JP6296584B1 - Orthokeratology lens decision supply method and decision supply system - Google Patents

Abstract

A method and system for quickly determining and supplying an optimal orthokeratology lens. An orthokeratology lens determination and supply system includes a selection device, a database server, a lens determination server, a terminal device, and a terminal-side lens manufacturing device. The selection device is obtained by an acquisition device. A determination device 28 that determines that the lens is a registered lens from lens movement data on the cornea, and constructs a database from the registered patient data and the registration stage data, and the terminal device receives the patient data acquisition device 71, lens data reception and transmission The apparatus 73 includes a patient stage data reception function, and can transmit patient data and patient stage data to a lens determination server. The lens determination server detects a registered lens from the database and determines it as an orthokeratology lens to be used for the patient. The registered lens correction data to the terminal side lens manufacturing equipment. Shin and producing orthokeratology lens. [Selection] Figure 1

Description

  The present invention relates to a contact lens for use in corneal correction therapy for correcting ocular refractive errors such as myopia and hyperopia by using a contact lens with a special curve design to deform and correct the corneal shape. The present invention relates to a decision supply method and a decision supply system for an orthokeratology lens.

  Among the corneal correction therapies, the conventional therapy for correcting myopia and astigmatism shown in Patent Document 1, for example, is called orthokeratology.

  Further, Patent Document 2 discloses an orthokeratology lens that is a contact lens for correcting myopia and / or astigmatism according to the invention of the present inventor (hereinafter, including orthokeratology including myopia and / or astigmatism correction and farsightedness correction). Referred to as a lens).

  The orthokeratology lens changes the curvature to a flat level in the case of myopia correction, and gradually increases the curvature in the case of hyperopia correction. In the final stage, the cornea is ideal. The curvature is such that the naked eyesight can be obtained.

  In addition, when attaching an orthokeratology lens to the cornea, conventionally, a plurality of candidate contact lenses, which are selected based on data obtained by measuring the refractive power (hereinafter, diopter or D) of a patient's cornea with a keratometer, are sequentially attached. Among them, an orthokeratology lens having an optimal correction D for correcting the cornea D is used.

  Occasionally, a large number of contact lenses with slightly different correction D are prepared, all of them are tested on the patient's cornea, one is used for correction, and the other is discarded. In addition, there is a problem that the burden on the patient increases.

  Since the number and area of doctors who perform vision correction treatment using the orthokeratology lens as described above are limited, it is a considerable time and economical burden for patients at remote locations to receive treatment. In addition, even if a doctor exists in a remote place, there are technical and time difficulties in obtaining an orthokeratology lens optimal for the patient.

US Pat. No. 5,695,509 Japanese Patent No. 3881221

  The present invention has been made in view of the above-described conventional problems, and it is optimal to quickly and optimally attach a contact lens to a patient's cornea many times without burdening the patient. It is an object of the present invention to provide an orthokeratology lens determination supply method and a determination supply system for determining and supplying an orthokeratology contact lens, that is, an orthokeratology lens.

  The present inventor has developed a method for easily finding an orthokeratology lens that is optimal for wearing on the cornea of a patient. In addition, using this method, a database was constructed by accumulating orthokeratology lens data actually used for cornea correction for more than 10,000 patients. The optimal orthokeratology lens can be easily determined from the cornea data. Further, the determined orthokeratology lens data is transmitted to a doctor's terminal, and the data is transmitted to the lens manufacturing apparatus from the data, so that the orthokeratology lens can be manufactured and supplied to the doctor.

  That is, the above problem is solved by the following embodiment.

  (1) Wearing process in which an orthokeratology lens is mounted on the cornea at a position centered on the pupil of the patient with the head upright, and images of the orthokeratology lens moving on the cornea are continuously displayed. Or intermittently acquired image information acquisition process, from the acquired image information, a trial process of sequentially executing a movement data detection process for detecting the movement speed and movement direction of the orthokeratology lens for a plurality of orthokeratology lenses, It is determined whether or not the acquired moving speed and moving direction data are within a certain range, and in the case of the certain range, the selection process of selecting as an orthokeratology lens to be used for a patient is repeated, and the selected orthokeratology lens is As a registered lens, it consists of data of lens correction D of the registered lens at a location in contact with the cornea From recording lens correction D data, registration cornea D data consisting of D data of the cornea before wearing the registration lens at the contact point, registration cornea diameter data consisting of patient cornea diameter data, and patient pupil diameter data The registered patient data including at least the registered cornea D data among the registered pupil diameter data, and whether the registered lens is a lens attached to the cornea at any stage after the first correction stage or the second stage in a plurality of correction stages. A database construction process for building a lens database by storing registration stage data comprising data shown, patient corneal D data comprising corneal D data to be corrected by the patient, patient corneal diameter data comprising corneal diameter data, and Patient data including at least patient cornea D data out of patient pupil diameter data composed of pupil diameter data. A patient data acquisition process, and a patient stage data acquisition process for acquiring patient stage data indicating which of the orthokeratology lenses is mounted in a plurality of correction stages to the cornea to be corrected. From the lens database, the registered lens having the same registration stage data as the registration cornea D data and the patient stage data closest to the acquired patient cornea D data is detected, and the detected registration lens is detected by the patient. A lens determination process for determining an orthokeratology lens to be used in the process, a registration lens correction D data transmission process for transmitting the registered lens correction D data of the determined orthokeratology lens to a lens manufacturing apparatus, and the transmitted registration lens correction D data is received and based on this, the patient And a method of determining and supplying an orthokeratology lens, comprising: a lens manufacturing process for manufacturing an orthokeratology lens used by a person.

