JP4459642B2 - Electronic medical record input system, program for causing computer to execute electronic medical record creation process, and computer-readable information recording medium recording the program - Google Patents

Description

  The present invention relates to an electronic medical record input system, a program that causes a computer to execute an electronic medical record creation process, and a computer-readable information recording medium that records the program. More specifically, an electronic medical record input system capable of inputting a test result of a Hess test used to identify an eye movement disease of an eye to be examined, a program for causing a computer to execute an electronic medical record creation process, and a computer reading recording the program The present invention relates to a possible information recording medium.

  In recent years, computerization of information management in the medical field has been progressing rapidly. For example, by creating a so-called electronic medical chart for each patient and making it available on the network, it is possible to improve the efficiency of medical chart management, sharing information to obtain the opinion of doctors other than the attending physician, and disclosure of information to patients We are trying to promote. In addition, in order to improve the efficiency of medical office work, electronic billing information is also progressing. Typically, information is centrally managed by configuring computer terminals and various inspection devices provided in waiting rooms, radiographing rooms, examination rooms, clinics, etc. in a clinic so that they can be connected to a LAN server.

  As an example of such an electronic medical record input system, one described in Patent Document 1 below is known. The system described in this document inputs a comment to a schema image, and displays a link symbol indicating a correspondence with a comment instead of a comment for the schema image on a diagnosis record screen including character information. A first electronic medical record screen in which a schema recording screen to which a symbol is assigned, a comment screen in which a link symbol and a comment are associated, and a schema recording screen that is inserted in the first electronic medical record screen One of the two types of electronic medical record screens is displayed, including a second electronic medical record screen in which a schema recording screen with comments, which is relatively larger in size, is inserted into the examination recording screen. Electronic medical record screen switching means is provided.

  By the way, since there are many types of examinations in the ophthalmology field, it is necessary to devise an input method for each examination in order to improve the efficiency of inputting examination results into the electronic medical record. As an example of an ophthalmic examination, a Hess test (also called a Hess screen test) for examining eye movements of an eye to be examined is widely used.

  As an apparatus used for the Hess test, for example, an eye movement inspection apparatus disclosed in Patent Document 2 below is known. The apparatus described in the document includes a fixation target display means capable of displaying fixation targets at a plurality of locations on a (Hes) screen, and an instruction for projecting and displaying an indication target on the screen. A target projecting means, causing one of the fixation targets to be fixed with one eye of the subject, and causing the point determined by the other eye to be indicated by the indicating target. An eye movement inspection apparatus for measuring a deviation in the viewing direction of both eyes, wherein the projection direction of the pointing target by the pointing target projection means can be changed around a first rotation center point, A first optical member that reflects and transmits the light beam is disposed on the visual light path of the screen by the subject to which the projected light beam of the pointing target is guided, and any point on the first optical member The optical path distance between the first optical member and the first rotation center point is By positioning the first rotation center point so as to be substantially equal to the optical path distance between the optical member of the subject and the midpoint between the rotation centers of the left and right eyes of the subject, the first optical member The projection optical path of the pointing target that is allowed to pass through the same point on the screen and the visual light path of the screen by the subject are substantially matched between the first optical member and the screen. It is characterized by that.

  The Hess test is performed as follows using such an eye movement test apparatus. First, a red grid-like Hess screen is presented to the subject in a dark room, and a red lens is worn on the right eye and a green lens is worn on the left eye. On the Hess screen, a total of nine red reference points for fixation (fixation targets) are arranged at the intersections of six straight lines that form the shape of a “field”. The examiner uses the green arrow at the tip of the pointing rod on hand or the pointing target projected on the Hess screen to indicate the position where the non-fixed eye has localized each reference point. Enter the indicated position (indicated point) on the inspection form. A plurality of curves are printed on the inspection paper so as to form a grid as in the case of a Hess screen. The examiner specifies a disease of eye movement of the eye to be examined by connecting a plurality of designated points entered on the examination form with straight lines to form a Hess figure and analyzing the formation state of the Hess figure. The term “Hess figure” is used in, for example, Non-Patent Document 1 described later.

  The Hess test carried out in this way is a red hess screen that is visible only with a fixation eye wearing a red lens, and a green arrow or pointing target only with a non-fixation eye wearing a green lens. Hess that is localized by the fovea of the non-fixed eye wearing a green lens with the red reference point visible in the fovea of the fixed eye wearing the red lens. -The position on the screen (viewing direction) is indicated by a pointing target or the like, and the positional deviation between the right and left eyes is examined by taking into account the deviation between the indicated position (indicating point) and the reference point. .

  When inputting Hess test results using a conventional electronic medical record input system, the handwritten inspection paper is captured by the scanner and stored as image data, and the points and instructions are the same as when handwritten on the inspection paper. A method has been used in which a straight line connecting points is manually input to a computer to form a Hess figure.

  However, in the former method using a scanner, if such a large amount of images are stored, the burden on the storage capacity of the database increases, and the work of converting the handwritten inspection paper into electronic data is involved, which is troublesome twice. For this reason, a burden is imposed on the user in terms of work efficiency. Furthermore, since it is necessary to store the handwritten original, it was necessary to prepare a storage space for it.

  In addition, the latter method of manually inputting the indication points and the straight lines connecting them to the computer is not as efficient as handwriting on the inspection sheet, especially for examiners who are not familiar with computer use. In particular, much longer time had to be spent on input work.

  In addition, there are many cases where skill is required to identify abnormal eye movements using a Hess test, such as when there are restrictions on eye movements in both eyes of the subject. It was difficult to make a correct diagnosis from the test results.

Japanese Patent No. 3347047 (claim) JP-A-8-80283 (claim) Izumi Yukio, "Basics of Binocular Visual Function Test", Optic Optical Publishing Co., Ltd., published on November 25, 1986, page 83

  The present invention has been made in view of such circumstances, and an electronic medical record input system and electronic medical record creation process capable of efficiently performing the work of inputting the test result of the Hess test into the electronic medical record. It is an object to provide a program to be executed and a computer-readable information recording medium in which the program is recorded.

  The present invention also relates to an electronic medical record input system capable of supporting identification of a disease based on a test result of a Hess test, a program for causing a computer to execute an electronic medical record creation process, and a computer readable recording of the program Another object is to provide an information recording medium.

  In order to achieve the above-mentioned object, the invention according to claim 1 is configured such that a server having a database for storing the electronic medical record of each patient can be communicated with the server via a network, and information input to the electronic medical record is performed. A display means for displaying an input screen to be performed, and includes an electronic medical record input terminal for generating electronic medical records by transmitting input information to the input screen to the server through the network, and a plurality of screens provided on the screen When one eye of the subject is fixed for each reference point, a straight line is provided between a plurality of indication points obtained by instructing the subject on the position on the screen that is localized by the other eye. An electronic medical record input system for inputting a test result into an electronic medical record for a Hess test for identifying a disease of an eye movement of a subject eye with reference to a hess figure formed by tying, The display means displays an input template screen for a user to input the plurality of instruction points obtained by the Hess test in a predetermined order, and receives an input of the plurality of instruction points on the input template screen. And a display control means for displaying the straight line forming the Hess figure on the input template screen as the inspection result.

  In order to achieve the above object, the invention described in claim 2 is the electronic medical record input system according to claim 1, wherein the display control means is a coordinate system set on the input template screen. A straight line calculating means for calculating the length and inclination of the straight line based on the coordinates of the designated point in the display, and displaying the straight line on the input template screen based on a calculation result by the straight line calculating means. Yes.

  In order to achieve the above object, the invention according to claim 3 is the electronic medical record input system according to claim 1, wherein the display control means sets the indication point on the input template screen. In response to the input outside the effective display frame, instead of the straight line connecting the designated point and another designated point, an arrow in a direction from the other designated point toward the designated point is displayed. It is characterized by that.

  In order to achieve the above object, the invention according to claim 4 is the electronic medical record input system according to claim 1, wherein a plurality of indication points are displayed on the input template screen with respect to the same reference point. Displacement calculating means for calculating a displacement between the last indicated point among the plurality of designated points and the designated point inputted immediately before the designated point, and the displacement calculated by the displacement calculating means A displacement determining means for determining whether or not the displacement is greater than or equal to a predetermined allowable value; and when the displacement determining means determines that the displacement is greater than or equal to the predetermined allowable value, retesting the Hess test And a re-inspection setting means for setting the input template screen in a state in which the designated point can be input.

  In order to achieve the above object, the invention according to claim 5 is the electronic medical record input system according to claim 4, which corresponds to the setting of the re-inspection by the re-inspection setting means. The display device further includes display color setting means for displaying a plurality of designated points corresponding to the same reference point in different colors.

