JP3203603U - UV irradiation equipment - Google Patents

Abstract

An object of the present invention is to provide an ultraviolet irradiation apparatus capable of effectively performing ultraviolet irradiation on a dental implant in addition to ultraviolet irradiation on a medical instrument. An ultraviolet irradiation apparatus according to the present invention includes a housing provided with an open / close door, an ultraviolet irradiation lamp provided in the housing, an ozone removing filter for removing ozone generated in the housing, a housing, and a housing. The body is provided with a dividing plate that divides the body into an ultraviolet irradiation lamp irradiation space and a heat radiation space. It is characterized by that. The concentrated ultraviolet irradiation space is provided with a support base for installing a dental implant, a cover screw and a healing abutment. [Selection] Figure 1

Description

  The present invention relates to an ultraviolet irradiation device used as a sterilization and cleaning device for medical instruments, and can irradiate artificial biomaterials such as bones and artificial tooth roots with ultraviolet rays, and can improve the binding property with a living body. The present invention relates to an irradiation apparatus.

  For medical devices, decontamination and sterilization is an essential requirement for the purpose of use. Conventionally, ultraviolet irradiation devices have been used, and many products are commercially available. The ultraviolet irradiation apparatus is an apparatus that generates ultraviolet rays using a low-pressure mercury lamp, a high-pressure mercury lamp, or an excimer lamp, and uses a sterilization function by decomposition of organic substances or ozone generation, which are characteristics of the ultraviolet rays.

  In recent years, it has been found that irradiation of an implant, which is an artificial tooth bud made of titanium, with ultraviolet light promotes binding to the living body, that is, osseointegration, and there is a method of irradiating ultraviolet light immediately before implantation of the implant. It is adopted.

  The properties required for an implant as a substitute for tooth buds are sufficient strength as a structural support, high affinity with bone tissue, activity to promote bone formation, and the like. It is desirable to use a dense material for the strength of the structural support. However, in order to improve bone compatibility, a fine rough surface is provided, and new bone is formed in the pores after implantation and integrated. In order to obtain the required strength, a sufficient area is secured. Bone affinity is a property called “bone conduction ability” that directly binds to bone without causing a foreign body reaction after implantation in a living body. In addition to providing pores, hydroxyapatite (HAP) is used as a calcium phosphate ceramic. ) And β-tricalcium phosphate (β-TCP) are used to promote bone formation. Titanium or titanium alloy as an artificial tooth root material is etched or sandblasted to provide fine irregularities on the surface, and has a bone affinity due to super hydrophilicity that is a function of the surface oxide film (titanium oxide). Improvements are being made (see, for example, Patent Documents 1 and 2).

  Among biomedical implants, titanium material was discovered in 1952 by the Swedish Per Ingvar Brönemark, who discovered that titanium and bone were completely bonded, and then titanium was implanted into the bone under certain conditions. In this case, the bone rejection reaction to titanium does not occur at all, and it starts with the fact that a strong bond is born through the oxide film covering the surface of titanium. The bone connection method, in which titanium and bone are directly connected without intervening connective tissue, is called osseointegration, which is a combination of Latin male (os) for bone and English integration for bone. It is.

  Osseointegration is a phenomenon in which bone and metal are directly bonded, and the force acting on the contact surface between the oxide film on the titanium surface and the bone binds biological molecules to the oxide film, causing bone adhesion (for example, Non-patent document 1 etc.).

Titanium oxide TiO _2, which is an oxide film on the surface of titanium or a titanium alloy, is known to exhibit a photocatalytic function when irradiated with ultraviolet rays, and is called the Honda Island effect from the name of the discoverer. When titanium oxide is irradiated with ultraviolet rays, electrons existing in the valence band are excited separately from the holes, move to the conductor beyond the band gap, and holes are generated in the valence band. As a result, the titanium oxide is activated, and by the oxidation-reduction reaction with water vapor in the atmosphere. Titanium atoms Ti and hydroxyl groups are bonded to generate terminal hydroxyl groups, and oxygen molecules O of titanium oxide and hydrogen atoms H are bonded to generate bridged hydroxyl groups. The ozone generated during this redox reaction also contributes to the decomposition of organic matter.

  The band gap of titanium oxide varies depending on the crystal structure, and is 3.2 eV for the anatase crystal structure and 3.0 eV for the rutile crystal structure. Therefore, the wavelength of the irradiated ultraviolet light is 387 nm or less for the anatase crystal structure and 413 nm or less for the rutile crystal structure. The rutile-type crystal structure can absorb light up to a portion close to visible light, and the rutile-type crystal structure that can absorb more light seems to promote the redox reaction. The mold shows a more redox reaction.

  The reason is the difference in the energy structure. The position of the valence band is very deep in both crystals, and the generated holes show sufficient oxidizing power. It is located near the redox potential of hydrogen and is characterized by a relatively weak reduction power. The position of the conduction band of the anatase type crystal is more negative than that of the rutile type, and has a stronger reducing power than the rutile type crystal. Therefore, due to the difference in the position of the conduction band, the anatase type crystal structure as a whole shows a higher redox reaction.