  (2) A selection device, a database server, a lens determination server connected to the database server, a terminal device connectable to the lens determination server, and a lens manufacturing device, wherein the selection device is A lens that captures an orthokeratology lens attached to the cornea at a position centered on the pupil of the patient with the head upright, and continuously or intermittently obtains an image of the state of moving on the cornea A lens for detecting lens movement data composed of at least moving speed and moving direction data of the orthokeratology lens from image information obtained by the photographing camera and the lens photographing camera and the orthokeratology lens moving on the cornea A lens movement data acquisition device including a movement data detection device, and whether or not the acquired lens movement data is within a certain range And a determination device that determines an orthokeratology lens in a certain range as an orthokeratology lens suitable for use in a patient, and the orthokeratology lens suitable for use in the patient as a registration lens. From the registered lens correction D data consisting of the lens correction D data at the location of contact with the patient's cornea, the registered cornea D data consisting of the D data of the cornea to be corrected at the location of contact, and the patient's cornea diameter data The registered patient data including at least the registered cornea D data among the registered cornea diameter data and the registered pupil diameter data, and the registered lens are attached to the cornea at any stage after the first stage or the second stage in a plurality of correction stages. Registration stage data consisting of data indicating whether the lens is And the database server stores the registered patient data and the registration stage data for the registered lens to construct a database, and the terminal device corrects the patient. Patient data acquisition for acquiring patient data including at least patient cornea D data among patient cornea D data including power cornea D data, patient cornea diameter data including corneal diameter data, and patient pupil diameter data including pupil diameter data Apparatus, patient stage data indicating whether the next orthokeratology lens is attached to the cornea at the first stage in the multiple correction stage or the stage after the second stage with respect to the cornea to be corrected by the patient A patient stage data acquisition device for acquiring the patient data and the patient stage data before The lens determination server detects the registered lens having the same registration stage data, the registered cornea D data closest to the patient stage data, the registered patient's cornea D data from the database. The lens manufacturing apparatus is configured to determine an orthokeratology lens to be used for a patient, and the lens manufacturing apparatus is configured to be mounted on the same patient as the registered lens based on the registered lens correction D data of the determined orthokeratology lens. Orthokeratology lens decision supply system, characterized in that it is configured to produce an orthokeratology lens for use in an apparatus.

  According to the present invention, similar data based on patient data including patient cornea D data of the patient's cornea, patient stage data of which stage orthokeratology lens for the same patient in multi-stage cornea correction Can be detected from a lens database to determine the optimal orthokeratology lens, and can be manufactured and quickly supplied to a remote physician, thus reducing patient burden and There is an effect that generation of useless lenses can be significantly suppressed.

The block diagram which shows the structure of the orthokeratology lens determination supply system based on the Example of this invention The block diagram which shows the structure of the database server in the Example Plan view schematically showing the movement state of an orthokeratology lens mounted on a patient's cornea Enlarged sectional view schematically showing the relationship between the patient cornea D in the patient data and the lens correction D in the orthokeratology lens in the case of myopia correction Enlarged sectional view schematically showing the relationship between the patient cornea D in the patient data and the lens correction D in the orthokeratology lens in the case of correction for hyperopia The block diagram which shows the structure of the lens determination server in the Example The block diagram which shows the structure of the terminal device in the Example The flowchart which shows the process which builds a database with the data obtained by the selection apparatus in the Example The flowchart which shows the process which determines and supplies the optimal orthokeratology lens in the lens determination server of an orthokeratology lens based on the data of a database, and the data from a terminal device in the Example. A graph showing the difference between cornea D data and lens correction D data when obtaining corrected lens correction D data Graph similar to FIG. 9A when the conditions are different A flowchart showing the process of determining an orthokeratology lens when the difference between patient data and registered patient data is large Flowchart showing the subroutine of the process shown in FIG.

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

  As shown in FIG. 1, an orthokeratology lens determination supply system (hereinafter referred to as a determination supply system) 10 for orthokeratology according to an embodiment of the present invention includes a selection device 20, a database server 30, and a lens determination that is a main server. A server 50, a lens manufacturing apparatus 50C connected to the lens determination server 50, a terminal device 70 connectable to the lens determination server 50, and a terminal side lens manufacturing apparatus 74 are configured.

  First, an outline of the mutual relationship between the above-described components will be described.

  In the decision supply system 10 according to the embodiment, in the selection device 20, data on the movement direction and speed of the orthokeratology lens mounted on the cornea of the patient immediately after the mounting is acquired by the lens movement data acquisition device 22. It is determined by the determination device 28 whether or not it is optimal for the cornea.

  The database server 30 is configured to repeat the process of storing orthokeratology lens (registered lens) data for which the determination result is usable (positive) and patient cornea data to construct the database 30B (see FIG. 2). ing.

  As shown in FIG. 1, the terminal device 70 and the terminal-side lens manufacturing device 74 are disposed at a position distant from the lens determination server 50, for example, a doctor 72 such as a remote place overseas or in Japan. . The terminal device 70 is configured to be able to transmit patient data including patient cornea D data in the patient's cornea acquired by the measurement of the doctor 72 to the lens determination server 50.

  The lens determination server 50 detects a registered lens having data similar to the received patient data from the database 30B of the database server 30, and determines this as an optimal orthokeratology lens.

  When the orthokeratology lens is determined by the lens determination server 50, as shown in FIG. 1, it is transmitted to the lens data reception / transmission device 73 of the terminal device 70, and from here, it is manufactured together with the lens data of the determined orthokeratology lens. The instruction signal is output to the terminal side lens manufacturing apparatus 74, and the terminal side lens manufacturing apparatus 74 manufactures an orthokeratology lens having the lens data. The doctor 72 acquires the manufactured orthokeratology lens and uses it for the patient.

  When the orthokeratology lens is not manufactured by the terminal side lens manufacturing apparatus 74, the orthokeratology lens is manufactured by the lens manufacturing apparatus 50C, and the manufactured orthokeratology lens receives the patient data via the lens shipping organization 50D. It is sent to a doctor 72 who manages and operates the terminal device 70 that has transmitted it and wants to correct the cornea of the patient using the orthokeratology lens.

  Table 1 shows output data from the lens movement data acquisition device 22, data output from the selection device 20 and stored in the database server 30, and data output from the terminal device 70 and input to the lens determination server 50. Indicates the type.

  Next, details of each device in the decision supply system 10 will be sequentially described.

  As shown in FIG. 1, the selection device 20 includes a patient data acquisition device 20B including a keratometer (not shown), a lens movement data acquisition device 22 including a lens photographing camera 24 and a lens movement data detection device 26, and a determination device. 28. In FIG. 1, reference numeral 20A denotes IF means, 21A denotes a keyboard, 21B denotes a display, and 21C denotes a printer.

  The lens photographing camera 24 photographs an orthokeratology lens attached to the cornea at a position centered on the pupil of the patient with the head upright, and continuously or intermittently displays an image moving on the cornea. Have been to get.

  The lens movement data detection device 26 detects lens movement data including at least movement speed and movement direction data from an image obtained by the lens photographing camera 24 in which the orthokeratology lens moves on the cornea. Yes.

  The lens movement data acquired by the lens movement data acquisition device 22 including the lens movement data detection device 26 is determined by the determination device 28 to determine whether it is within a certain range, and an orthokeratology lens within the certain range is used for the patient. Is determined to be suitable.

For example, as shown in FIG. 3, the above-mentioned fixed range means that the moving speed exceeds 0 mm and is 10 mm / second or less, and the moving direction V is within 6 degrees to the right or left from the perpendicular line Pe below the pupil Pu. When the condition of the angle θ is satisfied. Code O _L0 of FIG. 3 shows the orthokeratology lens at the position of the pupil Pu, O _L1 shows a state that has moved in the V direction from the position of the pupil Pu.