  In order to achieve the above object, the invention described in claim 6 is a server provided with a database for storing each patient's electronic medical record, and is capable of communicating with this server via a network, and information about the electronic medical record is provided. A display means for displaying an input screen for performing input, and including an electronic medical record input terminal for generating electronic medical records by transmitting input information to the input screen to the server through the network, and provided on a screen When one eye of the subject is fixed for each of a plurality of reference points, the position between the plurality of indication points obtained by instructing the subject to indicate the position on the screen that is localized by the other eye An electronic medical chart input system that inputs the test results into the electronic medical chart for the Hess test that identifies the eye movement disease of the subject's eye by referring to the Hess figure formed by connecting with a straight line. Display control means for causing the display means to display an input template screen for the user to input the plurality of indication points obtained in the Hess test in a predetermined order, and the formation state and disease of the Hess figure The disease data storage means for storing the disease data in which the correspondence relationship is stored, and the disease corresponding to the formation state of the Hess figure formed based on the indication point input on the input template screen from the disease data Diagnostic result display control means for selecting and displaying the result as the examination result on the display means.

  In order to achieve the above object, the invention according to claim 7 is the electronic medical record input system according to claim 6, wherein the diagnostic result display control means is set on the input template screen. Based on the coordinates of the indicated point in the coordinate system, the straight line calculating means for calculating the length and inclination of the straight line forming the Hess figure is provided, and the coordinates of the indicated point and the calculation result by the straight line calculating means Based on the disease data, the disease is selected and displayed on the display means.

  In order to achieve the above object, the invention according to claim 8 is the electronic medical record input system according to claim 6, wherein the diagnosis result display control means is input to the input template screen. An indication point / reference point displacement calculating means for calculating a displacement between the indicated point and the corresponding reference point is provided, and the disease state is calculated from the disease data based on a calculation result by the indication point / reference point displacement calculating means. Is selected and displayed on the display means.

  In order to achieve the above object, the invention according to claim 9 is characterized in that when one eye of a subject is fixed at each of a plurality of reference points provided on the screen, the localization is performed by the other eye. Hess for identifying a disease of eye movement of the eye with reference to a Hess figure formed by connecting a plurality of indication points obtained by instructing the position on the screen to the subject with a straight line An input template screen for causing a computer to execute a process of inputting an inspection result into an electronic medical record for a test, and allowing a user to input the plurality of instruction points obtained in the Hess test in a predetermined order A screen display step for displaying a predetermined display means, and the input of the plurality of instruction points on the input template screen, and the straight line forming the Hess figure as the inspection result. It is characterized in that comprises a display control step of displaying the template screen, a.

  In order to achieve the above object, the invention according to claim 10 is the program according to claim 9, wherein the display control step includes the instruction in the coordinate system set on the input template screen. A straight line calculating step of calculating the length and inclination of the straight line based on the coordinates of the point, and displaying the straight line on the input template screen based on the calculation result;

  In order to achieve the above object, the invention according to claim 11 is the program according to claim 9, wherein the display control step is configured such that the indication point is a predetermined effective display frame of the input template screen. In response to the input to the point, an arrow in a direction from the other indication point to the indication point is displayed instead of the straight line connecting the indication point and the other indication point. Yes.

  In order to achieve the above object, the invention according to claim 12 is the program according to claim 9, wherein a plurality of designated points are input to the input template screen for the same reference point. A displacement calculating step of calculating a displacement between the last input point of the plurality of indicating points and the immediately preceding input point, and the displacement calculated by the displacement calculating step is predetermined. A displacement determination step for determining whether the displacement is greater than or equal to an allowable value, and when the displacement determination step determines that the displacement is greater than or equal to the predetermined tolerance, an indication point by re-examination of the Hess test is determined. And a re-inspection setting step for setting the input template screen in a state where input is possible.

  In order to achieve the above object, the invention according to claim 13 is the program according to claim 12, in response to the setting of the re-examination performed by the re-examination setting step. The method further includes the step of displaying a plurality of designated points corresponding to the same reference point in different colors.

  In order to achieve the above object, the invention according to claim 14 is configured such that when one eye of a subject is fixed at each of a plurality of reference points provided on the screen, the localization is performed by the other eye. Hess for identifying a disease of eye movement of the eye with reference to a Hess figure formed by connecting a plurality of indication points obtained by instructing the position on the screen to the subject with a straight line An input template screen for causing a computer to execute a process of inputting an inspection result into an electronic medical record for a test, and allowing a user to input the plurality of instruction points obtained in the Hess test in a predetermined order A screen display step for displaying a predetermined display means, and a disease corresponding to the formation state of the Hess figure formed based on the indication point input on the input template screen, A diagnostic result display control step of selecting from the stored disease data and displaying the selected disease on the display means as the examination result. .

  In order to achieve the above object, the invention according to claim 15 is the program according to claim 14, wherein the diagnosis result display control step is performed in a coordinate system set on the input template screen. Calculating the length and inclination of the straight line forming the Hess figure based on the coordinates of the pointing point, and based on the coordinates of the pointing point and the calculated length and inclination of the straight line The disease is selected from the disease data and displayed on the display means.

  In order to achieve the above object, the invention according to claim 16 is the program according to claim 14, wherein the diagnostic result display control step is performed with respect to the indication point input on the input template screen. Including a step of calculating a displacement with respect to the corresponding reference point, and selecting the disease from the disease data based on the calculated displacement and displaying the disease on the display means.

  In order to achieve the above object, the invention described in claim 17 is a computer-readable information recording medium in which the program according to any one of claims 9 to 16 is recorded.

  According to the first and ninth aspects of the present invention, a Hess figure that is a basis for diagnosis by a Hess test can be obtained by simply inputting the position of the indicated point indicated by the subject to the input template screen in a predetermined order. Are automatically formed and displayed on the input template screen. Therefore, the labor of drawing a straight line between the indication points in order to form the Hess graphic is omitted, and the efficiency of the work of inputting the electronic medical record can be improved.

  Further, according to the present invention described in claim 6 and claim 14, since the disease of the eye to be examined is specified and displayed on the display means simply by inputting the indication point obtained by the examination to the input template screen, The user can easily specify the disease of the eye to be examined. Diagnosis using a Hess test requires skill, but according to the present invention, even a user who is unfamiliar with this examination can easily obtain a diagnosis result.

  Hereinafter, an example of an embodiment of an electronic medical record input system according to the present invention, a program that causes a computer to execute an electronic medical record creation process, and a computer-readable information recording medium that records the program will be described in detail with reference to the drawings. To do.

  The electronic medical record input system according to the present invention enables efficient input of a test result of a Hess test generally used for inspecting an eye movement restriction state of an eye to be examined, Moreover, it has a configuration for supporting identification of a disease based on the test result, that is, diagnosis. For this purpose, the electronic medical record input system has a function of receiving a plurality of designated points that are the results of the Hess test and automatically inputting a straight line connecting the designated points. Furthermore, the system has a function of automatically specifying the disease of the eye to be examined based on the input indication point arrangement.

[System configuration]
The system configuration of this embodiment will be described below with reference to FIGS. FIG. 1 is a schematic block diagram showing an example of the overall configuration of the electronic medical record input system of the present embodiment. 2 and 3 are schematic diagrams showing an example of a display form of the input template screen according to the present invention. FIG. 4 is a schematic diagram showing an example of the configuration of disease data for specifying the disease of the eye to be examined based on the test result. FIG. 5 is a schematic diagram showing an example of a control program for realizing the processing according to the present invention.

  As shown in FIG. 1, the electronic medical record input system of this embodiment is configured to include a server 1 and an electronic medical record input terminal 10 connected through a LAN (Local Area Network) or the like installed in a hospital. . Although only one electronic medical record input terminal is shown in the figure, normally, an electronic medical record input terminal is arranged for each doctor or each clinic. In addition, although not shown, it is normal that various ophthalmic devices such as a fundus camera and an autorefractometer are connected to the network.

[Server configuration]
The server 1 is an information processing apparatus that forms the core of this system, and includes a control unit 2, a storage unit 3, and an input / output interface (input / output I / F) 4. The server 1 is provided with a database 5 for storing the electronic medical chart C.

  The control means 2 is composed of an arithmetic control device such as a CPU built in the information processing apparatus. The control unit 2 executes the control program 3A stored in the storage unit 3, thereby providing the electronic medical record information to the electronic medical record input terminal 10, storing the input electronic medical record in the database 5, management of the database 5, etc. Perform the process. The storage unit 3 includes a volatile storage device such as a RAM and a nonvolatile storage device such as a ROM or a hard disk drive (HDD). The control program 3A is stored in a nonvolatile storage device.

  The input / output I / F 4 includes an interface circuit that controls transmission / reception of data performed by the server 1 between the electronic medical record input terminal 10 and the database 5.