  This redox reaction of titanium oxide by ultraviolet irradiation promotes the precipitation of calcium phosphate and the adsorption of osteocalcin and osteopontin, which are bone proteins, and enables early acquisition of osseointegration. Then, it is considered as follows.

  The surface of titanium as a dental implant material is coated with titanium oxide, but the surface titanium oxide and bone protein are both negatively charged near pH 7, and are divalent positive such as calcium. Both are attracted by the presence of ions. Further, since the hydroxyl group adsorbed on the titanium surface has a positive charge, it is considered that a bone protein having a negative charge is adsorbed. Osseointegration on the surface of titanium, which is a dental implant material, is performed by forming an intermediate layer at the interface via titanium oxide.

  In the intermediate layer, at the initial stage of implanting titanium implants, osteocalcin and osteopontin generated from osteoblasts are adsorbed to the titanium interface via calcium and hydroxyl groups. These bone proteins enhance osteoblast migration and bind to osteoblast integrants, and the layer of “titanium-titanium oxide-titanium hydroxide-calcium-bone protein-collagen fiber-bone” It becomes a structure. This layer structure becomes a structure of “titanium-titanium oxide-titanium hydroxide-protein polysaccharide complex-osteoid (bone tissue before calcification) -bone” with time, and osseointegration is obtained.

  Electrons excited in the conductor by irradiation with ultraviolet rays move to the valence band over time, recombine with holes, and the redox reaction disappears. Therefore, it is important to irradiate with ultraviolet rays when the oxidation-reduction reaction continues, that is, immediately before implant placement.

  Thus, the oxidation-reduction reaction by ultraviolet irradiation to the implant is a factor that promotes the binding with the living body, and the effect of this reaction varies depending on the material of the implant. However, it is certain that osseointegration is acquired earlier by ultraviolet irradiation.

  From the relationship with the layer of "titanium-titanium oxide-titanium hydroxide-calcium-bone protein-collagen fiber-bone" which is the mechanism of osseointegration, the ideal surface state is titanium and oxygen as elemental composition. The other elements do not contribute to the acquisition of osseointegration, and other elements are pollutants, which are obstructive factors for the acquisition and promotion of osseointegration.

  Patent Document 3 details the surface contamination of dental implants and the effect of ultraviolet irradiation. According to Patent Document 3, based on the results of XPS analysis of commercially available dental implants, the components of dental implants that are wary of the initial stage of production and time are, of course, titanium Ti and oxygen O, carbon C as other elements. , Phosphorus P, and silicon Si. Except for titanium Ti and oxygen O, they become pollutants, and the carbon content is the highest, 20-40 atm%, which is higher than the titanium Ti concentration.

  By irradiating this commercially available dental implant with ultraviolet light, the carbon concentration is reduced to 10 atm%. This result is considered to be a synergistic effect of the oxidation-reduction reaction of titanium oxide and the cleaning action by ultraviolet rays.

  As described above, the current technical background of the effect of irradiating the implant with ultraviolet rays has been described. However, a dedicated dental implant irradiation device has been disclosed for dental implants (see Patent Documents 4 to 9).

  The dental implant irradiation device disclosed in Patent Document 4 is a dental implant light irradiation device that irradiates ultraviolet rays onto a screw-type dental implant in which a screw portion made of a spiral protrusion is formed, and includes a housing and The stage is provided with a stage in which a plurality of dental implants are arranged and held along one direction, and an ultraviolet irradiation lamp disposed in the casing, and radiates from the ultraviolet irradiation lamp. The irradiated ultraviolet rays are applied to the entire surface of the protrusions forming the screw portions of the plurality of dental implants held on the stage. In addition, two ultraviolet irradiation lamps are arranged on both sides parallel to one direction in an implant group composed of a plurality of dental implants held on a stage.

  In Patent Document 5, ozone removing means is disclosed in addition to the apparatus of Patent Document 4, and in Patent Document 6, a housing having an opening / closing door, a lock mechanism for sealing the door to the housing, and a housing are provided. A control unit comprising an ultraviolet lamp and ozone removing means, which locks the door before the ultraviolet lamp starts lighting, starts ozone removal processing after the ultraviolet lamp is extinguished, and releases the door locked state after a certain period of time. It has.

  In Patent Document 7, a carriage provided in the casing so as to be able to be drawn out and an implant holder placed on the carriage and disposed opposite to the ultraviolet lamp in the casing are arranged, and the implant holder is detachable from the carriage. It is disclosed to comprise a mounting table placed on the mounting table and an implant support table that is detachably mounted on the mounting table.

  Further, Patent Document 8 discloses an ultraviolet lamp monitor, and Patent Document 9 discloses an ultraviolet lamp protective cover.