  While the patient is sleeping or getting up, the orthokeratology lens that descends from the pupil position is returned to the pupil position by blinking, but if the above conditions are not met, i.e. if it descends too fast or moves significantly diagonally Even if it blinks, it does not return to the pupil position. When the moving speed is 0, the orthokeratology lens is in close contact with the cornea and the amount of oxygen supplied to the cornea is reduced, which is inappropriate. The maximum moving speed of 10 mm / second and the angle of 6 degrees are based on the treatment data of 10,000 people or more implemented by the present inventors.

  For the determination device 28, whether the orthokeratology lens used for the patient is the first lens mounted on the cornea at the first stage in the multiple correction stage or the lens mounted on any stage after the second stage Stage data is input from the keyboard 21A, for example.

  In addition, the selection device 20 uses the lens correction D data, the lens movement data, and the stage data for the orthokeratology lens (registered lens) that has been determined to be suitable for use by the patient, at a location that contacts the patient's cornea. And near-field data indicating whether myopia correction or far-presbyopia correction, corneal D data consisting of corneal D data of the cornea to be corrected at the contact point, corneal diameter data and pupil diameter Patient data including the pupil diameter data is output to the database server 30.

  The database server 30 stores the input data for the orthokeratology lens as registered lens movement data, registered lens correction D data, registration stage data, registered lens movement data, registered near distance data, and registered cornea D data, respectively. The registered patient data including the registered corneal diameter data and the registered pupil diameter data is accumulated as shown in Table 2, for example, and the database 30B is constructed.

Here, diopter (D) is, as the smaller, the lens and the radius of curvature R of the cornea, since r is increased, the relationship of the lens Di opt Lee D _R to the cornea diopter D _r in the case of myopia correction, in Figure 4A As shown, D _r > D _R , that is, r <R, and in the case of hyperopia correction, as shown in FIG. 4B, D _r <D _R , that is, r> R, and the difference between the two D _r- D _R or D _R -D _r differs depending on what number stage of multi-step correction, and the first stage is the largest.

  More specifically, as shown in FIG. 2, the database server 30 includes IF means 30A, control means 40, and a database 30B. In FIG. 2, reference numeral 40A denotes a keyboard, 40B denotes a display, and 40C denotes a printer.

  The control means 40 includes a registered lens correction D data reception function 41, a registered lens movement data reception function 42, a registration stage data reception function 43, a registered patient data reception function 44, and a registered cornea / lens D difference data calculation means 45. And is configured.

  The database 30B includes a registered lens correction D data storage unit 31, a registered lens movement data storage unit 32, a registration stage data storage unit 33, a registered patient data storage unit 34, and a registered cornea / lens D difference data storage unit. 35.

  In this specification, for example, the registered lens correction D data receiving function 41 constitutes a registered lens correction D data receiving means together with the IF means 30A. That is, the function constitutes a means together with the IF means.

  The registered lens correction D data reception function 41 in the database server 30 is configured to receive registered lens correction D data transmitted from the selection device 20 via the IF means 30A. The accepted registered lens correction D data is stored in the registered lens correction D data storage means 31 in the database 30B.

  Similarly, the registered lens movement data transmitted from the selection device 20 is received by the registered lens movement data receiving function 42 and stored in the registered lens movement data storage unit 32. The registration stage data transmitted from the selection device 20 is received by the registration stage data reception function 43 and stored in the registration stage data storage means 33. The registered patient data is received by the registered patient data reception function 44 and stored in the registered patient data storage means 34. The registered cornea / lens D difference data calculating means 45 calculates the difference between the registered cornea D data and the registered lens correction D data in the registered patient data, and the numerical value of the calculation result is expressed as cornea / lens D difference data. It is stored in the registered cornea / lens D difference data storage means 35.

  Next, details of the lens determination server 50 shown in FIG. 5 will be described.

  The lens determination server 50 includes an IF unit 50A, a control unit 60, and a storage device 50B. In FIG. 5, reference numeral 60A denotes a keyboard, 60B denotes a display, and 60C denotes a printer.

  For the control means 60, a signal from the terminal device 70 is received by the corresponding function in the control means 60 via the Internet 14 and the IF means 50A.

  Further, a signal is manually input from the keyboard 60A to the control means 60 via the IF means 50A.

  The control means 60 includes a terminal setting information reception function 61, a patient data reception function 62, a patient stage data reception function 63, a lens photographing camera possession information reception function 63A, a database search means 64, and a corrected lens correction D data calculation. Means 65, correction data lens determination means 66, test lens data creation means 66A, lens manufacturing instruction function 67, determination lens data request reception transmission function 67A, lens completion information reception function 68, and lens return information reception function 69 and a determination test lens data receiving function 69A.

  The storage device 50B includes a terminal information storage unit 51, a patient data storage unit 52, a patient stage data storage unit 53, a decision lens data request storage unit 53A, a lens photographing camera possession information storage unit 53B, and a corrected lens correction D. Data storage means 54, correction data lens storage means 55, test lens data storage means 55A, decision lens storage means 56, lens manufacturing instruction information storage means 57, completed lens information storage means 58, and lens return information storage Means 59 and decision test lens data storage means 59A are provided.

  As shown in FIG. 6, the terminal device 70 includes a patient data acquisition device 71, a control device 80 including a patient data transmission function 84, and a storage device 90. In FIG. 6, reference numeral 70A denotes IF means, 80A denotes a keyboard, 80B denotes a display, and 80C denotes a printer.

  The control device 80 includes a terminal registration information transmission function 81, a patient data reception function 82, a patient stage data reception function 83, the patient data transmission function 84, a patient stage data transmission function 85, and a lens reception information reception function 86. A lens return information transmission function 87, a determination test lens information transmission function 88, and a lens data request transmission function 89A, a lens data reception function 89B, and a lens data transmission that constitute the lens data reception transmission device 73 together with the IF means 70A. And a function 89C.

  The storage device 90 includes a terminal registration information storage unit 91, a patient data storage unit 92, a patient stage data storage unit 93, a data transmission storage unit 94, a lens reception information storage unit 95, and a lens return information storage unit 96. The determination test lens information storage means 97 and the lens data request information storage means 98 are provided.

  The terminal device 70 is used by the contracted doctor 72 with respect to the lens determination server 50 serving as the headquarter server, and the terminal registration information transmission function 81 provides information indicating that it is under the control of the doctor 72 together with the password and ID. It is configured to transmit to the determination server 50. The terminal registration information is registered in the terminal registration information storage means 91 in the storage device 90. The terminal registration information includes information on whether or not the terminal device 70 includes a lens photographing camera similar to the lens photographing camera 24 in the selection device 20.