  The database 5 is a storage device having a large storage capacity that is built in or connected to the information processing device that constitutes the server 1. The control means 2 receives the electronic medical record input from the electronic medical record input terminal 10, for example, forms a file for each patient and stores it in the database 5. Further, the control means 2 receives an electronic medical chart viewing request or input request from the electronic medical chart input terminal 10, searches the database 5, selects a desired file, and transmits it to the electronic medical chart input terminal 10.

[Configuration of electronic medical record input terminal]
The electronic medical record input terminal 10 is a computer terminal for a user (such as a doctor or an examiner) to perform an electronic medical record input operation. The electronic medical record input terminal 10 includes a control unit 11, a storage unit 12, a monitor device 13, a keyboard 14, a mouse 15, and an input / output interface (I / F) 16.

  The control means 11 comprises an arithmetic control device such as a CPU built in the computer terminal. The control means 11 executes the control program 100 stored in the storage means 12 to display an electronic medical record input screen and accept input information, transmit the input electronic medical record to the server 1, and store it in the database 5. Processing for browsing the electronic medical record C is performed.

  The storage unit 12 includes a volatile storage device such as a RAM and a nonvolatile storage device such as a ROM or an HDD. The control program 100 executed by the control means 11 is stored in a nonvolatile storage device. In addition to the control program 100, the storage means 12 includes input template data 200, coordinate system setting information 300, in-frame region setting information 400, input order setting information 500, indication point related information 600, Monocular disease data 700 and binocular disease data 800 are stored. The storage means 12 constitutes disease data storage means of the present invention that stores monocular disease data 700 and binocular disease data 800.

  The control program 100 is a computer program that is executed for the control means 11 to perform the various processes described above. Details of the control program 100 will be described later.

  The input template data 200 is image data for causing the monitor device 13 to display an input screen including an input template screen for a user to input an instruction point acquired by the Hess test.

  An example of an input template screen displayed based on the input template data 200 is shown in FIG. The input template screen 1000 shown in the figure includes a right eye input template 1000R for inputting the result of the Hess test for the right eye of the subject, and an input for the left eye for inputting the result of the Hess test for the left eye. It consists of a template 1000L. In each of these screens 1000R and 1000L, “up” and “down” are displayed to indicate the vertical direction, and “inside” and “outside” are displayed to indicate the nose side and the temple side of the subject. And are each displayed.

  The screens 1000R and 1000L are surrounded by effective display frames 1001R and 1001L indicating the effective display areas of the respective screens. A group of curves forming a lattice shape similar to a Hess screen is displayed in the internal areas of the effective display frames 1001R and 1001L, and reference points are provided at some of the lattice points. Here, the curve group and the reference point are actually displayed in red. Further, the number assigned to the reference point in the figure is not displayed on the actual screen.

  Note that the input template data 200 may be configured as data including the screens 1000R and 1000L, or may be configured as data of only one screen. In the latter case, the data is copied and the right-eye input template 1000R and the left-eye template screen 1000L are displayed.

  The input template data 200 is image data for causing the monitor device 13 to display not only the input template screen 1000 having the configuration shown in FIG. 2 but also the screens shown in FIGS. 3, 8, 9, and 10 to be described later. Is also included.

(Coordinate system setting information)
The coordinate system setting information 300 is information for setting a coordinate system for specifying a position on the input template screen 1000. As a coordinate system set by the coordinate system setting information 300, for example, a two-dimensional plane coordinate system (XY coordinate system) having the origin at the lower left position of each screen 1000R, 1000L toward the paper surface of FIG. Use. The coordinate system setting information 300 is set for each of the right-eye input template 1000R and the left-eye input template 1000L. In addition, the coordinates of the screens 1000R and 1000L are set not only in the internal areas of the effective display frames 1001R and 1001L but also in the external areas. Although this will be described in detail later, this is for calculating the direction of the arrow displayed in response to the indication point being input to the out-of-frame area.

(In-frame area setting information)
The in-frame region setting information 400 is information for distinguishing the inside and outside regions of the effective display frames 1001R and 1001L provided in the right-eye input template 1000R and the left-eye input template 1000L, respectively. The in-frame region setting information 400 is configured as coordinates (X, Y) = (a ≦ X ≦ b, c ≦ Y ≦ d) of the in-frame region based on the coordinate system set in the coordinate system setting information 300. Has been. Here, the coordinate X = a indicates the “outer” side straight line that constitutes the effective display frame 1001R, the coordinate X = b indicates the “inner” side straight line, and the coordinate Y = c indicates the “lower” side straight line. The coordinate Y = d indicates a straight line on the “upper” side. The same applies to the effective display frame 1001L.

  Note that the coordinates of the out-of-frame area may be stored instead of the coordinates of the in-frame area to specify the in-frame area and the out-of-frame area. Further, the coordinates X = a, X = b, Y = c, and Y = d of the effective display frames 1001R and 1001L may be stored.

(Input order setting information)
The input order setting information 500 is information in which the order in which a plurality of instruction points acquired by the Hess test are input to the input template screen 1000 is set. For example, as shown in FIG. 2, when inspection is performed using nine reference points displayed in a grid of 3 rows and 3 columns, the center (number 1), the upper (number 2), the upper right (number) Round 3), right (number 4), lower right (number 5), lower (number 6), lower left (number 7), left (number 8), upper left (number 9) Corresponding indication points are set to be input in this order. The control unit 11 causes the monitor device 13 to display the input order set as the input setting information 500 in accordance with a request from the user. The display mode is, for example, by displaying the numbers shown in FIG. 2 on the input template screen 1000.

(Point-point related information)
The indication point related information 600 is information that associates an indication point and an indication point connected with a straight line to form a Hess graphic based on the input order of the indication points set in the input order setting information 500. For example, the association between the indication point corresponding to the “center” reference point and the indication point corresponding to the “upper” reference point is “the indication point input first” and “the indication input second” “Point” is set according to the input order indicated by the input order setting information 500.

  According to the indication point related information 600 of the present embodiment, center and top, center and bottom, center and right, center and left, top and top right, top and top left, bottom and bottom right, bottom and bottom left, right and top right, The indication point and the indication point corresponding to the reference point of each combination of the right and lower right, the left and upper left, and the left and lower left are associated with each other. That is, based on the input order setting information 500, the indication points input to “first” and “second”, the indication points input to “first” and “sixth”, “first” and “4” Indicating point input to "th", indicating point input to "first" and "8th", indicating point input to "second" and "third", "second" and "9th" Indicated points input to "5th" and "6th" input points, "6th" and "7th" input points, "3rd" and "4th" input Indicated points, "4th" and "5th" input points, "8th" and "9th" input points, and "7th" and "8th" input The designated points are associated with each other to form designated point related information 600. In the present embodiment, in accordance with the indication point related information 600 as described above, a Hess figure having a shape like a “field” distorted as shown in FIG. 3 is formed and displayed on the input template screen 1000.

  FIG. 3 shows an example of a display form of the input template screen 1000 displaying each input point and each straight line connected based on the point-related information 600 (the display process will be described later). To do). Each indicated point and each straight line are not displayed on the actual screen, but are numbered as shown in FIG. That is, in the input template 1000L for the left eye of the input template screen 1000, the number 1 is designated as the designated point corresponding to the upper left reference point, the number 2 is designated as the designated point corresponding to the upper reference point, and the upper right reference point. The corresponding pointing point is number 3, the pointing point corresponding to the left reference point is number 4, the pointing point corresponding to the center reference point is number 5, and the pointing point corresponding to the right reference point is Is the number 6 for the pointing point corresponding to the lower left reference point, the number 8 for the pointing point corresponding to the lower reference point, and the number 9 for the pointing point corresponding to the lower right reference point. Each is attached.

  Furthermore, in this left-eye input template 1000L, number 10 is assigned to the straight line connecting the designated points corresponding to the upper left and upper reference points, and number 11 is assigned to the straight line connecting the designated points corresponding to the upper and right reference points. The straight line connecting the pointing points corresponding to the left and center reference points is number 12 and the straight line connecting the pointing points corresponding to the center and right reference points is the number 13 corresponding to the lower left and lower reference points. Number 14 is for the straight line connecting the pointing points, number 15 is for the straight line connecting the pointing points corresponding to the lower and lower right reference points, and number 16 is for the straight line connecting the pointing points corresponding to the upper left and left reference points. However, number 17 corresponds to the straight line connecting the reference points corresponding to the upper and center reference points, and number 18 corresponds to the straight line connecting the reference points corresponding to the upper right and right reference points, corresponding to the left and lower left reference points. No. 19 is connected to the straight line connecting the indicated points to connect the indicated points corresponding to the center and the lower reference point. The straight line number 20, number 21 on the line connecting the designated point corresponding to the reference point of the right and lower right are assigned respectively.