Japanese Patent Laid-Open No. 2002-327079 Japanese Unexamined Patent Publication No. 2011-110388 Japanese Patent Application Laid-Open No. 2014-193249 Japanese Patent Application Laid-Open No. 2012-075548 Japanese Patent Application Laid-Open No. 2012-075549 Japanese Patent Application Laid-Open No. 2012-157412 Japanese Unexamined Patent Publication No. 2012-157413 Japanese Unexamined Patent Publication No. 2012-176160 Japanese Unexamined Patent Publication No. 2012-176161

Masanori Yoshinari “Implant materials and their surfaces: Part 1. Titanium as an implant material”, Dentology, 103 (5): p313-319

  Osseointegrated implants based on osseointegration are prosthetic treatments that restore human functions, and early acquisition and maintenance of osseointegration is essential for long-term success.

  For this purpose, it is effective to irradiate the implant with ultraviolet rays just before implantation. However, currently available ultraviolet irradiation devices for dental implants are expensive, and a low-cost device that can be easily handled is desired. ing.

  An object of the present invention is to provide an ultraviolet irradiation device that enables ultraviolet irradiation to a medical instrument in addition to ultraviolet irradiation to a dental implant.

  An ultraviolet irradiation device according to the present invention includes a housing provided with an opening / closing door, an ultraviolet irradiation lamp provided in the housing, an ozone removing filter for removing ozone generated in the housing, and an ultraviolet ray inside the housing. It is equipped with a dividing plate that divides the irradiation lamp irradiation space and the heat radiation space, and a concentrated ultraviolet irradiation space is provided in the ultraviolet irradiation lamp irradiation space by an enclosure plate and a dividing plate surrounding the ultraviolet irradiation lamp and the irradiated object. And

  The dividing plate and the surrounding plate have a reflection characteristic that the surface corresponding to the ultraviolet irradiation lamp reflects ultraviolet rays, and the position of the dividing plate in the housing can be adjusted. Moreover, a division board and a surrounding board are removable.

  A plurality of ultraviolet irradiation lamps are installed. As this ultraviolet irradiation lamp, a low-pressure ultraviolet lamp, a high-pressure ultraviolet lamp, or an excimer lamp is used.

The open / close door of the ultraviolet irradiation device is provided with a replaceable elastic body in order to increase the sealing performance in the housing.
It is characterized by.

  An ultraviolet irradiation apparatus that can be applied to a dental implant includes a casing provided with a closed door, an ultraviolet irradiation lamp provided in the casing, and an ozone removal filter for removing ozone generated in the casing. A discharge fan, and a partition plate that divides the inside of the housing into the ultraviolet irradiation lamp irradiation space and a heat dissipation space, and in the ultraviolet irradiation lamp irradiation space, an enclosure plate and a dividing plate surrounding the ultraviolet irradiation lamp and the irradiated object, A concentrated ultraviolet irradiation space is provided, and the supporting space for installing the dental implant and the cover abutment is provided in the concentrated ultraviolet irradiation space.

  In the concentrated ultraviolet irradiation space, a dental implant support base provided with circular recesses having different diameters and depths can be provided so that a dental implant, a cover screw, and a healing abutment can be installed. In the dental implant support, a circular recess having a different diameter and depth is provided with a recess having a small diameter and a recess having a large diameter. Further, the dental implant support base is provided with a reflective property in which the surface on which the dental implant, the cover screw, and the healing abutment are installed reflects ultraviolet light. Furthermore, the dental implant support can be installed with an implant driver attached to the dental implant.

  Two ultraviolet irradiation lamps provided in the ultraviolet irradiation apparatus are arranged in parallel, and the support base is located between the two ultraviolet irradiation lamps, along the longitudinal direction of the ultraviolet irradiation lamp, with a dental implant, a cover screw, and a healing abutment. The structure can be installed in the longitudinal direction. In addition, two ultraviolet irradiation lamps are arranged in parallel and one on the upper part, and the support base is disposed between the three ultraviolet irradiation lamps along the longitudinal direction of the ultraviolet irradiation lamp, along the longitudinal direction of the dental implant and the cover screw. It can also be set as the structure which can be installed in a direction.

  A circular recess having a different diameter and depth is provided on a side surface of the dental implant support, and a recess having a small diameter is provided in a recess having a large diameter.

  According to the present invention, a normal ultraviolet irradiation apparatus is provided with an ultraviolet concentrated irradiation chamber, and an object to be irradiated can be set in the vicinity of the ultraviolet lamp, so that effective ultraviolet irradiation can be performed. Can have an effect. Due to the presence of this thermal diffusion space, it is possible to irradiate ultraviolet rays for a long time.

  The ultraviolet intensive irradiation chamber is surrounded by a dividing plate and a surrounding plate, each of which can be removed, and can be used as a one-room medical instrument sterilization apparatus.