  The patient data reception function 82 is configured to receive patient data (patient data including patient cornea D data, corneal diameter, and pupil diameter) from the patient data acquisition device 71 via the IF unit 70A. The received patient data is configured to be stored in the patient data storage means 92. Of the patient data, the patient near distance data is input from the keyboard 80A.

  The patient stage data is input from the keyboard 80A and received by the patient stage data receiving function 83 via the IF means 70A, and this is stored in the patient stage data storage means 93.

  The patient data transmission function 84 stores the patient data stored in the patient data storage unit 92, and the patient stage data transmission function 85 converts the patient stage data stored in the patient stage data storage unit 93 into the IF unit 70A. The data is transmitted to the lens determination server 50 via the Internet 14. The transmission of these data is stored in the data transmission storage means 94.

  The lens reception information receiving function 86 is for receiving input of information indicating that the doctor 72 has received the orthokeratology lens by the operation of the doctor 72 via the keyboard 80A and the IF means 70A. This lens receipt information is stored in the lens receipt information storage means 95 in the storage device 90.

  The lens return information transmission function 87 is used to return the lens return information to be shot from the keyboard 80A when the doctor 72 returns the used orthokeratology lens that has been used for corneal correction and completed correction at that stage to the lens shipping organization 50D. Based on this, information indicating that the lens has been returned is transmitted to the lens determination server 50 via the IF means 70A and the Internet 14. This lens return information is stored in the lens return information storage means 96 in the storage device 90.

  The decision test lens information transmission function 88 tries to attach a plurality of sent test lenses (described later) to the patient, and informs the lens decision server 50 of the information of the test lens that is determined to be optimal for treatment. This information is stored in the determination test lens information storage means 97.

  When the doctor 72 requests lens data for manufacturing an orthokeratology lens used for a patient, the lens data request transmission function 89A transmits a request signal to the lens determination server 50, and the lens data reception function 89B. Is configured to transmit the data of the determined orthokeratology lens stored in the determined lens storage means 56 to the lens data reception / transmission device 73 via the IF means 50A.

  The patient data acquisition device 71 is configured to acquire patient data including patient cornea D data, corneal diameter data, and pupil diameter data of the cornea to be corrected by the patient. The patient data transmission function 84 is transmitted via the Internet 14. Patient data can be transmitted to the lens determination server 50.

  As the patient data acquisition device 71, specifically, Topcon (KP-8100PA) Auto Kerato-Refractometer, Ajinomoto Trading Co. Shin-Nippon (CT-1000) Corneal Topographer, or Oculuse (Oculuse) ) Use Pentacam Corneal Topographer, etc.

  The lens determination server 50 detects a registered lens used for the cornea of the same patient cornea D data as that of the cornea or the cornea of the closest patient cornea D data from the database 30B, and uses an orthokeratology lens having a curvature suitable for use by the patient. Is configured to be determined as

  Next, the database construction process and the process of determining the orthokeratology lens will be described with reference to FIGS.

  In the database construction process, as shown in step S101 in FIG. 7, the orthokeratology lens is mounted on the cornea to be corrected by the patient. At this time, the orthokeratology lens is mounted at a position around the pupil of the patient with the head upright. In this way, the orthokeratology lens descends along the corneal surface due to gravity, but in the relationship between the lens curvature of the orthokeratology lens on the contact surface and the corneal curvature of the cornea, it does not necessarily move vertically downward, Also, the speed is not uniform.

  As described above, the present inventor has a condition that the orthokeratology lens has a moving speed exceeding 0 mm and not more than 10 mm / second, and the moving direction is within an angle of 6 degrees to the right or left from the perpendicular line vertically below the pupil. When satisfied, it was found that it can be used to correct the cornea.

  Next, the process proceeds to step S102, where the lens imaging camera 24 captures an orthokeratology lens mounted on the patient's cornea, and continuously or intermittently acquires an image of the orthokeratology lens moving on the cornea. . Proceeding to step S103, movement data including the movement speed and movement direction of the orthokeratology lens is acquired by the lens movement data detection device 26 from the image information acquired by the lens photographing camera 24.

  Next, in step S104, the determination device 28 determines whether or not the acquired movement data is within a certain range. Specifically, it is determined whether the moving speed exceeds 0 and within 10 mm / second, and the moving direction determines whether the angle is within 6 degrees with respect to a perpendicular passing through the center of the patient's pupil.

  If the determination result is Yes, the process proceeds to the next step S105, where it is determined that the orthokeratology lens is a registered lens that can be used for corneal correction. If a determination result is No, it will progress to step S108.

  When it is determined in step S105 that the orthokeratology lens can be used for treatment, in the next step S106, the determination device 28 sets the orthokeratology lens as a registered lens, and the registered lens correction D data for the registered lens. The registered lens movement data, registration stage data, and registered patient data are transmitted to the database server 30.

  In the database server 30, the transmitted data is received by the registered lens correction D data reception function 41, the registered lens movement data reception function 42, the registration stage data reception function 43, and the registered patient data reception function 44, respectively. The correction D data storage means 31, the registered lens movement data storage means 32, the registration stage data storage means 33, and the registered patient data storage means 34 are stored. The database 30B is constructed by repeating the above process in this way.

  The control means 40 of the database server 30 calculates the difference between the patient's cornea D data and the lens correction D data of the orthokeratology lens for correcting the cornea from the registered patient data, and calculates the registered cornea / lens D difference data. The calculation can be performed by the means 45, and the calculation result is stored in the registered cornea / lens D difference data storage means 35 (see step S107).

  As described above, an orthokeratology lens is attached to the patient's cornea, whether or not the lens is usable is determined, and the process of storing the determination result in the database is repeated. In step S108, the next lens is If not, the database construction process is terminated, and if there is a next lens, the process proceeds to step S109, the next orthokeratology lens is attached, and the following steps S102 to S108 are repeated again.

  Next, a process of determining an orthokeratology lens optimal for patient correction in the lens determination server 50 based on data sent from the terminal device 70 using data stored in the database 30B of the database server 30 will be described. To do.

  As shown in FIG. 8, in step S201, the terminal device 70 acquires patient data including patient cornea D data, corneal diameter, and pupil diameter data of the patient to correct the cornea by the patient data acquisition device 71. Then, it is transmitted to the lens determination server 50 via the Internet 14 (see step S202).

  At this time, the doctor 72 inputs the data of which stage of the plurality of correction stages from the keyboard 80A of the terminal device 70 to the patient stage data reception function 83 through the IF means 70A. The When the doctor 72 needs lens data for manufacturing the orthokeratology lens determined by the lens determination server 50, lens data request information is input to the lens data request transmission function 89A.