  In the input template 1000R for the right eye, the number 31 corresponds to the upper left reference point, the number 32 corresponds to the upper reference point, and the number 32 corresponds to the upper right reference point. No. 33, No. 34 for the indication point corresponding to the left reference point, No. 35 for the indication point corresponding to the center reference point, No. 36 for the indication point corresponding to the right reference point, The indication point corresponding to the lower left reference point is assigned number 37, the indication point corresponding to the lower reference point is assigned number 38, and the indication point corresponding to the lower right reference point is assigned number 39. .

  Further, in this right-eye input template 1000R, number 40 is assigned to the straight line connecting the upper left and upper reference points, and number 41 is assigned to the straight line connecting the upper and right reference points. The number 42 corresponds to the straight line connecting the left and center reference points, and the number 43 corresponds to the straight line connecting the center and right reference points to the lower left and lower reference points. The number 44 is assigned to the straight line connecting the indicated points, the number 45 is assigned to the straight line connecting the indicated points corresponding to the lower and lower right reference points, and the number 46 is assigned to the straight line connecting the indicated points corresponding to the upper left and left reference points. However, the number 47 corresponds to the straight line connecting the upper and center reference points, the number 48 corresponds to the straight line connecting the upper and right reference points, and the number 48 corresponds to the left and lower left reference points. No. 49 is connected to the straight line connecting the indicated points to connect the indicated points corresponding to the center and the lower reference point. The straight line number 50, number 51 on the line connecting the designated point corresponding to the reference point of the right and lower right are assigned respectively.

  Hereinafter, in order to simplify the description, these indicated points and straight lines may be abbreviated as “indicated points of number m” and “straight lines of number n”, respectively.

(Disease data)
The monocular disease data 700 and the binocular disease data 800 constitute the disease data referred to in the present invention, and store the correspondence between the formation state of the Hess graphic formed on the input template screen 1000 and the disease. The monocular disease data 700 stores the correspondence between the formation state of the Hess figure for the single eye to be examined and the disease, and the binocular disease data 800 contains the formation state of the Hess figure for both the left and right eyes and the disease. Is stored.

  Here, the “formation state of the Hess figure” refers to the Hess figure such as the arrangement (coordinates) of the indication point forming the Hess figure, the length and inclination of the straight line, or the displacement (distance) of the indication point with respect to the reference point. It means various kinds of information specified from the shape.

  4A shows a partial configuration example of the monocular disease data 700, and FIG. 4B shows a partial configuration example of the binocular disease data 800.

  The monocular disease data 700 shown in FIG. 4 (A) includes an “illness name” indicating “right eye pulley nerve palsy” and “left eye pulley nerve palsy”, which is an example of a disease in a monocular of the left and right eyes, an indication point, and “Numbers 1 to 51 (see FIG. 3)” attached to each straight line, judgment information for each indication point and straight line for determining that the eye to be examined has the disease (“value” in the figure and “Effective range”) and “search conditions” for designating reference points and / or straight line numbers to be referred to for determining whether the disease is the disease or not.

  Examples of the disease names stored in the monocular disease data 700 include right external straight muscle paralysis, left intraocular straight muscle paralysis, right upper oblique muscle paralysis, and left lower oblique muscle paralysis. The monocular disease data 700 includes determination information and search conditions set for each number for each disease name.

  The determination information of the monocular disease data 700 includes, for each of the numbers 1 to 51, the “value” column indicating the coordinates of the indicated point or the length and inclination of the straight line, the coordinate value indicated in the “value” column, and the like. An “effective range” column indicating a central range is provided. Here, the coordinates of the indication point, the length of the straight line, and the inclination are values based on the coordinate system indicated by the coordinate system setting information 300.

  For example, for the indication point number 1 in FIG. 4A, coordinates (30, 125) are stored in the “value” column, and ± 5 is stored in the “effective range” column. This represents that it is determined whether or not the coordinates of the designated point are included in the range of (30 ± 5, 125 ± 5). Similarly, “0.01, 50” shown in the “Value” column of the straight line number 10 and “± 0.01, ± 2” shown in the “Effective range” column indicate that the length of the straight line is 0.01 ± This indicates that it is determined whether the slope is included in the range of 0.01 and the slope is included in the range of 50 ± 2.

  Note that the determination information does not need to be formed from the “value” column and the “effective range” column as described above, and may be configured to set a range as a determination criterion for the presence or absence of a disease. For example, the determination information of the indicated point of the number 1 may be directly set as the coordinate value range (25 to 35, 120 to 130).

  The search condition of the monocular disease data 700 is information that selectively designates the reference points and / or straight lines to be referred to in order to determine whether or not the subject's eye suffers from the disease by numbers 1 to 51. is there.

  For example, the search condition for determining whether or not the patient suffers from “right eye pulley nerve palsy” shown in FIG. 4A is “1 AND 10 AND 11”. This indicates that the judgment information of the indication point of No. 1, the straight line of No. 10, and the straight line of No. 11 is adopted as the judgment object, and further, when all the conditions shown in these three judgment information are satisfied (AND search) Indicates that it is determined that the right eye pulley nerve palsy.

  Similarly, the search condition for “left eye pulley nerve palsy” is “1 AND (10 OR 51)”, and the judgment information of the indication point of No. 1, the straight line of No. 10, and the straight line of No. 51 is adopted as the judgment target. Left eye pulley nerve when the condition shown in the judgment information of the designated point of No. 1 and the condition shown in the judgment information of the straight line of No. 10 or the straight line of No. 51 (OR search) are satisfied. Indicates that it is determined to be paralyzed.

  On the other hand, the binocular disease data 800 shown in FIG. 4 (B) is similar to the monocular disease data 700, “pathology name” indicating “binocular pulley nerve palsy”, which is an example of a disease related to the left and right eye, “Nos. 1 to 51” attached to the indication points and the straight lines, and judgment information about the indication points and the straight lines for judging whether or not the eye to be examined has the disease (“value” and “ “Effective range”) and a “search condition” for designating a reference point and / or a straight line number to be referred to in order to diagnose whether or not the disease is the disease.

  Further, as shown in FIG. 4B, the binocular disease data 800 may include a “value explanation” column indicating the content of the determination information. Such a “value explanation” column can be provided in the monocular disease data 700 as a matter of course.

  The determination information of the binocular disease data 800 includes, for each of the numbers 1 to 51, the “value” column indicating the coordinates of the indicated point or the length and inclination of the straight line, the coordinate value indicated in the “value” column, and the like. And an “effective range” column indicating a range centered at.

  For example, “0.00, 55” shown in the “value” column and “± 0.01, ± 2” shown in the “effective range” column of the straight line number 10 in FIG. 4B are the length of the straight line. Is included in the range of 0.00 ± 0.01 and the slope is included in the range of 55 ± 2.

  Further, the above search condition of the binocular disease data 800 selectively designates the reference points and / or straight lines referred to for determining whether or not the subject's eye suffers from the disease by numbers 1 to 51. Information.

  For example, the search condition for determining whether or not “binocular pulley nerve palsy” shown in FIG. 4B is affected is “10 AND 11”. This indicates that the straight line with the number 10 and the straight line with the number 11 are adopted as the determination targets, and it is determined that the binocular pulley is paralyzed when both of the conditions shown in the two pieces of determination information are satisfied. It is shown that.

  The monocular disease data 700 and the binocular disease data 800 are created using clinical data acquired in advance by clinical examinations for a large number of eyes for various diseases that can be diagnosed by the Hess test.

  Using the monocular disease data 700 or the binocular disease data 800, the control means 11 can display a Hess graphic based on a typical test result of each disease on the input template screen 1000 (see FIG. 10 described later). . For this purpose, the control means 11 uses, for example, the coordinate values of the indication points, the lengths and the inclinations of the straight lines described in the “value” column of FIG. 4 (A) or FIG. Such a typical Hess figure is obtained and displayed on the input template screen 1000.

  The monitor device 13 constitutes display means according to the present invention that displays various screens such as an electronic medical record input screen under the control of the control means 11. In particular, the monitor device 13 displays an input template screen 1000 for inputting the test result of the Hess test into the electronic medical record, an input screen 2000 described later including the input template screen 1000, and the like. .

  The keyboard 14 and the mouse 15 are input devices that accept an instruction point input operation on the input template screen 1000 by the user.

  The input / output I / F 16 includes an interface circuit that controls transmission and reception of data between the electronic medical record input terminal 10 and the server 1 and other terminals (not shown).

