 5, but a second type described below is used. The semiconductor light emitting element according to the embodiment may be adopted.

Next, a second embodiment of the internal body light-emitting device according to the present invention will be described with reference to FIGS. (In particular, it corresponds to claims 1 to 3)
FIG. 6 is a conceptual diagram of the in-vivo site light-emitting device according to the second embodiment of the present invention. In FIG. 6, the same parts as those shown in FIG. 1 are denoted by the same reference numerals, and description of the configuration is omitted.
In FIG. 6, the in-vivo body light-emitting device 1f according to the second embodiment has a plurality of semiconductor light-emitting elements 16 serving as light sources inside an insertion portion 18 of a tube 2 that is flexible and light transmissive in the main body. A power supply unit 13 that is disposed and supplies power to the semiconductor light emitting element 16 is provided at one end of the tube 2. In the power supply unit 13, when a switch 15 that connects the power cable 17 connected to the power source 14 is turned on, the power from the power source 14 is supplied to the semiconductor light emitting element 16 through the power cable 17 of the power supply circuit. The light emitting element 16 emits light, and the outside of the tube 2 is illuminated by the light emitting unit 3. The material of the tube 2 in the second embodiment is not particularly limited as long as it is harmless to the living body. For example, plastic such as polyethylene, polypropylene, vinyl chloride, nylon, Teflon (registered trademark), and silicon is used. be able to.
In the second embodiment, the power cable 17, the switch 15 provided therein, the semiconductor light emitting element 16 connected to the power cable 17 and functioning as a light source, and the power source 14 are used as the light emitting means. .
Further, the switch 15 is an irreversible switch, and the details of the configuration will be described later. However, it is desirable that the connection cannot be canceled once connected.
The semiconductor light emitting element means an element that is made of a semiconductor material and emits light when energized, and includes, for example, an LED and a laser diode.

When the switch 15 of the internal body light-emitting device 1f is turned on to cause the light-emitting portion 3 to emit light and the insertion portion 18 is inserted into a narrow tube in the living body, the thin tube is illuminated from the inside by the internal-body light-emitting device 1f and appears to shine in the body cavity. Therefore, in laparoscopic surgery or the like, doctors and veterinarians can easily visually recognize the position and running state of tubules, and can reliably perform examinations, treatments, and operations.
Moreover, since the irreversible switch is provided, it becomes impossible to extinguish the light after the light emitting unit 3 emits light, and the reuse of the internal body light emitting device 1f is restricted. Therefore, by promoting the disposable, it is possible to prevent infection in the medical institution and to eliminate complicated sterilization processing and management work necessary for reusing the internal body light emitting device 1f.
And the whole body light-emitting device 1f is integrally formed by melting or the like, and there is no need to connect a light guide fiber as in the conventional device, so the degree of freedom during surgery of doctors and veterinarians is improved, As a result, the operation can be performed more safely and promptly by reducing the physical burden of a doctor or the like. Moreover, by forming integrally, the sterilization process by ethylene oxide gas, a gamma ray irradiation, etc. is attained, and it can provide in the state sterilized previously.
In FIG. 6, the semiconductor light emitting elements 16 are connected in series, but may be connected in parallel or mixed in series and parallel. Further, when the installation interval of the semiconductor light emitting elements 16 is narrowed, high lightness is obtained in the light emitting unit 3, but as in the case of the first embodiment described above, the lightness uniformity of the entire tube 2 is not particular, In order to cause the entire tube 2 to emit light, the installation interval of the semiconductor light emitting elements 16 is 3 cm or less, preferably 2 cm or less. Further, the emission color of the semiconductor light emitting element 16 is not particularly limited as long as it is a color that can be distinguished from a living body, but blue, yellowish green, or white is preferable to avoid red in order to easily determine in the body cavity.
Incidentally, when a semiconductor light emitting element is used, the power supply unit 13 usually includes a power supply stabilization circuit in addition to the power supply 14 and the switch 15.

Here, the configuration of the irreversible switch will be described with reference to FIG.
7A to 7D are cross-sectional structural views schematically showing the configuration of the irreversible switch according to the present embodiment.
First, in FIG. 7A, the irreversible switch formed in the power supply unit 13a is energized by contacting the power cables 17a ₁ and 17a ₂ forming the power supply circuit with the battery 19 provided therein. It is configured. In a state before the irreversible switch is turned on, the power cable 17 a ₁ is in contact with the electrode of the battery 19, but the other power cable 17 a ₂ is not in contact with the electrode of the battery 19. Here, the irreversible switch is brought into a conducting state by pushing the pushing portion 21 protruding from the lid portion 22 toward the battery 19. That is, the pushing portion 21 to be pushed in pushes the battery 19 through the partition wall 20 made of an easily deformable material so that the electrode of the battery 19 and the power cable 17a ₂ come into contact, and the power supply circuit is formed as a closed circuit, Although not shown, the semiconductor light emitting elements connected to the power cables 17a ₁ and 17a ₂ are lit.
And even if the pushing-out part 21 once pushed in returns to the original position, the battery 19 does not move, and the semiconductor light-emitting element is turned on until the power is completely consumed with the power on. Become.