  The patient data from the patient data acquisition device 71 is once received by the patient data reception function 82 via the IF unit 70A. The received patient data and patient stage data are stored in the patient data storage unit 92 and the patient data storage unit 92. Each is stored in the patient stage data storage means 93. The lens data request information is stored in the lens data request information storage means 98.

  The stored patient data and patient stage data are obtained by the patient data transmission function 84 and the patient stage data transmission function 85 in the control device 80 of the terminal device 70, and the lens data request information is obtained by the lens data request transmission function 89A. The data is transmitted to the lens determination server 50 via the means 70A and the Internet 14.

  In the lens determination server 50, the patient data and the patient stage data are received by the patient data receiving function 62 and the patient stage data receiving function 63 in the control means 60, and the patient data storing means 52 and the patient stage data storing in the storage device 50B, respectively. It is stored in the means 53. The lens data request information is received by the determined lens data request reception / transmission function 67A, and stored in the determination lens data request storage unit 53A in the storage device 50B. Furthermore, when the doctor 72 has a lens photographing camera equivalent to the lens photographing camera 24 at the time of contract with the doctor 72, the information is input from the lens photographing camera possession information reception function 63A and the lens photographing camera possessed. It is stored in the information storage means 53B.

  In step S203, based on the patient data or patient data and patient stage data sent from the terminal device 70 by the database searching means 64 of the lens determination server 50, the patient from the terminal device 70 is read from the database 30B in the database server 30. A registered lens having data identical or similar to the data and patient stage data is detected.

  Proceeding to step S204, it is determined whether or not the difference between the detected registered cornea D data in the registered lens and the patient cornea D data in the patient data from the terminal device 70 is equal to or smaller than a certain value (for example, 0.03D).

  If YES in step S205, the process advances to step S205 to store the registered lens in the determined lens storage unit 56 as a determined lens.

  Here, the “difference” is set to 0.01 mm of the radius of curvature of the cornea. This is because the detection accuracy limit of the measuring device is considered to be 0.01 mm. According to Table 3, when the radius of curvature is converted to diopter (D), it is 0.03D.

  If there are a plurality of registered lenses of Yes, the registration lens of the registered corneal diameter data and the registered pupil diameter data closest to the patient corneal diameter data and the patient pupil diameter data may be used as the determination lens.

  Proceeding from step S205 to step S205A, it is determined whether or not there is a lens data request from the doctor 72. If No, the process proceeds to step S206. In step S206, an instruction signal (lens data) for creating an orthokeratology lens having the same data as the stored determination lens is transmitted to the lens manufacturing apparatus 50C, where the orthokeratology lens is created.

  If Yes in step S205A, that is, if the determined lens data request information is stored in the determined lens data request storage unit 53A, the process proceeds to step S205B, and the instruction signal is transmitted to the lens data reception / transmission device 73 of the terminal device 70. In step S205C, an instruction signal is transmitted from the lens data reception / transmission device 73 to the terminal-side lens manufacturing device 74 to create an orthokeratology lens. That is, an orthokeratology lens is created remotely and used for treatment.

  In addition, the diopter (D) in the lens correction D data is converted according to the diopter / millimeter conversion table shown in Table 3, and is output as the curvature radius (mm) of the lens.

  The lens manufacturing apparatus 50C and the terminal-side lens manufacturing apparatus 74 are apparatuses that manufacture orthokeratology lenses based on the received data, and may be ordinary cutting-type contact lens manufacturing apparatuses or 3D printers. The terminal side lens manufacturing apparatus 74 is located in the vicinity of the doctor 72 or a lens manufacturer that cooperates with the doctor 72, and the lens manufacturing apparatus 50 </ b> C is disposed in the vicinity of the lens determination server 50.

  In step S207, the created orthokeratology lens is directly acquired by the doctor 72 or supplied from the lens manufacturer to the doctor 72. If there is no lens data request, the terminal device 70 is managed. It is sent to the doctor 72 via the lens shipping organization 50D.

  In the above step S204, if the determination result is No, the process proceeds to step S208. Steps S208 to S210 are executed as follows by the corrected lens correction D data calculation means 65 in the control means 60 of the lens determination server 50.

First, in step S208, as shown in FIGS. 9A and 9B, when a registered lens having data that most closely approximates the cornea D data is the first lens, the first registered cornea D data r ₁ for the lens Then, when the registered lens having the next approximate data is the second lens, a corneal D data difference r ₁ −r ₂ = ΔC from the second registered corneal D data r ₂ is obtained, and in the next step S209, A registered lens correction D data difference R ₁ −R ₂ = ΔL is obtained when the registered lens correction D data of the first lens and the second lens are R ₁ and R ₂ , respectively.

In step S210, the product of the difference Δr ₁ between the patient cornea D data r ₀ in the patient data and the registered cornea D data r ₁ in the first lens and ΔL / ΔC is obtained, and the registered lens correction D data in the first lens is obtained. subtracted or added to the R ₁ is adapted to calculate a correction lens correction D data.

That is, when the lens correction D per unit cornea D is obtained and multiplied by r ₀ −r ₁ = Δr ₁ , the lens correction D value (difference) corresponding to the difference between r ₀ and r ₁ is calculated, and D ₀ is It may be added to _{R 1.} For example, as shown in FIG. 9A, when r ₀ > r ₁ > r ₂ and R ₁ > R ₂ , D ₀ = (r ₀ −r ₁ = Δr ₁ ) × ΔL / ΔC + R ₁ . When r ₁ > r ₀ > r ₂ and R ₁ > R ₀ > R ₂ , D ₀ = R ₁ −Δr ₁ × ΔL / ΔC as shown in FIG. 9B.

  In the next step S211, it is determined whether the ΔL is equal to or smaller than a certain value, that is, whether the difference between the registered lens correction D data of the first lens and the second lens is too large. If it is too large, the reliability of the corrected lens correction D data is small. If the determination result is Yes, the process proceeds to step S212, and if No, the process proceeds to a subroutine (B: FIG. 10) described later.

  In step S212, the correction data lens determination unit 66 sets the correction orthokeratology lens having the calculated correction lens correction D data as the determination lens, and the data is represented by reference numeral A in FIGS. To the database 30B. Next, returning to step S205, the determined lens is stored in the storage device 50B, and in the next step S205A, it is determined whether or not there is a lens data request.

  The correction lens correction D data, the correction data lens, and the decision lens are respectively stored in the correction lens correction D data storage means 54, the correction data lens storage means 55, and the decision lens storage means 56 in the storage device 50B. It can also be part of the database.

  If the determination result in step S205A is Yes, the orthokeratology lens is supplied through steps S205B and S205C described above. If the determination result is No, the process proceeds to step S213.