  The control means 11 of the electronic medical record input terminal 10 replaces the control program 100 stored in the storage means 12 with a control program 3A stored in the storage means 3 of the server 1 like a normal server-client system. You may make it perform the process which concerns on this invention by performing via a network. Hereinafter, the control unit 11 will be described as executing the control program 100 stored in the storage unit 12 of the electronic medical record input terminal 10.

[Configuration of control program]
Next, the configuration of the control program 100 executed by the control means 11 for performing the processing procedure according to the present invention will be described.

  FIG. 5 shows a schematic configuration of the control program 100. The control program 100 includes a straight line calculation program 101, an input order setting program 102, an inside / outside frame determination program 103, an indicated point displacement calculation program 104, an indicated point displacement determination program 105, a re-inspection setting program 106, a display color The program includes a setting program 107, an examination count program 108, a disease selection program 109, an instruction point / reference point displacement calculation program 110, a display control program 120, and an input operation program 130.

  Here, the control means 11 constitutes the display control means according to the present invention by executing the straight line calculation program 101, the frame inside / outside determination program 103, and the display control program 120. Further, the control means 11 constitutes a displacement calculating means by executing the designated point displacement calculating program 104, constitutes a displacement judging means by executing the designated point displacement judging program 105, and executes the reinspection setting program 106. By doing so, a reinspection setting means is configured. Further, the control means 11 constitutes a display color setting means by executing the display color setting program 107. Furthermore, the control means 11 constitutes the diagnosis result display control means according to the present invention by executing the straight line calculation program 101 or the indicated point / reference point displacement calculation program 110 and the disease selection program 109.

(Line calculation program)
The straight line calculation program 101 is associated with each straight line forming the Hess graphic, that is, the indication point related information 600, based on the coordinates of the indication point in the coordinate system set on the input template screen 1000 by the coordinate system setting information 300. This program is executed to calculate the length and inclination of each straight line connecting the designated points. More specifically, the control means 11 performs the following process by executing this straight line calculation program 101. It is assumed that the following point A and point B are associated by the point-related information 600.

  First, the control unit 11 refers to the coordinate system setting information 300 and obtains the coordinates (x1, y1) of the designated point A and the coordinates (x2, y2) of the designated point B input to the input template screen 1000. Next, the distance √ {(x1−x2) ^ 2 + (y1−y2) ^ 2} between the designated point A and the designated point B is calculated, and the length L of the straight line connecting the designated point A and the designated point B is calculated. Ask for. Further, the X coordinate x1 of the designated point A and the X coordinate x2 of the designated point B are compared, and the inclination α of the straight line in the direction from the designated point having a small X coordinate to the designated point is calculated. For example, when x1 ≦ x2, the inclination α of the straight line is (y2−y1) / (x2−x1). The above calculation processing is executed for all the pairs of pointing points associated by the pointing point related information 600. The calculated length L and inclination α of each straight line are stored in a predetermined storage area of the storage unit 12.

  The control means 11 displays a Hess graphic based on the inspection result by displaying a straight line between the indicated points displayed on the input template screen 1000 using the length and inclination of the straight line thus calculated. . At this time, an arrow may be displayed instead of a straight line in accordance with a determination result based on the inside / outside frame determination program 103 described later.

(Input order setting program)
The input order setting program 102 is a program executed to generate input order setting information 500 in response to an operation for setting an input order of instruction points on the input template screen 1000. The control means 11 executes the input order setting program 102 to create input order setting information 500 representing the input order of the indicated points set and input by operating the keyboard 14 and the mouse 15 and stores them in the storage means 12. save.

  As the input order setting information 500 is set, the control unit 11 newly generates the instruction point related information 600 corresponding to the new input order setting information 500. This is because even if the input order is different, the formed Hess figures must be the same, and therefore it is necessary to adjust the correspondence between the input order of the indicated points and the straight line between the indicated points.

  The above-described input order shown in FIG. 2 (center, top, top right, right, bottom right, bottom, bottom left, left, top left) is held in the input order setting information 500 as a default setting, It is preferable that the designated point related information 600 corresponding to the default setting is held.

(Internal / external judgment program)
The inside / outside frame determination program 103 is a program that is executed to determine whether the designated point is input inside or outside the effective display frames 1001R and 1001L of the input template screen 100. The control means 11 executes the inside / outside frame determination program 103 to thereby execute the coordinates (x1, y1) of the designated point A calculated according to the straight line calculation program 101 and the in-frame area indicated by the in-frame area setting information 400. The coordinates (a.ltoreq.X.ltoreq.b, c.ltoreq.Y.ltoreq.d) are compared to determine whether or not the designated point A is included in the in-frame region. Specifically, it is determined whether the X coordinate x1 of the designated point A is included in the X coordinate a ≦ X ≦ b of the in-frame region, and the Y coordinate y1 of the designated point A is the Y coordinate c ≦ Y of the in-frame region. It is determined whether it is included in ≦ d. When it is determined that both are included, it is determined that the indication point A is input to the in-frame region, and when it is determined that neither one is included, the indication point A is input outside the frame. Judge that The determination result is stored in a predetermined storage area of the storage unit 12.

  When it is determined that the designated point A has been input to the in-frame region, the control means 11 obtains according to the straight line calculation program 101 between this designated point A and another designated point associated therewith. Display a straight line. On the other hand, when it is determined that the designated point A has been input outside the frame, the control means 11 displays an arrow pointing in the direction from the other designated point toward the designated point A instead of a straight line (see FIG. 8 described later). . In addition, when it is determined that another indication point associated with the indication point A is also input outside the frame, neither a straight line nor an arrow is displayed between these indication points.

  When it is determined that the instruction point A is input outside the frame, the control unit 11 does not display the instruction point A on the input template screen 1000.

(Indication point displacement calculation program)
In response to the input of a plurality of indication points corresponding to the same reference point on the input template screen 1000, the indication point displacement calculation program 104 includes the indication point last input among the plurality of indication points, This is a program that is executed to calculate the displacement (distance) between the indicated point input immediately before. For example, when k instruction points are input with respect to a certain reference point, the control means 11 follows the instruction point displacement calculation program 104 and the last kth input instruction point and the immediately preceding instruction point are input. The displacement between the k-1th input point and the designated point is calculated.

  Hereinafter, the last input point with respect to the same reference point will be referred to as “latest indication point”, and the indication point input immediately before will be referred to as “previous indication point”.

  The control means 11 executes the following process according to the designated point displacement calculation program 104.

  First, the control means 11 refers to the input order setting information 500 to determine the designated point input with respect to the same reference point. When the indication points for the nine reference points are input in the order shown in FIG. 2, for example, the indication points corresponding to the central reference point that is the first in the input order are first input in the order of 10 The determination is made by using the indicated points of the 19th, 19th, 28th,...

  In general, when the number of reference points is K, it is determined that the actual input order corresponds to the same reference point by using K as a modulo. That is, the u-th indicating point and the v-th indicating point in the actual input order are determined to correspond to the same reference point when u≡v (mod K).

  Next, the control means 11 uses the coordinates calculated in accordance with the straight line calculation program 101 for the latest indicated point and the previous indicated point among a plurality of indicated points determined to correspond to the same reference point. The displacement between each indicated point is calculated.

  For example, when three indicating points (the actual input order is the first, tenth and nineteenth indicating points) are input for the central reference point shown in FIG. 2, the latest indicating point is the 19th indicating point. The previous indicated point is the 10th indicated point. Assuming that the coordinates of the 19th indicating point are (x19, y19) and the coordinates of the 10th indicating point are (x10, y10), the displacement between the indicating points to be calculated is the distance √ {(x19−x10). ) ^ 2 + (y19-y10) ^ 2}. The displacement between the indicated points calculated in this way is stored in a predetermined storage area of the storage unit 12.

  The control unit 11 calculates displacements of a plurality of indication points corresponding to the first (input order first) reference point in the input order set by the input order setting information 500. In the case of the present embodiment shown in FIG. 2, the displacement between the latest and the last indicated point corresponding to the center reference point is calculated.

(Indicating point displacement judgment program)
The designated point displacement determination program 105 calculates a displacement between a plurality of designated points with respect to the same reference point, which is calculated according to the designated point displacement calculation program 104, to be equal to or greater than a predetermined allowable value (sometimes referred to as a displacement allowable value). It is a program that is executed to determine whether or not there is. The setting information of the allowable displacement value is data used for determining whether or not reinspection should be performed in order to ensure inspection accuracy, as will be described later. The setting information of the permissible displacement value is defined as a distance in the coordinate system set by the coordinate system setting information 300, and adopts a clinically acquired value as with the monocular disease data 700 and the binocular disease data 800.

  The control means 11 executes the designated point displacement determination program 105 to compare the displacement value calculated according to the designated point displacement calculation program 104 with the above-described allowable displacement value and determine the magnitude relationship. The determination result is stored in a predetermined storage area of the storage unit 12.