  Since the support for holding the irradiated object is provided with a recess for attaching the dental implant and the cover screw, the dental implant and the cover abutment can be irradiated with ultraviolet rays simultaneously. Healing caps can also be attached, and all parts necessary for implant surgery can be used. Since a cover screw is used at the same time when a dental implant is placed, simultaneous irradiation with ultraviolet rays is an important point during surgery.

  In addition, by providing a recess on the side of the dental implant support, the dental implant, cover screw, and healing abutment can be installed in the longitudinal direction, parallel to the longitudinal direction of the ultraviolet lamp, and evenly irradiated with ultraviolet rays. Is done.

The front view of the ultraviolet irradiation device by this invention. The front view and top view of the enclosure board by this invention. The front view of the ultraviolet irradiation device which has arrange | positioned three ultraviolet irradiation lamps. The front view and top view of the enclosure board by this invention. The figure explaining the dental implant for one-time methods. The figure explaining the dental implant for two times methods. The figure explaining the state by which the dental implant was embed | buried. The figure explaining a dental implant and an implant driver. The figure explaining a dental implant support stand. The figure explaining the state by which the dental implant and the cover screw were hold | maintained at the support stand. The side view of the support stand in which the recessed part holding a dental implant and a cover screw was provided in the side surface. The figure explaining the state at the time of the dental implant and the cover screw hold | maintained on the side surface of the support stand being irradiated with the vacuum ultraviolet lamp. The figure which shows the result of having evaluated the wettability of the dental implant before and behind ultraviolet irradiation in the concentrated ultraviolet irradiation space of the ultraviolet irradiation device of this invention.

  The ultraviolet irradiation treatment according to the present invention can be used as an irradiation type BOX within 20 mm from the ultraviolet irradiation lamp by moving the dividing plate in the housing, and sterilized by setting large medical equipment and surgical instruments. can do.

  In particular, by providing a UV concentrated irradiation space that surrounds the UV irradiation lamp using a dividing plate and making the other space a heat dissipation space, it is possible to irradiate the irradiated object with concentrated UV light for a long time. It has become.

  FIG. 1 is a view showing an ultraviolet irradiation apparatus using two ultraviolet irradiation lamps according to the present invention, and FIG. 2 shows a surrounding board surrounding the ultraviolet irradiation lamp. FIG. 3 is a view showing an ultraviolet irradiation apparatus using three ultraviolet irradiation lamps according to the present invention, and FIG. 4 shows a surrounding plate surrounding the ultraviolet irradiation lamp.

  The ultraviolet irradiation apparatus 10 using two ultraviolet irradiation lamps according to the present invention shown in FIG. 1 is divided into upper and lower spaces by a dividing plate 12 inside the casing. The lower space functions as a heat dissipation space 16 for heat dissipation. For this purpose, the dividing plate 12 is provided with a number of holes for smooth air convection. The dividing plate 12 can be moved up and down by the partition 14 and installed. In the ultraviolet irradiation device 10 shown in FIG. 1, three pairs of partitioning tables 14 that are paired on the left and right are provided. This partition 14 enables installation close to the ultraviolet irradiation lamp according to the size of the irradiated object. Further, the dividing plate 12 can be removed.

  The upper space in the housing divided into two by the dividing plate 12 is a space for ultraviolet irradiation, and the ultraviolet irradiation lamps are installed on the left and right of the concentrated ultraviolet irradiation space. Further, a concentrated ultraviolet irradiation space 20 is provided by surrounding the ultraviolet irradiation lamp with a surrounding plate 18. Although FIG. 1 shows an ultraviolet irradiation lamp socket 22 for setting an ultraviolet irradiation lamp, various ultraviolet lamps are set in the ultraviolet irradiation lamp socket 22 to irradiate ultraviolet rays.

  The surrounding board 18 has shown the top view and front view in FIG. The enclosure plate 18 includes an upper plate 40, a side plate 42, and a front plate 44, and forms a concentrated ultraviolet irradiation space 20 that surrounds the ultraviolet irradiation lamp together with the divided plate 12. The surfaces surrounding the ultraviolet irradiation lamps of the upper plate 40 and the side plate 42 have a mirror finish and reflect ultraviolet rays. The side plate 42 is attached so as to be spread downward at an angle of about 20 degrees from the vertical direction to effectively dissipate heat to the heat dissipating space 16 as a lower space. The front plate 44 is provided with an opening 46. The opening 46 is a work opening for setting an object to be irradiated.

  As shown in FIG. 1, the surrounding plate 18 is attached to the uppermost part of the space in the housing, and the left and right ends of the upper plate 40 are placed on an attachment part (not shown). The enclosure plate 18 has a structure that is simply placed on the mounting portion, and can be freely removed.