Next, in FIG.7 (b), the structure of the irreversible switch formed in the electric power supply part 13b is also formed in the electric power supply part 13b provided in the edge part of a body region light-emitting device, and is provided in an inside. A power supply circuit is formed by contacting the power cables 17b ₁ and 17b ₂ with the battery 19. Among these power cables 17b ₁ and 17b ₂ , the power cable 17b ₁ is in contact with the battery 19 in advance, but the power cable 17b ₂ is not in contact with the battery 19 initially.
A conductor 23 is connected to one electrode of the battery 19, and the conductor 23 is provided with a contact 24 b ₁ whose ends are formed in a plurality of bowl shapes. Also, the end of the power cable 17b ₂ is provided with a contact 24b ₂ whose ends are formed in a plurality of hooks. When the tube 2 is strongly crushed or bent, the contacts 24b ₁ and 24b ₂ are deformed. Then, the power cable 17b ₂ is connected to the battery 19 via the contacts 24b ₁ and 24b ₂ and the conductor 23, and the power supply circuit is formed as a closed circuit.
Thereby, a semiconductor light emitting element (not shown) connected to the other ends of the power cables 17b ₁ and 17b ₂ is turned on.
The other power cable 17b ₁ is previously brought into contact with the other electrode of the battery 19, but when the power cable 17b ₁ in the present embodiment is not shielded, a power source is provided as shown in FIG. 7 (b). In order to avoid short circuit with the cable 17b ₂ , it is desirable to wire inside the tube 2 of the internal body light emitting device.

Subsequently, in FIG. 7C, the irreversible switch formed in the power supply unit 13 c is provided with a conductor 23 on one electrode of the battery 19, as in FIG. part is the contact 24c ₁ formed in a spiral shape, the power cable 17c ₁ end to the ends of the power cable 17c ₂ may form a closed circuit by deforming contact with the contact 24c ₂ formed in a spiral shape , 17c ₂ , a semiconductor light emitting element (not shown) connected to the other end is turned on. In FIG. 7C, the contact 24c ₁ and the contact 24c ₂ appear to be separated from each other, but the spiral contact 24c ₂ is inserted in a non-contact manner inside the contact 24c _{1 having} a larger diameter. In this state, by bending or crushing the tube 2, these are deformed and contacted.
Also in this embodiment, the other power cable 17c ₁ is previously brought into contact with the other electrode of the battery 19, but when the power cable 17c ₁ is not shielded, the power cable as shown in FIG. it is desirable to interconnect the interior of the tube 2 in order to avoid short circuit between the 17c _2.
The dotted line in the figure is intended to mean that the contact 24c _1, 24c ₂ are further extended.

Finally, in FIG. 7 (d), the irreversible switch formed in the power supply unit 13d is a conductive layer provided on one electrode of the battery 19, as in FIGS. 7 (b) and 7 (c). a contactor 24d ₁ formed on the end portion of the body 23, the other power supply contactor 24d ₂ that are formed at the end of the cable 17d ₂ is deformed in contact with the closed circuit formed by the power cables _17d 1, 17d ₂ The semiconductor light emitting element (not shown) connected to the end is lit.
The contacts 24d ₁ and 24d ₂ in the power supply unit 13d are cylindrical and are arranged so as to be double, and these contacts 24d ₁ and 24d ₂ appear to be separated from each other, but FIG. Similarly, the cylindrical contact 24d ₂ is inserted in a non-contact manner inside the contact 24d _{1 having} a larger diameter than that, and the tube 2 is deformed by bending or crushing the tube 2. It comes into contact and conducts.
The dotted line in the figure is intended to mean that the contacts 24d _1, 24d ₂ are further extended.
Also in FIG. 7 (d), the when the power supply cable 17d ₁ is not shielded, the power cable 17d ₁ and wire into the interior of the tube 2, a short-circuit between the contact 24d ₁ and contact piece 24d ₂ It is desirable to avoid it.
Even in the irreversible switch shown in FIGS. 7B to 7D, when the two contacts come into contact with each other to form a closed circuit, it cannot be released until power is completely consumed. The semiconductor light emitting element is turned on. Note that the contact 24b ₁ ~24d _2, it is desirable to employ a material with a deformation easy even with and electrically conductive such as copper or aluminum.
By providing an irreversible switch as shown in FIGS. 7A to 7D, it is possible to limit reuse of the internal body light-emitting device and prevent contamination infection in a medical institution or the like.