(Re-inspection setting program)
The re-inspection setting program 106 accepts the instruction point that is continuously input as the inspection result of the re-inspection when it is determined based on the instruction point displacement determination program 105 that the displacement between the instruction points is equal to or greater than the allowable displacement value. This is a program executed to set the input template screen 1000 so as to display the received indication points. When it is determined that the displacement between the indicated points is greater than the allowable displacement value, the control unit 11 executes the reinspection setting program 106 and sets the input template screen 1000 to a reinspection mode in which the reinspection result can be input. . At this time, the instruction points that are continuously input are displayed on the input template screen 1000 together with the instruction points (and straight lines) that have been displayed before the previous time.

  Furthermore, the control means 11 executes the straight line calculation program 101 in accordance with the reinspection setting program 106, and calculates and displays the length and inclination of the straight line forming the Hess figure based on the reinspection. Thus, a plurality of Hess figures are displayed on the input template screen 1000.

(Display color setting program)
The display color setting program 107 displays a plurality of designated points corresponding to the same reference point input on the input template screen 1000 in different colors, and a straight line based on the designated points acquired by reexamination. This is a program that is executed to perform a process of displaying in a color different from the straight line already displayed on the screen 1000. The control means 11 executes the display color setting program 107 according to the re-inspection setting program 106 to display, for example, the indication points and straight lines in the first inspection in black, and the indication points in the second inspection. In addition, control is performed so that the straight line is displayed in blue and the indication point and the straight line in the third inspection are displayed in red. Different display colors are set for the fourth and subsequent examinations. That is, the display color setting program 107 is a program that causes the control unit 11 to execute a process of displaying a plurality of Hess figures based on repeated examinations in different colors. In addition, what is necessary is just to determine suitably about how many times of inspections a display color is set.

(Inspection count program)
The inspection count program 108 updates the counter in response to the determination that the displacement between the indicated points is equal to or greater than the allowable displacement value according to the indicated point displacement determination program 105, thereby indicating the number of times the inspection has been repeated. A program that is executed to count. The control means 11 executes the inspection number counting program 108 to update the counter by +1 every time it is determined that the displacement between the indicated points is equal to or greater than the allowable displacement value, and count the number of inspections.

  The control means 11 resets the counter to “1” during the first examination for the subject. This reset operation is performed, for example, at a timing when the input template screen 1000 is displayed on the monitor device 13 in accordance with a user operation. After the completion of the first inspection, the first indicating point in the input order is re-input in order to confirm whether or not the inspection has been properly performed, and the indicated point and the first inspection When it is determined that the displacement from the first indication point is equal to or greater than the allowable displacement value, the counter is updated to “2” and it is recognized that the second inspection has been started. Similarly, the counter is updated by +1 every time it is determined that the displacement between the latest point and the previous point is equal to or greater than the allowable displacement value, and the number of inspections is recognized. The counted number of inspections is stored in a predetermined storage area of the storage unit 12.

(Disease selection program)
The disease selection program 109 is a program for selecting the disease specified by the formation state of the Hess figure formed based on the indication point input on the input template screen 1000 from the disease data and displaying it on the monitor device 13. . By executing the disease selection program 109, the control unit 11 is specified by the coordinates of the indication point input to the input template screen 1000 and the length and inclination of the straight line calculated according to the straight line calculation program 101. Processing for selecting the disease of the eye to be examined from the monocular disease data 700 and / or the binocular disease data 800 is performed.

  More specifically, the control unit 11 executes the disease selection program 109 to thereby execute the “value” regarding the indicated point and / or straight line of the number indicated by the search condition of the monocular disease data 700 shown in FIG. ”And“ effective range ”(judgment information), the coordinates of the designated point of the number and / or the length and inclination of the straight line entered in the input template screen 1000 are included in the range set by the judgment information. It is determined whether or not the eye to be examined suffers from the disease (this determination technique has been described above in the description of FIG. 4). The control means 11 executes such processing for each “disease name” included in the disease data.

  The control means 11 selects a disease by a method similar to a normal diagnosis method by a doctor. For example, first, the presence or absence of the outer oblique line, inner oblique line, upper oblique line, or lower oblique line of the eye to be examined is determined based on the coordinates of the indication point (see FIG. 3) at the center of the Hess figure. Next, it is analyzed whether or not the arrangement of the pointing points of the left and right eyes, that is, the Hess figure is symmetric. If it is asymmetric, the disease is identified by paying particular attention to the reduced Hess of the left and right Hess.

  It is to be noted that an indication point / reference point displacement calculation program 110 described later is executed to calculate the amount and direction of displacement of each indication point from the reference point, and the calculation result is analyzed to analyze the vertical and horizontal eye positions. Processing is performed to obtain a deviation, narrow down the disease corresponding to the obtained eye position deviation from the monocular disease data 700, search the judgment information of the monocular disease data 700 for each narrowed disease, and select a disease corresponding to the search condition. You may go.

  The control means 11 displays the disease selection result on the monitor device 13. The display form is, for example, by displaying a disease name determined to be affected. If there is no disease determined to be affected, a message such as “no applicable disease” is displayed.

  The process of selecting the disease of the eye to be examined from the binocular disease data 800 is also performed in the same manner as the selection from the monocular disease data 700 described above.

(Indication point / reference point displacement calculation program)
The designated point / reference point displacement calculation program 110 is a program executed to calculate the amount and direction of displacement from the corresponding reference point for each designated point input on the input template screen 1000. The control means 11 executes the designated point / reference point displacement calculation program 110 to thereby perform the coordinates (x1, y1) of the designated point A input to the input template screen 1000 and the reference point corresponding to the designated point A. Based on the coordinates (x0, y0) of O, the amount of displacement between the indicated point A and the reference point O, that is, the distance √ {(x1−x0) ^ 2 + (y1−y0) ^ 2} is calculated. . Further, the direction of displacement of the designated point A relative to the reference point O is obtained by calculating the slope (y1-y0) / (x1-x0) of the straight line from the reference point O toward the designated point A. The obtained amount and direction of displacement are stored in a predetermined storage area of the storage unit 12.

(Display control program)
The display control program 120 is a program that is executed to perform display processing of the monitor device 13. In accordance with the display control program 120, the control means 11 selects image data and message data corresponding to instructions from the user or instructions of each program included in the control program 100 from the storage means 12, performs appropriate processing, and monitors them. It is displayed on the screen 13.

(Input operation program)
The input operation program 130 is a program that controls the control unit 11 to execute a program corresponding to an operation signal from the keyboard 14 or the mouse 15. When the control unit 11 receives an operation signal corresponding to the user's operation from the keyboard 14 or the mouse 15, the control unit 11 selects and executes the program corresponding to the operation signal from the control program 100 according to the input operation program 130. For example, in response to the operation of the mouse 15 and all indication points being input on the input template screen 1000, the control unit 11 selects and executes the straight line calculation program 101 according to the input operation program. Then, the length and inclination of each straight line connecting the indicated points are calculated.

[Processing procedure]
A processing procedure executed by the electronic medical record input system of the present embodiment having the above-described system configuration will be described with reference to the flowcharts shown in FIGS. In addition, the configuration of the screen forms displayed on the monitor device 13 corresponding to the processing by the system will be sequentially described.

  The control program 100, the input template data 200, the coordinate system setting information 300, the in-frame region setting information 400, the input order setting information 500, the indication point related information 600, the monocular disease data 700, and the binocular disease data 800 are stored in advance in the storage means 12. It is assumed that it is stored in

  When setting the input order of instruction points on the input template screen 1000, the user operates the keyboard 14 and mouse 15 to make a setting request in advance. The control unit 11 receives the setting request and executes the input order setting program 102 to create the input order setting information 500.

(Step S1; input template screen display)
First, the user performs a predetermined operation such as clicking a file icon with the mouse 15 to display the input template screen 1000 shown in FIG. 2 on the monitor device 13 and prepares to input the test result of the Hess test. (S1).

(Step S2; test result input)
The user operates the mouse 15 and the like to input nine indication points, which are the results of the Hess test, into the input template screen 1000 in a predetermined input order based on the input order setting information 500 (S2).

  Here, the user sequentially inputs the indication points designated by the subject in real time while performing a Hess test on the subject's eye. Needless to say, the electronic medical record input system of the present invention can be used even when the already acquired inspection result is input.

(Step S3: Calculation of coordinates of designated point, straight line length and inclination)
When the user completes the input of the nine instruction points, the control means 11 executes the straight line calculation program 101, obtains the coordinates of each input instruction point with reference to the coordinate system setting information 300, and indicates the instruction points. The length and inclination of a straight line connecting with other indication points associated by the related information 600 are calculated (S3).