  In step S213, the lens manufacturing instruction function 67 of the lens determination server 50 transmits a correction lens creation instruction signal having the calculated corrected lens correction D data to the lens manufacturing apparatus 50C. In step S213, the corrected lens is corrected. And proceed to step S207. In step S207, the corrected lens is shipped to the doctor 72 from the lens shipping organization 50D.

  Next, the case where the determination result is No in step S211 will be described.

  In this case, as indicated by reference numeral B, the process proceeds to step S301 shown in FIG.

  In step S301, the test lens data creation unit 66A calculates creation data for a plurality of test lenses.

  First, ΔL / m = αL, m is an integer of 3 ≦ m ≦ 10, and m types of correction D (corrected lens correction D + αL, corrected lens) are obtained by adding αL, 2αL,. Correction D + 2αL,... Correction lens correction D + mαL), and correction lens correction D, αL, 2αL,... M correction numerical values of corrected lens correction D-2αL,... Corrected lens correction D-mαL) are calculated.

  In the next step S302, it is determined whether or not there is a lens data request. If No, the process proceeds from the code D to the subroutine of FIG. 11, and if Yes, the process proceeds to step S303 and the test having the 2m type correction D is performed. The lens data is transmitted to the terminal device 70.

  In the next step S304, the test lens data is transmitted from the terminal device 70 to the terminal-side lens manufacturing device 74, and the test lens is manufactured.

  In step S305, the doctor 72 attaches a test lens to the patient.

  In the next step S306, the doctor 72 determines whether or not a lens photographing camera similar to the lens photographing camera 24 of FIG. 1 is included in the terminal device 70. If yes, the process proceeds to step S307, and the lens photographing camera is determined. Take a picture of the test lens attached to the patient.

  Proceeding to step S308, the movement data of the test lens is acquired from the image acquired by the above photographing. In the next step S309, the movement data is obtained from the terminal device 70 via the Internet 14 and the determination device 28 of the selection device 20. Send to.

  Proceeding to step S310, as an orthokeratology lens using the optimal test lens selected by the determination device 28 for treatment, the data is returned to the routine of FIG. 7 together with the patient data, as indicated by symbol A, and added to the database 30B. .

  Specifically, the selected orthokeratology lens data used for treatment is sent from the terminal device 70 to the lens determination server 50, received by the determination test lens data reception function 69A of the lens determination server 50, and the determination test lens. It is stored in the data storage means 59A. Further, the lens determination server 50 sends the data of the orthokeratology lens used for the treatment together with the patient data to the control means 40 of the database server 30 (see symbol A in FIGS. 10 and 7), and the data is sent to the database 30B. It is added as registered lens data and registered patient data.

  Returning to step S311, the optimal test lens data is sent to the terminal device 70, and the doctor 72 uses the test lens of the sent data for the patient.

  In the case of No in step S306, the process proceeds to step S310 as indicated by the symbol E. Here, as an orthokeratology lens that uses the optimum test lens selected by the doctor 72 for treatment, the data is added to the database 30B together with the patient data, and after step S311, the optimum test lens is obtained in step S312. Is used for patients.

  Next, when the determination result is No in step S302, the process proceeds to step S401 in the subroutine of FIG. This step S401 is the same as step S301 in FIG.

  In the next step S402, a test lens having the calculated 2m types of corrections D is created by the lens manufacturing apparatus 50C.

  Proceeding to step S403, the manufactured plurality of test lenses are sent to the doctor 72. In step S404, the doctor 72 attaches the test lens to the patient and uses the optimal test lens as an orthokeratology lens for treatment.

  In the next step S 405, orthokeratology lens data used for treatment is sent from the terminal device 70 to the lens determination server 50.

  Proceeding to the next step S406, the orthokeratology lens data used for the treatment together with the patient data is added to the database 30B.

  In addition, according to the clinical trial example of the present inventors, 6 to 10 types of test lenses having the 2m types of correction D are sufficient.

  In the decision supply system 10 of the above embodiment, the lens manufacturing apparatus 50C and the terminal side lens manufacturing apparatus 74 are provided, but the present invention is not limited to this, and only one of them is provided. Is also included.

  Further, the present invention is applied to both the case where the lens photographing camera 24 is included and the case where it is not included as a part of the terminal device 70.

  It can reduce the burden on the patient and can be used when determining and manufacturing an orthokeratology lens for corneal correction.

10 ... Orthokeratology lens decision supply system (decision supply system)
DESCRIPTION OF SYMBOLS 14 ... Internet 20 ... Selection apparatus 20A ... IF means 20B ... Patient data acquisition apparatus 21A, 40A, 60A, 80A ... Keyboard 21B, 40B, 60B, 80B ... Display 21C, 40C, 60C, 80C ... Printer 22 ... Lens movement data acquisition Device 24 ... Lens photographing camera 26 ... Lens movement data detection device 28 ... Determination device 30 ... Database server 30A ... IF means 30B ... Database 31 ... Registration lens correction D data storage means 32 ... Registration lens movement data storage means 33 ... Registration stage data Storage means 34 ... Registered patient data storage means 35 ... Registered cornea / lens D difference data storage means 40 ... Control means 41 ... Registered lens correction D data reception function 42 ... Registration lens movement data reception function 43 ... Registration stage data reception function 44 ... Registered patient data reception function 45 ... Registered cornea / lens D difference data calculation means 50 ... Lens determination server 50A ... IF means 50B, 90 ... Storage device 50C ... Lens manufacturing device 50D ... Lens shipping organization 51 ... Terminal information storage means 52 ... Patient Data storage means 53 ... Patient stage data storage means 53A ... Determination lens data request storage means 53B ... Lens photographing camera possession information storage means 54 ... Correction lens correction D data storage means 55 ... Correction data lens storage means 55A ... Test lens data storage means 56 ... Determined lens storage means 57 ... Lens manufacturing instruction information storage means 58 ... Completed lens information storage means 59 ... Lens return information storage means 59A ... Determination test lens data storage means 60 ... Control means 61 ... Terminal setting information reception function 62 ... Patient Data reception function 63 ... Patient stage Data reception function 63A ... Lens photographing camera possession information reception function 64 ... Database search means 65 ... Correction lens correction D data calculation means 66 ... Correction data lens determination means 66A ... Test lens data creation means 67 ... Lens manufacturing instruction function 67A ... Determination Lens data request reception / transmission function 68 ... Lens completion information reception function 69 ... Lens return information reception function 69A ... Determination test lens data reception function 70 ... Terminal device 70A ... IF means 71 ... Patient data acquisition device 72 ... Doctor 73 ... Lens data reception Transmission device 74 ... Terminal side lens manufacturing device 80 ... Control device 81 ... Terminal registration information transmission function 82 ... Patient data reception function 83 ... Patient stage data reception function 84 ... Patient data transmission function 85 ... Patient stage data transmission function 86 ... Lens reception Information reception function 87 ... Lens Transmission information transmission function 88 ... Determination test lens information transmission function 89A ... Lens data request transmission function 89B ... Lens data reception function 89C ... Lens data transmission function 91 ... Terminal registration information storage means 92 ... Patient data storage means 93 ... Patient stage data storage Means 94 ... Data transmission storage means 95 ... Lens reception information storage means 96 ... Lens return information storage means 97 ... Determination test lens information storage means 98 ... Lens data request information storage means