Next, a first modification of the internal body light-emitting device according to the second embodiment will be described as Example 5 with reference to FIG.
FIG. 8 is a conceptual diagram of the internal body light-emitting device according to the present embodiment. In FIG. 8, the same parts as those shown in FIG. 6 are denoted by the same reference numerals, and description of the configuration will be omitted.
In FIG. 8, in the internal body light emitting device 1 g, a plurality of semiconductor light emitting elements 16 are arranged inside the insertion portion 18 of the tube 2, and a constriction 8 is formed in the tube 2 so as to partition each semiconductor light emitting element 16. Yes. The tube 2 can be bent more freely by these constrictions 8, and can be easily intubated without damaging the tubule that is bent in the living body when the in-vivo region light-emitting device 1g is used.

Next, a second modification of the in-vivo site light-emitting device according to the second embodiment will be described as Example 6 with reference to FIG. (Especially corresponding to claim 2)
In the internal body light emitting device 1h according to the present embodiment, the power supply unit 13 is provided integrally with the tube 2 as the main body in the internal body light emitting device 1f according to the second embodiment (see FIG. 6). Are provided separately from the tube 2. The power supply unit 13 is provided with the power supply 14 and the switch 15, and the configuration in which these and the semiconductor light emitting element 16 are connected by the power supply cable 17 remains the same. By connecting with the wiring 28, the insertion portion 18 into the body can be reduced in weight and size without being affected by the size of the power source 14.
This is because the insertion portion 18 is inserted into a delicate site, and this light weight and downsizing can further reduce the burden on the patient during the operation.
In addition, because of the length of the wiring 28 connecting the insertion portion 18 and the power supply portion 13, during operation, the power supply portion 14 and the switch 15 can be placed at a position where a doctor or veterinarian can easily perform an operation, for example, an operating table or a patient (subject). By placing it on the skin or the like of the surgeon, the doctor or veterinarian can be more easily operated.
Although the insertion section 18 and the power supply section 13 are separated from each other, the connection is not disconnected in advance through the wiring 28 if the wiring 28 is positioned as an extension cable of the power cable 17. There may be.
Alternatively, the connection relationship of the wiring 28 may include a connector (not shown) that can be attached and detached at the end of the insertion portion 18 and / or the end of the power supply portion 13. In this case, it is possible to cope with a single failure such as an unexpected insertion part 18 by replacing parts, and maintenance of the power supply part 13 etc. can be performed separately, so that handling and economy can be improved. It becomes.
In the present embodiment, since the power supply unit 13 includes the power supply 14 and the switch 15, the switch 15 is also separated from the insertion unit 18. However, the switch 15 is not limited to such a case. For example, you may provide in the edge part by the side of the electric power supply part 13 of the insertion part 18. FIG. Furthermore, in the present embodiment, it is sufficient to discard only the insertion portion 18 from the viewpoint of preventing reuse in order to prevent contamination infection in a medical institution or the like. The power supply unit 13 can be reused. Therefore, the switch 15 is not necessarily an irreversible switch, and a general-purpose switch may be used.