(Step S4: Determination of input position of designated point)
The control means 11 executes the inside / outside frame determination program 103, and each indicated point obtained in step S3 is an area (inside frame area) inside the effective display frames 1001R and 1001L (see FIG. 2) of the input template screen 1000. Or the outside area (outside the frame area) is determined with reference to the in-frame area setting information 400, and each indication point is a frame for a pair of indication points associated by the indication point related information 600. It is determined whether or not an input has been made to the inner area (S4).

(Step S5; display of a straight line connecting designated points inputted in the frame area)
When it is determined that both of the pair of instruction points associated by the instruction point related information 600 have been input to the in-frame region (S4; Y), the control unit 11 executes the display control program 120 to execute the step S3. Based on the calculation result, a straight line connecting the pair of designated points is displayed on the input template screen 1000 (S5).

(Step S6; display of an arrow toward the indicated point input to the out-of-frame area)
In addition, when it is determined that one of the associated pair of instruction points has been input to the out-of-frame area (S4; N), the control unit 11 executes the display control program 120, and based on the calculation result in step S3. Then, an arrow in the direction toward the designated point input in the out-of-frame area is displayed on the input template screen 1000 (S6).

  Note that when both of the pair of indication points are input to the out-of-frame region, no straight line or arrow is displayed between these indication points.

  In FIG. 8, when only one indication point (referred to as an out-of-frame indication point) is input to the out-of-frame area (step S4; N), the out-of-frame indication point is displayed from the in-frame indication point displayed on the input template screen 1000. The display form of the arrow which points the direction which goes to is shown. This figure is formed when the indication point of No. 3, the indication point of No. 6, and the indication point of No. 9 shown in FIG. 3 are input outside the effective display frame 1001L of the input template for left eye 1000L. The display form of a Hess figure is shown. At this time, as shown in the figure, the input template 1000L for the left eye is not displayed from the designated point of number 2 instead of the straight line of number 11 connecting the designated point of number 2 and the designated point of number 3. An arrow A1 in the direction toward the designated point of number 3 is displayed. Similarly, an arrow A2 in the direction from the designated point of number 5 to the designated point of non-displayed number 6 and an arrow A3 in the direction from the designated point of number 8 to the designated point of non-displayed number 9 are displayed. . In addition, when both related indication points are input to the out-of-frame area, that is, the indication points of No. 3 and No. 6 and the indication points of No. 6 and No. 9 Straight lines and arrows are not displayed between the indicated points.

  Through the above steps S5 and S6, a Hess graphic based on the inspection result input on the input template screen 1000 is displayed. Here, according to the display color setting program 107, the control means 11 displays the Hess graphic based on the result of the first inspection in black.

  FIG. 9 shows a configuration example of the input screen 2000 in a state in which a Hess graphic based on the first inspection result (a case where all indicated points are input in the in-frame region) is displayed on the input template screen 1000. Yes. The input screen 2000 includes an input template screen 1000 for displaying a Hess graphic, a disease specifying button 2001, and a comment display unit 2002. The disease specifying button 2001 is operated when specifying the disease of the eye to be examined based on the coordinates of the indication point input on the input template screen 1000 and the length and inclination of the straight line calculated based on the indication point. This button is clicked (clicked with the mouse 15). The comment display unit 2002 is a screen area in which comments relating to a Hess graphic displayed on the input template screen 1000 are displayed.

(Step 7: Re-input to confirm inspection accuracy)
Next, in order to confirm whether or not the above examination has been properly performed, the user instructs the subject to again designate the first reference point in the above input order, and the designated point is displayed on the input template screen 1000. Input (S7).

(Step 8: Calculation of displacement of indicated point)
The control means 11 executes the straight line calculation program 101 to obtain the coordinates of the designated point re-input in step S7, executes the designated point displacement calculation program 104, and executes the re-input coordinates of the designated point, The displacement from the coordinates of the designated point input first in step S2 is calculated (S8).

(Step S9: Determination of necessity of re-examination)
Subsequently, the control means 11 executes the designated point displacement determination program 105, determines whether or not the displacement between the designated points calculated in step S8 is equal to or greater than the allowable displacement value, and whether reexamination is necessary or not. Is determined (S9).

(Step S10: Re-inspection mode setting)
When performing re-inspection, that is, when the calculated displacement is equal to or greater than the allowable displacement value (S9; Y), the control means 11 executes the re-inspection setting program 106 and displays the input template screen 1000 as the re-inspection result. A state where the input can be accepted is set (S10).

  At this time, the control means 11 executes the inspection count program 108 and updates the counter by +1 to “2”. Further, the storage unit 12 stores count information indicating that the inspection to be performed subsequently is the second time. Further, the control means 11 converts the Hess figure obtained by the re-examination, that is, the indication point and the straight line connecting the indication points into the Hess figure (black) by the first examination according to the display color setting program 107. Are displayed in different colors (blue).

  Steps S2 to S10 are repeated until it is determined that the displacement in the latest inspection (Mth) and the previous inspection (M-1) is less than the allowable displacement (that is, in step S9). Repeat until “N”). At this time, the counter indicates “M”, and count information indicating that the examination has been performed M times is stored in the storage unit 12. The Hess figures acquired by the first to Mth examinations are displayed in different colors according to the display color setting program 107. Here, all the Hess figures from each examination may be simultaneously displayed on the input template screen 1000, or only one or more Hess figures may be selectively displayed, such as displaying only the latest Hess figure and the previous Hess figure. It is good also as a structure which is displayed on.

  In addition, a predetermined allowable number of repetitions (for example, 5 times) is set in advance, and in response to the counter (that is, the number of inspections indicated by the count information) exceeding the allowable number of repetitions, an inspection for the subject is performed. You may control to complete | finish. This makes it possible to make judgments such as using other testing methods for subjects whose disease is difficult to identify by the Hess test, and to repeat the Hess test over and over again. Therefore, it is possible to avoid a situation where time is wasted.

(Step S11; identification of monocular disease)
On the other hand, when the reexamination is not performed, that is, when the calculated displacement is less than the allowable displacement value (S9; N), the control unit 11 receives the operation of the disease specifying button 2001 by the user and loads the disease selection program 109. The disease corresponding to the coordinates of the designated point, the length of the straight line, and the inclination acquired in step S3 is selected from the monocular disease data 700 (S11). At this time, for each disease included in the monocular disease data 700, the control means 11 refers to the coordinates of the indication point indicated in the search condition and / or the length and inclination of the straight line to determine whether or not the disease corresponds to the disease. Make a decision and select the name of the disease.

  As described above, the displacement from the reference point is obtained for each indication point, the disease is narrowed down based on the displacement, and the disease is selected by searching the monocular disease data 700 for each narrowed disease. Processing may be performed. With such a configuration, when a large number of diseases are included in the monocular disease data 700, it is only necessary to search for the narrowed disease without searching for all the diseases individually. It is possible to shorten the time required.

(Step S12; identification of diseases of both eyes)
Further, according to the disease selection program 109, the control unit 11 selects the disease corresponding to the coordinates of the indication point, the length of the straight line, and the inclination acquired in step S3 from the binocular disease data 800 by the same method (S12). ).

(Step S13; display of diagnosis result)
The control means 11 executes the display control program 120 and displays the monocular disease name specified in step S11 and the binocular disease name specified in S12 on the monitor device 13 as a diagnosis result. (S13).

  FIG. 10 shows an example of the input screen 2000 that displays the diagnosis result. As shown in the figure, the left-eye input template 1000L includes a typical Hess figure of the specified disease (here, binocular pulley nerve palsy) along with a Hess figure (solid line) based on the examination result of the left eye. (Dotted line) is displayed. The right eye input template 1000R displays a typical Hess figure (dotted line) of the specified disease together with a Hess figure (solid line) based on the examination result of the right eye. In the comment display portion 2002, a Hess graphic indicated by a solid line represents a test result (examination data), and a typical Hess graphic of a disease in which the Hess graphic indicated by a dotted line is specified is displayed. Information indicating that it is displayed is displayed. In addition, the count result of the number of inspections may be further displayed on the comment display unit 2002 or the like.

  For the Hess graphic displayed on the input template screen 1000 and the disease identified in steps S11 and S12, the user performs a predetermined operation such as clicking the test result input button provided on the input screen 2000 with the mouse 15. By doing so, it is input to the subject's electronic medical record. The electronic medical record into which the Hess figure and the inspection result are input is transmitted to the server 1 and stored in the database 5.

[Action / Effect]
According to the electronic medical record input system of the present embodiment configured to execute the processing as described above, the following operations and effects are exhibited.