  An opening / closing door 24 is provided in front of the ultraviolet irradiation device 10 and is opened and closed by a handle 26. Inside the opening / closing door 24, a sponge as an elastic body is attached along the casing frame. When the opening / closing door 24 is closed, the pressure inside the opening / closing door 24 ensures the hermeticity inside the casing. By using a sponge, the cost can be reduced and the sponge can be replaced.

  The object to be irradiated is set by opening the opening / closing door 24 and placing it on the dividing plate 12 through the opening 46 of the enclosure plate 18. At this time, you may provide the support stand 32 which mounts a to-be-irradiated object. The support base 32 is adjusted in height according to the object to be irradiated and set at a position close to the ultraviolet irradiation lamp.

  When the irradiated object is set, the door 24 is closed and the power switch 28 is pushed. When the power is turned on, since the power switch 28 is also used as a power lamp, the lamp is lit on the power switch 28. The irradiation time of the ultraviolet irradiation lamp is set by the UP / DOWN switch 34. The UP / DOWN switch 34 is a timer and sets an optimum irradiation time according to the object to be measured. The irradiation time can be set in increments of 1 minute between 01 and 10 minutes, and thereafter, 15, 20, 25, 30, 40, 50 minutes, and 1, 2, 3 hours. After the irradiation time is determined by setting the UP / DOWN switch 34, when the START / STOP switch 30 is pressed, the ultraviolet irradiation lamp is turned on, ultraviolet irradiation is started, and the ultraviolet lamp selection LED 36 is turned on.

  Selection of the ultraviolet irradiation lamp is performed by the LAMP switch 38. The ultraviolet lamps are turned on when the left and right ultraviolet rays are indicated by L / R LEDs, and the central ultraviolet ray lamp is indicated by S. In the ultraviolet irradiation apparatus using two ultraviolet irradiation lamps shown in FIG. 1, since there is no ultraviolet lamp in the central portion, the LED indicated by S is not used, and each time the LAMP switch 38 is pressed, the left and right ultraviolet lamps are turned on.・ Off will be repeated. In the ultraviolet irradiation apparatus using three ultraviolet irradiation lamps shown in FIG. 3, L / R, S, and full lighting are repeated every time the LAMP switch 38 is pressed.

  The reason why the power switch 28 and the START / STOP switch 30 are provided is for preparations such as reconfirmation of equipment installed in the casing and confirmation of irradiation time.

  When the time set by the UP / DOWN switch 34 elapses, the ultraviolet irradiation lamp is turned off and the ultraviolet irradiation is completed. If it is desired to stop during the ultraviolet irradiation, the power of the ultraviolet irradiation lamp is turned off when the START / STOP switch 30 is pressed. Ozone generated in the housing by ultraviolet irradiation (also referred to as vapor phase ozone) is sucked by a suction pump separately provided outside through the ozone removal filter 39.

  The suction pump is connected to the ultraviolet irradiation device 10 through a suction tube and a signal line, and starts to operate at the end of the set time of the UP / DOWN switch 34. At the same time, the suction pump operation LED 37 in the ultraviolet irradiation device 10 is turned on. . The operation time of the suction pump can be varied in 4 steps of 2 minutes, 3 minutes, 3 minutes and a half, and 4 minutes. A wide ozone removal filter 39 is provided due to the large size of the main body sterilization space, and the removal of gas phase ozone can be completed in a short time. The removal of gas phase ozone is completed in approximately 3 minutes.

  FIG. 3 shows an ultraviolet irradiation apparatus 10-1 in which three ultraviolet irradiation lamps are arranged in the concentrated ultraviolet irradiation space 20. In FIG. 3, an ultraviolet irradiation lamp socket 22 is shown, but ultraviolet irradiation lamps are set in the ultraviolet irradiation lamp socket 22, and one is placed on the upper part of the concentrated ultraviolet irradiation space and one on the left and right sides, for a total of 3 It is structured to surround three sides with a single ultraviolet lamp. Thereby, more effective ultraviolet irradiation than the ultraviolet irradiation apparatus 10 shown in FIG. 1 is realized.

  FIG. 4 shows the surrounding plate 18-1 and shows a plan view and a front view. The enclosure plate 18-1 includes an upper plate 40, a side plate 42, and a front plate 44, and together with the dividing plate 12, forms a concentrated ultraviolet irradiation space 20 that surrounds the ultraviolet irradiation lamp. The side plate 42 is bent about 20 degrees in the vertical direction from the center line and surrounds the ultraviolet irradiation lamp. The front plate 44 is provided with an opening 46. The opening 46 is a work opening for setting an object to be irradiated.

  The ultraviolet irradiation devices 10 and 10-1 according to the present invention can be expected to be effective for dental implants by providing the concentrated ultraviolet irradiation space 20. This is because the dental implant is embedded in the alveolar bone as a substitute for the lost tooth, and therefore, irradiation of ultraviolet rays is effective for sterilization and promotion of osseointegration.