Claims (25)

Wearing process in which an orthokeratology lens is mounted on the cornea at a position centered on the patient's pupil with the head upright, images of the orthokeratology lens moving on the cornea continuously or intermittently An image information acquisition process to be acquired, a movement data detection process for detecting a movement speed and a movement direction of the orthokeratology lens from the acquired image information, a trial process for sequentially executing a plurality of orthokeratology lenses, the acquired It is determined whether or not the data of the moving speed and moving direction are within a certain range, and in the case of the certain range, the selection process of selecting as an orthokeratology lens to be used for a patient is repeated, and the selected orthokeratology lens is used as a registered lens. , A registration label comprising lens correction D data of the registration lens at a position where it contacts the cornea. Correction D data, registration cornea D data consisting of D data of the cornea before wearing the registration lens at the contact point, registration cornea diameter data consisting of patient cornea diameter data, and pupil diameter data of the patient The registered patient data including at least the registered cornea D data among the registered pupil diameter data, and whether the registered lens is a lens attached to the cornea at any stage after the first correction stage or the second stage in the multiple correction stage. A database construction process for storing registration stage data consisting of data and constructing a lens database;
Patient data including at least patient corneal D data among patient corneal D data including corneal D data to be corrected, patient corneal diameter data including corneal diameter data, and patient pupil diameter data including pupil diameter data Patient data acquisition process to acquire,
Patient stage data acquisition process for acquiring patient stage data as to which stage of the orthokeratology lens this time the mounting of the orthokeratology lens is to be performed on the cornea to be corrected by the patient;
From the lens database, a registration lens having the same registration stage data as the registration cornea D data and patient stage data closest to the acquired patient cornea D data is detected, and the detected registration lens is sent to the patient. The lens determination process to determine as the orthokeratology lens to be used,
A registration lens correction D data transmission process of transmitting the registered lens correction D data of the determined orthokeratology lens to a lens manufacturing apparatus;
A lens manufacturing process for receiving the transmitted registration lens correction D data and manufacturing an orthokeratology lens used for the patient based on the received registration lens correction D data;
A method for determining and supplying an orthokeratology lens comprising: In claim 1,
In the patient data acquisition process and the patient stage data acquisition process, a patient data transmission process of transmitting the acquired patient data and the patient stage data to a lens determination server that executes the lens determination process via the Internet. A method for determining and supplying an orthokeratology lens, comprising: In claim 1,
In the lens manufacturing process, the registration lens correction D data transmitted in the registration lens correction D data transmission process is received by a terminal device that executes the patient data acquisition process, and the received registration lens correction D is received. An orthokeratology lens decision supply method comprising a registered lens correction D data transmission step of transmitting data to the lens manufacturing apparatus. In claim 2,
In the registration lens correction D data transmission process, the registration lens correction D data is transmitted from the lens determination server via the Internet or directly to the lens manufacturing apparatus, and the manufactured orthokeratology lens is transmitted to the patient. A method for determining and supplying an orthokeratology lens, characterized in that: In any one of Claims 1 thru | or 4,
The registered patient data in the database construction process includes registered near distance data consisting of data indicating whether the registered lens is for correcting myopia or correcting for presbyopia,
The patient data in the patient data acquisition process includes patient near distance data composed of data indicating whether the lens is for myopia correction or for hyperopia correction,
The lens determination process includes registration cornea D data closest to the acquired patient cornea D data from the lens database, patient near-field data, and registration near-field data and registration stage data identical to the patient stage data. A method for determining and supplying an orthokeratology lens, wherein the registration lens is detected, and the detected registration lens is determined as an orthokeratology lens to be used for a patient. In any one of Claims 1 thru | or 5,
In the selection process in the database construction process,
When the moving speed exceeds 0 and is 10 mm / second or less, and the moving direction satisfies the condition of an angle of 6 degrees to the right or left from the perpendicular line below the pupil, it is selected as an orthokeratology lens used for the patient. A method of determining and supplying an orthokeratology lens. In any one of Claims 1 thru | or 6.
In the database construction process, the cornea / lens D difference data which is the difference between the cornea patient cornea D data before wearing the orthokeratology lens and the registered lens correction D data of the worn orthokeratology lens is stored, and the lens database is stored. A method for determining and supplying an orthokeratology lens, characterized by being constructed. In any one of Claims 1 thru | or 7,
In the lens determination process, when the difference between the acquired patient cornea D data and the nearest registered cornea D data is equal to or greater than a predetermined value, the detected registered lens is set as the first lens and the acquired The registered lens having the registered cornea D data second closest to the patient cornea D data is the second lens, and the registered cornea D data and the registered lens correction D data are the first cornea D data in the first lens. And the first lens correction D data, and in the second lens, the second cornea D data and the second lens correction D data,
From the ratio of the cornea D difference data between the first cornea D data and the second cornea D data and the lens correction D difference data between the first lens correction D data and the second lens correction D data, The lens D difference per unit cornea D data difference is obtained, and the product of the lens D difference and the difference between the patient cornea D data and the first cornea D data in the acquired patient data is the first lens correction D data. A method for determining and supplying an orthokeratology lens, wherein the correction lens D data is obtained in addition to or subtracted, and the orthokeratology lens having the correction lens D data is used as an orthokeratology lens for a patient. In claim 8,
When the lens D difference ΔL between the first lens correction D data and the second lens correction D data is greater than or equal to a certain value, ΔL / m = αL, where m is an integer of 3 ≦ m ≦ 10, and the correction lens D A process of calculating m kinds of correction D obtained by adding αL, 2αL,..., MαL to the data, and m correction D values obtained by subtracting αL, 2αL,. A process of creating a test lens having each of the 2m types of correction D, and a process of mounting the 2m type of test lens on a patient to form an orthokeratology lens using an optimal test lens for treatment. Determined supply method of orthokeratology lens. In claim 9,
A test lens data transmission process for transmitting data of a test lens having the 2m type correction D to the lens manufacturing apparatus, and a test lens manufacturing for manufacturing a test lens by the lens manufacturing apparatus based on the transmitted test lens data Process,
A method for determining and supplying an orthokeratology lens comprising: In any one of Claims 8 thru | or 10.
In the database construction process, the lens database is constructed by storing lens D data, patient data and stage data for the orthokeratology lens determined based on the lens D difference, and constructing a lens database. Decision supply method. In claim 8,
A method for determining and supplying an orthokeratology lens, comprising: a lens manufacturing process for manufacturing a corrected orthokeratology lens based on the corrected lens D data. A selection device, a database server, a lens determination server connected to the database server, a terminal device connectable to the lens determination server, and a lens manufacturing device;