Next, a second modification of the in-vivo body light-emitting device according to the second embodiment will be described as Example 7 with reference to FIG.
FIG. 10 is a conceptual diagram of the internal body light-emitting device according to the present embodiment. In FIG. 10, the same parts as those shown in FIG. 6 are denoted by the same reference numerals, and description of the configuration will be omitted.
In FIG. 10, the internal body light emitting device 1 i includes a semiconductor light emitting element 16 as an electrical light emitting means and a power supply unit 13 that supplies power to the semiconductor light emitting element 16. A first resin layer 10 having transparency and flexibility, and a second resin layer 11 having light transparency and flexibility, which is a clad portion that covers the first resin layer 10, are provided. The tip transparent portion 25 is installed on the tip side. The optical semiconductor element 16 is provided at the end of the main body 2 in this embodiment, but may be provided inside the main body 2. In this embodiment, since only one optical semiconductor element 16 is provided, the light emitting section 3 is located at the position where the semiconductor light emitting element 16 is provided, but a plurality of optical semiconductor elements 16 are provided. In the case, it means a portion including the whole of the plurality of optical semiconductor elements 16.
When power is supplied from the power supply unit 13 and the semiconductor light emitting element 16 emits light, the light is reflected at the interface between the first resin layer 10 and the second resin layer 11 as indicated by the solid line arrow 26, and the first The resin layer 10 advances toward the tip transparent portion 25. Further, all light is not reflected at the interface between the first resin layer 10 and the second resin layer 11, and a part of the light passes through the second resin layer 11 as indicated by a dotted arrow 27 and passes through the body. The outside of the partial light emitting device 1i, that is, the entire main body 2 is illuminated.
Therefore, in this embodiment, even if the number of semiconductor light-emitting elements 16 is small, when inserted into a thin tube in a living body, it becomes possible to illuminate the thin tube from the inside, thereby realizing a reduction in the cost of the apparatus. Can do.
In addition, the material of the 1st resin layer 10 and the 2nd resin layer 11 may be what is used for the general plastic fiber, for example, acrylic polymer etc. are used for the 1st resin layer 10 which is a core part, for example. Teflon (registered trademark) or the like can be used for the second resin layer 11 which is a clad portion. When these materials are used and the bendability is not sufficient, it is better to provide a constriction as described with reference to FIGS. 3 and 8. This constriction may be formed only in the second resin layer 11 that is the clad part, or may be formed over the first resin layer 10 that is the core part.

  As described above, according to the first to fourth aspects of the present invention, the position and running state of the tubule in the living body can be opened through an endoscope or the like inserted into the body cavity and a monitor, or can be opened. It is possible to accurately and quickly visually recognize the luminescent site of the patient directly with the naked eye of a doctor or the like. In addition, it is possible to provide an in-vivo site light-emitting device that is easy to handle during use and management, and can be used in veterinary medical institutions and medical institutions.

1 is a conceptual diagram of an internal body light-emitting device according to a first embodiment of the present invention. 1 is a conceptual diagram of an internal body light-emitting device according to Example 1. FIG. It is a conceptual diagram of the in-vivo part light-emitting device which concerns on Example 2. FIG. FIG. 10 is a conceptual diagram of an internal body light-emitting device according to Example 3. It is a conceptual diagram of the internal body light-emitting device which concerns on Example 4. FIG. It is a conceptual diagram of the internal region light-emitting device which concerns on the 2nd Embodiment of this invention. Any of (a) to (d) is a cross-sectional structure diagram schematically showing an irreversible switch of the internal body light-emitting device according to the second embodiment. FIG. 10 is a conceptual diagram of an internal body light-emitting device according to Example 5. It is a conceptual diagram of the in-vivo region light-emitting device according to Example 6. It is a conceptual diagram of the in-vivo region light-emitting device according to Example 7.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1a-1i ... Internal body light-emitting device 2 ... Tube 3 ... Light emission part 4,5 ... Drug 6 ... Partition 7 ... Partition wall 8 ... Constriction 9 ... Connection part 10 ... 1st resin layer 11 ... 2nd resin layer 12 ... string 13,13A～13d ... power supply unit 14 ... power supply 15 ... switch 16 ... semiconductor light-emitting element 17,17a ₁ ~17d 2 _... power cable 18 ... insertion portion 19 ... battery 20 ... partition wall 21 ... pushing portion 22 ... lid 23 ... Derivatives 24b _{1 to} 24d ₂ ... Contacts 25 ... Transparent tip portion 26 ... Solid arrow 27 ... Dotted arrow 28 ... Wiring 29 ... Cover

Claims (4)

  A body part light-emitting device that is inserted into a thin tube in a living body and emits light, and has a main body unit that is sealed at both ends and is hollow or solid, and has a flexible and light-transmitting tubular body. It has at least one light emitting unit provided therein, and electric light emitting means for causing the light emitting unit to emit light. The electric light emitting means includes a semiconductor light emitting element as a light source, and power to the semiconductor light emitting element. A body part light-emitting device comprising: a power supply for supplying power; and a power supply circuit, wherein the power supply circuit includes an irreversible switch that cannot be disconnected once connected to the power supply, and is disposable.   The in-vivo region light-emitting device according to claim 1, wherein a power source of the electric light emitting unit is separated from the main body and connected to the main body via the power supply circuit.   The in-vivo site light-emitting device according to claim 1, further comprising at least one constricted portion formed on a peripheral portion of the main body portion and having an outer periphery smaller than an outer periphery of the main body portion. The in-vivo region light-emitting device according to any one of claims 1 to 3, further comprising a lead portion connected to one end portion of the main body portion and made of a linear body.