  FIG. 5 shows a one-time dental implant in which the implant surgery is performed once. The dental implant 50 includes a fixture 52, a collar portion 54, and an abutment 56. The fixture 52 is embedded in the alveolar bone and combined with the living tissue. It is screwed for embedding, and the surface is provided with fine irregularities to increase the contact area with living tissue. Titanium is often used as the material, and the surface is covered with an oxide film (titanium oxide). The collar portion 54 is provided for attaching a denture, but part or all of the collar portion 54 is embedded in the alveolar bone. The abutment 56 is exposed from the gums and serves as a support for mounting a denture.

  FIG. 6 shows a two-way dental implant in which the implant procedure is performed twice. The dental implant 50-1 for the two-time method includes a fixture 52 and a collar portion 54. The dental implant 50-1 has a hollow portion with the upper portion of the collar portion 54 as an opening, and is provided with screw holes for attaching the cover screw 60 and the healing abutment 64.

  The cover screw 60 is attached to the dental implant 50-1, covers the opening of the collar portion with the cover cap 62, and closes the hollow portion. After the first operation, the healing abutment 64 is replaced with a cover abutment and attached to the dental implant 50-1, and used as a base for a denture.

  In the two-time method, the dental implant 50-1 is embedded in the alveolar bone, a cover screw is attached, and then the gums are sutured to cover the upper part.

  FIG. 7 shows a state after the first operation. The fixture 52 of the dental implant 50-1 embedded in the alveolar bone 70 is combined with the living body by osseointegration. The gum incision is sutured after the cover screw 60 is mounted, but the epithelial tissue proliferates to block traffic to the outside, and the bone is absorbed while avoiding the downgrowth of the epithelial tissue. The periosteum 72, connective tissue 74, and epithelial tissue 76 cover the upper portion of the collar portion 54 and the cover cap 62 in a layered manner. The suture part 78 incised at the time of implant placement is healed by tissue bonding.

  The dental implant has been described above. However, since it is embedded in a living body and directly comes into contact with living tissue, it is necessary to sufficiently sterilize and remove contaminants before surgery. On the other hand, fine irregularities, grooves and pores on the surface that are imparted for biocompatibility are contaminated by the adhesion or adsorption of organic compounds during the manufacturing process, and it is extremely difficult to remove even after washing. It becomes a hindrance to theo-integration. There are also impurities contained in the original material. Furthermore, when stored for a long period of time, adhesion and adsorption of organic compounds contained in the atmosphere also occur.

  Furthermore, the fixture 52 is expected to be enhanced by ultraviolet irradiation in order to promote osseointegration. Under such circumstances, when performing an operation of irradiating the dental implant with ultraviolet rays, it is necessary to prevent direct contact with human hands.

  In the dental implants 50 and 50-1, the fixture 52 and the collar portion 54 are in direct contact with the living tissue. The cover screw 60 is a cover cap 62, and the healing abutment 64 is a healing cap 66. In particular, the dental implant 50-1 is difficult to handle because the entire surface is in contact with the living tissue except for the upper surface of the collar portion 54.

  For this reason, dental implants can be irradiated with ultraviolet rays with an implant driver attached.

  Typically, dental implants are contained in cases packaged in sterile packages. When the dental implant is taken out, it is taken out by being coupled with an implant driver attached to the handpiece so that it cannot be touched by human hands. The extracted dental implant has a handpiece and is inserted into the alveolar bone by rotating the implant driver with a separately installed motor.

  The ultraviolet irradiation to the dental implant is set in the ultraviolet irradiation apparatus using this implant driver.

  FIG. 8 shows a state where the implant driver 68 is mounted on the dental implant 50-1 for the two-time method. The upper part of the implant driver 68 is a coupling part attached to the handpiece. The dental implant 50-1 only needs to use the implant driver 68 as an operation unit, and does not need to touch a portion that directly contacts the living tissue. The same condition can be realized even with a single-use dental implant. In addition, there is a dental implant sold with the implant driver 68 coupled, and in this case, it can be used as it is.

  FIG. 9 is a plan view and a side view of a dental implant support for installing a dental implant, a cover abutment, and a healing abutment. The dental implant support base 80 has a holding portion 82, and sets the dental implants 50 and 50-1, the cover screw 60, and the healing abutment 64. The holding portion 82 is provided with double circular recesses, and a circular recess having a small diameter and a deep depth is present in the circular recess having a large diameter.

  FIG. 10 is a view showing a state where the dental implant 50-1 and the cover screw 60 are installed on the dental implant support base 80. FIG. In the dental implant 50-1, the implant driver 68 is coupled, and the shaft portion of the implant driver 68 is set in the concave portion of the holding portion 82. If there is a holder 84 for the dental implant 50-1 in addition to the implant driver 68, it may be set in a state of being coupled to the holder 84. The cover screw 60 is set by inserting a screw portion into a concave portion inside the holding portion 82.