The selection device is:
Lens photography that captures an orthokeratology lens attached to the cornea at a position centered on the pupil of the patient with the head upright, and continuously or intermittently captures an image moving on the cornea Lens movement for detecting lens movement data composed of at least moving speed and moving direction data of the orthokeratology lens from image information obtained by the camera and the lens photographing camera and the orthokeratology lens moving on the cornea A lens movement data acquisition device including a data detection device and whether or not the acquired lens movement data is within a certain range, and determine a certain range of orthokeratology lens as an orthokeratology lens suitable for use in a patient And an orthokeratology lens suitable for use with the patient as a registered lens. , For the registered lens, registered lens correction D data consisting of data of lens correction D at a location where the patient contacts the cornea, and registered cornea D data consisting of D data of the cornea to be corrected at the location where the contact is made, The registered patient data including at least the registered cornea D data among the registered cornea diameter data and the registered pupil diameter data made up of the patient's cornea diameter data, and the registered lens are either the first stage or the second stage or later in the multiple correction stage. Registration stage data consisting of data indicating whether the lens is attached to the cornea at the stage, and output to the database server,
The database server is
Storing the registered patient data and the registration stage data for the registered lens, and constructing a database;
The terminal device
Patient data including at least patient cornea D data is acquired from patient cornea D data composed of D data of the cornea to be corrected, patient cornea diameter data composed of corneal diameter data, and patient pupil diameter data composed of pupil diameter data. The patient data acquisition device, whether the next orthokeratology lens is attached to the cornea at the first stage in a plurality of correction stages or the stage after the second stage with respect to the cornea to be corrected by the patient A patient stage data acquisition device that acquires patient stage data of the patient, and is capable of transmitting the patient data and patient stage data to the lens determination server,
The lens determination server is
The acquired patient cornea D data from the database, the registered cornea D data closest to the patient stage data, and a registered lens having the same registered stage data are detected and determined as an orthokeratology lens used for the patient. And
The lens manufacturing apparatus is configured to manufacture the same orthokeratology lens for patient wearing as the registered lens, based on the registered lens correction D data of the determined orthokeratology lens. Determines and supplies orthokeratology lenses. In claim 13,
The terminal device receives the registered lens correction D data of the registered lens corresponding to the determined orthokeratology lens transmitted from the lens determination server, and the received registered lens correction D data is the lens manufacturing An orthokeratology lens decision supply system comprising a lens data reception and transmission device configured to output to a device. In claim 14,
An orthokeratology lens determination and supply system, wherein the lens manufacturing apparatus is provided attached to the terminal device. In claim 15,
The terminal device has an orthokeratology function that requests the lens determination server to transmit lens data of the registered lens determined as an orthokeratology lens to the terminal device. Lens decision supply system. In claim 13,
An orthokeratology lens decision supply system, wherein the lens manufacturing apparatus is configured to receive the registered lens correction D data from the lens decision server via the Internet or directly. In any of claims 13 to 17,
Furthermore,
The selecting device is configured to output registered near distance data consisting of data indicating whether the registered lens is for correcting myopia or correcting for presbyopia to the database server,
The database server is configured to store the registered near-field data to construct a database;
The terminal device is capable of transmitting patient near distance data consisting of data indicating whether the lens is for myopia correction or for hyperopia correction to the lens determination server,
The lens determination server detects a registered lens having the acquired patient cornea D data and patient near distance data, the registered cornea D data closest to the patient stage data, the same registered near distance data, and registered stage data from the database. And determining and supplying an orthokeratology lens, which is configured to be determined as an orthokeratology lens to be used for a patient. In claim 18,
The determination device uses orthokeratology for a patient when the moving speed exceeds 0 and is equal to or less than 10 mm / second and the moving direction satisfies an angle of 6 degrees to the right or left from the perpendicular line below the pupil. -A decision supply system for orthokeratology lenses, which is configured to be selected as a lens. In claim 18 or 19,
The database server stores the cornea / lens D difference data, which is the difference between the cornea patient cornea D data before wearing the orthokeratology lens and the registered lens correction D data of the attached orthokeratology lens, and constructs a lens database An orthokeratology lens determination and supply system characterized by being configured to In any of claims 18 to 20,
When the difference between the acquired patient cornea D data and the registered cornea D data closest thereto is a predetermined value or more, the lens determination server sets the detected registered lens as a first lens and acquires the acquired lens. The registered lens having the registered cornea D data second closest to the patient cornea D data in the patient data is the second lens, and the registered cornea D data and the registered lens correction D data are the first lens 1 cornea D data and first lens correction D data, and in the second lens, second cornea D data and second lens correction D data,
From the ratio of the cornea D difference data between the first cornea D data and the second cornea D data and the lens correction D difference data between the first lens correction D data and the second lens correction D data, The lens correction D difference per unit cornea correction D data difference is obtained, and the product of the lens correction D difference and the difference between the patient cornea D data and the first cornea D data in the acquired patient data is the first lens. An orthokeratology characterized in that the corrected lens correction D data is obtained in addition to or subtracted from the correction D data, and the orthokeratology lens having the corrected lens correction D data is used as an orthokeratology lens for a patient. -Lens decision supply system. In claim 21,
When the lens D difference ΔL between the first lens correction D data and the second lens correction D data is equal to or greater than a predetermined value, the lens determination server sets ΔL / m = αL, m to an integer of 3 ≦ m ≦ 10. Numerical values of m types of correction D obtained by adding αL, 2αL... MαL to the corrected lens correction D, and m types of correction D obtained by subtracting αL, 2αL. And a determination lens supply system for orthokeratology lenses, wherein data for manufacturing test lenses each having the 2m kinds of corrections D are output. In claim 22,
An orthokeratology lens determination supply system, wherein the lens determination server is configured to transmit manufacturing data of test lenses each having the 2m types of corrections D to the lens manufacturing apparatus. In claim 21,
The database server includes corrected lens correction D data, patient data, and patient stage data for an orthokeratology lens determined based on the lens correction D difference data, respectively, as registered lens correction D data, registered patient data, and registered stage. An orthokeratology lens determination and supply system configured to store as data and to construct a lens database. 25. Any one of claims 18 to 24.
Determination of an orthokeratology lens, wherein the lens movement data detection device is an image analysis device, and the selection device is a central control device in which data of allowable values of movement speed and movement direction is stored in advance. Supply system.

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