  FIG. 11 shows a horizontal dental implant support. The horizontal dental implant support base 86 is provided with holding portions 82-1 and 82-2 on the side surface, and the small-diameter concave portion in the large-diameter concave portion is penetrated and used in common. It is not necessary to use a common recess having a small diameter, and it may be provided at another position. Moreover, it does not need to penetrate. Of course, the holding portion may be provided only on one side, and the position of the holding portion on the side surface portion is also a design problem.

  FIG. 12 shows a state in which the dental implant 50-1 and the cover screw 60 to which the implant driver 68 is coupled are installed on the horizontal dental implant support 86 and set in the ultraviolet irradiation lamp 88 of the ultraviolet irradiation apparatus 10. Yes. Since the ultraviolet irradiation lamp 88 is inserted into the ultraviolet irradiation lamp socket 22 of the ultraviolet irradiation apparatus 10 shown in FIG. 1, it is disposed horizontally from the front to the back.

  Therefore, if the dental implant 50-1 to which the implant driver 68 is coupled and the cover screw 60 are installed using the horizontal dental implant support base 86, the longitudinal direction of the ultraviolet irradiation lamp 88 and the dental implant 50- 1 and the longitudinal direction of the cover screw 60 coincide with each other, and efficient ultraviolet irradiation becomes possible. Although the number of ultraviolet rays irradiated at one time is small, since several horizontal dental implant support bases 86 can be arranged, this arrangement is sufficient in practice.

As the ultraviolet irradiation lamp, a low-pressure ultraviolet lamp is mainly used. The low-pressure ultraviolet lamp shows a spectral distribution having intensities at wavelengths of 185 nm and 254 nm. Vacuum ultraviolet light having a wavelength of 185 nm is absorbed by oxygen O ₂ in the air to generate ozone O ₃ . When ultraviolet light having a wavelength of 254 nm is absorbed by the ozone O ₃ , atomic active oxygen [O] is generated. In addition, vacuum ultraviolet light having a wavelength of 185 has a strong photon energy and an energy per mole of 651 kJ / mol, and generally dissociates an organic compound represented by C _m H _n O _k into mC, nH, and kO. The dissociated organic substances mC, nH and kO react with atomic active oxygen [O] having strong oxidizing power to generate volatile substances such as carbon dioxide CO ₂ and water H ₂ O, which are removed by volatilization. The

  Vacuum ultraviolet light generated from a low-pressure ultraviolet lamp has a wavelength of 185 nm, absorption by oxygen in the atmosphere is less than that of excimer light having a wavelength of 172 nm, and the attenuation of light intensity is about 20 even at a position 20 mm from the low-pressure ultraviolet lamp. %. Therefore, it is suitable for dental implants having a three-dimensional shape, but it is still more effective to place the dental implant parallel to the low-pressure ultraviolet lamp in order to obtain a uniform and highly accurate clean surface. .

  As the ultraviolet lamp, in addition to the low-pressure ultraviolet lamp, a high-pressure ultraviolet lamp or an excimer lamp may be used. Since the excimer lamp becomes hot, a water cooling device is provided above the excimer lamp.

  FIG. 13 shows the results of investigating the wettability with respect to water before and after UV irradiation when a low-pressure UV lamp is used in the UV irradiation apparatus of the present invention and UV irradiation is applied to a titanium dental implant. ing. Before the ultraviolet irradiation of the fixture, the surface state is highly water-repellent with respect to water, but after the ultraviolet irradiation, the fixture is extremely hydrophilic and wet. The ultraviolet irradiation time is about 15 minutes for the ultraviolet irradiation device 10 with two ultraviolet lamps, and about 8 minutes for the ultraviolet irradiation device 10-1 with three ultraviolet irradiation lamps.

  This is because titanium oxide, which is an oxide film on the fixture surface, is electronically excited by ultraviolet rays and forms a bridge that is hydroxyl-bonded to moisture in the atmosphere by the oxidation-reduction reaction of titanium oxide molecules. Because it became. Osseointegration is considered to be promoted by the generation of this redox reaction by surface activation between the fixture and the living tissue inside the alveolar bone. In addition, it is considered that generation of ozone by ultraviolet irradiation promotes an oxidation reaction on the surface of the titanium fixture, and a titanium oxide film is formed.

  By performing ultraviolet cleaning with an ultraviolet irradiation device, removal of impurities contained in titanium or titanium oxide, particularly removal of carbon components, is effectively performed. In this case, the irradiation time of the ultraviolet lamp is set to 1 hour or more. Is effective. However, since the irradiation time is long, it may be preliminarily cleaned with ultraviolet rays for the purpose of removing the carbon component, and immediately before implant surgery, the dental implant may be irradiated with ultraviolet rays for surface activation and implantation.

  The promotion of osseointegration by UV irradiation depends on the characteristics of the titanium oxide on the fixture surface, so it does not produce the same effect on all titanium dental implants, and varies depending on the titanium raw material and the manufacturing method. It will be natural to come. In recent years, methods of actively forming a titanium oxide film on the fixture surface have been studied, and the relationship with osseointegration has become clear. Even in that case, the ultraviolet irradiation device according to the present invention is effective, and we are convinced that it can greatly contribute to future development.

  Although the ultraviolet irradiation apparatus of the present invention has been described above, the present invention includes appropriate modifications that do not impair the object and advantages thereof, and is not limited by the above embodiments.

DESCRIPTION OF SYMBOLS 10,10-21 Ultraviolet irradiation apparatus 12 Dividing plate 14 Partition 16 Heat radiation space 18,18-1 Fence board 20 Concentrated ultraviolet irradiation space 22 Ultraviolet irradiation lamp socket 24 Opening / closing door 26 Handle 28 Power switch 30 START / STOP switch switch 32 Support Stand 34 UP / DOWN switch 36 UV lamp selection LED
37 Suction pump operation LED
38 LAMP switch 39 Ozone removal filter 40 Upper plate 42 Side plate 46 Front plate 46 Opening 50, 50-1 Dental implant 52 Fixture 54 Collar portion 56 Abutment 60 Cover screw 62 Cover cap 64 Healing abutment 66 Healing cap 68 Implant Driver 70 Alveolar bone 72 Periosteum 74 Connective tissue 76 Epithelial tissue 78 Suture part 80 Dental implant support base 82 Holding part 84 Holder 86 Horizontal dental implant support base 88 UV irradiation lamp

Claims (14)

A housing provided with an open / close door;
An ultraviolet irradiation lamp provided in the housing;
An ozone removal filter for removing ozone generated in the housing;
A dividing plate that divides the inside of the housing into the ultraviolet irradiation lamp irradiation space and the heat radiation space,
With
In the ultraviolet irradiation lamp irradiation space, a concentrated ultraviolet irradiation space is provided by the enclosure plate surrounding the ultraviolet irradiation lamp and the object to be irradiated and the divided plate,
Ultraviolet irradiation device characterized by. In the ultraviolet irradiation device according to claim 1,
The divided plate and the surrounding plate have a reflection characteristic that the surface corresponding to the ultraviolet irradiation lamp reflects ultraviolet rays,
Ultraviolet irradiation device characterized by. In the ultraviolet irradiation device according to claim 1,
The position where the dividing plate is arranged in the housing is adjustable,
Ultraviolet irradiation device characterized by. In the ultraviolet irradiation device according to claim 1,
The dividing plate and the surrounding plate are removable;
Ultraviolet irradiation device characterized by. In the ultraviolet irradiation device according to claim 1,
There are multiple UV irradiation lamps installed.
Ultraviolet irradiation device characterized by. In the ultraviolet irradiation device according to claim 1,
The ultraviolet irradiation lamp is a low-pressure ultraviolet lamp, a high-pressure ultraviolet lamp, or an excimer lamp;
Ultraviolet irradiation device characterized by. In the ultraviolet irradiation device according to claim 1,
The opening / closing door is provided with an exchangeable elastic body in order to increase the sealing performance in the housing,
Ultraviolet irradiation device characterized by. In the ultraviolet irradiation device according to claim 1,
In the concentrated ultraviolet irradiation space, in order to be able to install a dental implant, a cover screw, and a healing abutment, a dental implant support base provided with circular recesses having different diameters and depths was provided.
Ultraviolet irradiation device characterized by. In the ultraviolet irradiation device according to claim 8,
The dental implant support base has a reflective property of reflecting ultraviolet rays on a surface on which the dental implant, the cover screw, and the healing abutment are installed,
Ultraviolet irradiation device characterized by. In the ultraviolet irradiation device according to claim 8,
In the dental implant support base, a circular recess having a different diameter and depth is provided with a recess having a small diameter in a recess having a large diameter,
Ultraviolet irradiation device characterized by. In the ultraviolet irradiation device according to claim 8,
The dental implant support can be installed with an implant driver attached to the dental implant;
Ultraviolet irradiation device characterized by. In the ultraviolet irradiation device according to claim 8,
Two UV irradiation lamps are arranged in parallel,
The support is a structure that can be installed in the longitudinal direction of the dental implant and the cover screw along the longitudinal direction of the ultraviolet irradiation lamp between the two ultraviolet irradiation lamps,
Ultraviolet irradiation device characterized by. In the ultraviolet irradiation device according to claim 8,
Two ultraviolet irradiation lamps are arranged in parallel and one on the top,
The support is a structure that can be installed in the longitudinal direction of the dental implant and the cover screw along the longitudinal direction of the ultraviolet irradiation lamp between the three ultraviolet irradiation lamps,
Ultraviolet irradiation device characterized by. In the ultraviolet irradiation device according to claim 8,
On the side surface of the dental implant support, a circular recess having a different diameter and depth is provided with a recess having a small diameter in a recess having a large diameter,
Ultraviolet irradiation device characterized by.