  First, since the Hess figure is automatically formed and displayed simply by inputting the position of the designated point designated by the subject in the predetermined order on the input template screen 1000, the efficiency of the work of inputting the electronic medical chart is greatly improved. Is done. In other words, in the past, the work of inputting the indication points obtained by the Hess test on the inspection paper or the screen and the operation of creating a Hess figure by connecting the indication points with a straight line are both manual operations of the user. However, according to the electronic medical record input system of this embodiment, since the Hess figure is automatically formed only by manually inputting the former work, the input efficiency of the electronic medical record is improved. It becomes. It is also possible to reduce the burden on the user.

  That is, when forming a Hess figure based on the input indication point, it is essential to determine which indication point corresponds to which reference point. In addition to setting the input order, the correspondence between the indicated point and the reference point is established by setting which input order indicated point and the indicated point need a straight line. . Thereby, automation of the process of forming the Hess figure is realized.

  In addition, since the order in which the indication points are input can be changed as appropriate, the user can input the indication points in the familiar input order, so that it is possible to improve the efficiency of the electronic medical record input operation.

  In addition, when an indication point is input outside the effective display frames 1001R and 1001L provided on the input template screen 1000, an arrow in a direction toward the indication point is displayed instead of a straight line. It is possible to clearly indicate that the designated point has been input to the out-of-frame area.

  In addition, in order to check the inspection accuracy, when the same reference point is instructed again by the subject and the indicated point is input, a re-examination is required according to the displacement of a plurality of indicated points corresponding to the reference point. This is automatically determined, and if necessary, the result of the re-examination is set to a state in which the result can be input. Furthermore, even users who are unfamiliar with the Hess test can accurately recognize the necessity of re-examination, improving the operability of the system and performing the Hess test with good inspection accuracy. Can be done. In addition, when the indication point by re-examination is input, since a Hess figure is automatically formed and displayed, work efficiency is improved.

  Furthermore, when the inspection is performed a plurality of times in order to obtain an appropriate inspection result, the Hess figures corresponding to each inspection are displayed in different colors, so that the input operation at the time of the re-inspection can be performed without confusion. it can. Therefore, it is possible to improve the efficiency of the electronic medical record input work, and it is possible to prevent erroneous input. Moreover, when displaying the Hess figure which concerns on a some test | inspection simultaneously, it becomes possible to recognize the shape of each Hess figure easily.

  Furthermore, since the number of inspections until an accurate inspection result is obtained is automatically counted, it is possible to grasp the degree of understanding of the subject about the Hess test. This inspection number information can be used for smoothly performing the next inspection.

  In addition, since the disease of the eye to be examined is specified simply by inputting the indication point obtained by the examination, diagnosis support can be suitably performed. Particularly, skill is required for diagnosis by the Hess test, but according to the configuration of the present invention, even a user who is unfamiliar with this examination can make a diagnosis accurately. The corresponding relationship between the indicated point and the reference point is also used for this process.

  Note that the processing related to the diagnosis support is based on the coordinates of the pointing point, the length of the straight line, and the inclination, as is usually performed by a doctor, and thus the accuracy of the diagnosis is good.

  Furthermore, since the diagnosis process is executed to identify a monocular disease first and then to identify a binocular disease as usual, it is possible to obtain an accurate diagnosis result.

[Other processing procedures]
A processing procedure for making a diagnosis based on the displacement of the designated point with respect to the reference point will be described with reference to the flowchart shown in FIG. In the figure, components that perform the same processing as the steps shown in the flowchart of FIG. 6 are denoted by the same step numbers.

  In order to execute the processing procedure, the following disease data (not shown) is stored in the storage unit 12. This disease data is composed of monocular disease data and binocular disease data, as described above.

  The monocular disease data is configured in a tabular form for each disease name as shown in FIG. 4 (A). The indication points of the left eye numbers 1 to 9 and the right eye numbers 31 to 39 are shown. It includes a “displacement value” and an “effective range” with respect to the indication point. The “displacement value” indicates the displacement value of the indication point with respect to the corresponding reference point, and more specifically, the displacement value of the indication point that is typical in the case of suffering from the disease. “Effective range” indicates the range of displacement of the indicated point when the disease is affected. Further, the monocular disease data includes “search conditions” similar to those in FIG.

  On the other hand, the binocular disease data is configured in the same table format as that shown in FIG. 4B, and includes a “displacement value” and an “effective range” as in the case of the monocular disease data.

  Further, the control means 11 executes the disease selection program 109 to search for disease data in the same manner as the above-described processing procedure based on the displacement calculated using the indication point / reference point displacement calculation program 110. Identify the disease name.

  Hereinafter, another processing procedure by the electronic medical record input system of the present embodiment will be described.

  First, the user performs a predetermined operation to display the input template screen 1000 shown in FIG. 2 on the monitor device 13 (S1), and operates the mouse 15 and the like to display nine indication points obtained by the Hess test. Are input to the input template screen 1000 in a predetermined input order based on the input order setting information 500 (S2).

  When nine designated points are input, the control means 11 executes the designated point / reference point displacement calculation program 110 shown in FIG. 5 and calculates the displacement of each designated point with respect to the reference point (S21). For example, for the designated point of number 5, the displacement, that is, the distance from the central reference point (maru 1) shown in FIG. 2 is calculated. The displacement between the indication point and the reference point is calculated using the coordinates of the indication point and the reference point based on the coordinate system setting information 300 as described above.

  Next, in order to confirm whether or not the above examination has been properly performed, the user instructs the subject to again designate the first reference point in the above input order, and the designated point is displayed on the input template screen 1000. Input (S7). The control means 11 executes the designated point displacement calculation program 104 to obtain the coordinates of the designated point re-input in step S7, and the obtained coordinates and the coordinates of the designated point inputted first in step S2. Is calculated (S8). Further, the control means 11 executes the designated point displacement determination program 105, determines whether or not the displacement calculated in step S8 is equal to or greater than the displacement allowable value, and determines whether or not re-examination is necessary. (S9).

  When performing re-inspection (S9; Y), the control means 11 executes the re-inspection setting program 106 so that the input template screen 1000 can accept input of re-inspection results (S10). Steps S2 to S10 are repeated until it is determined that the displacement in the latest inspection (Mth) and the previous inspection (M-1) is less than the allowable displacement value.

  When the reexamination is not performed (S9; N), the control unit 11 executes the disease selection program 109 in response to the operation of the disease specifying button 2001 by the user, and the displacement between the indication point and the reference point acquired in step S21. Is selected from monocular disease data (S22).

  Furthermore, according to the disease selection program 109, the control means 11 selects the disease corresponding to the displacement between the indication point acquired in step S21 and the reference point from the binocular disease data by the same method (S23).

  The control means 11 executes the display control program 120 and causes the monitor device 13 to display the disease name specified in steps S22 and S23 as a diagnosis result (S24). The display form is the same as that according to the above-described processing procedure.

  The disease name identified in steps S22 and S23 is written in the electronic medical record of the subject when the user performs a predetermined operation. The electronic medical record is transmitted to the server 1 and stored in the database 5.

  According to such another processing procedure, the disease of the eye to be examined can be specified simply by inputting the indication point obtained by the examination, so that diagnosis support can be suitably performed. In particular, even a user unfamiliar with the Hess test can make a diagnosis accurately.

  In addition, since the other processing procedures are based on the displacement of the input indication point with respect to the reference point as normally performed by a doctor, the diagnostic accuracy is good.

  Furthermore, since the diagnosis process is executed to first identify a monocular disease and then to identify a bilateral disease as in a normal diagnosis, it is possible to obtain an accurate diagnosis result. .

[program]
The straight line calculation program 101, the input order setting program 102, the frame inside / outside determination program 103, the indication point displacement calculation program 104, the indication point displacement determination program 105, and the reexamination setting program included in the control program 100 shown in FIG. 106, display color setting program 107, examination count program 108, disease selection program 109, and indication point / reference point displacement calculation program 110 are programs that cause a computer to execute an electronic medical chart creation process according to the present invention. Is comprised. Here, the program of the present invention does not need to include all of these programs. For example, one or a plurality of programs are selected such as a configuration of only the straight line calculation program 101 or a configuration of only the disease selection program 109. It is possible to adopt a configuration that includes the above. The control program 100 can be created in any program language.

  The user of the electronic medical record input system can acquire and use the program according to the present invention by downloading the control program 3A stored in the storage unit 3 of the server 1 and storing it in the storage unit 12.

[Information recording medium]
The above-mentioned program included in the control program 100 can be recorded on any kind of computer-readable information recording medium such as a CD-ROM or DVD-ROM. The user can acquire and use a desired program by reading the contents of the information recording medium using a recording medium reading device such as a CD-ROM drive (not shown) of the electronic medical record input terminal 10.

  The configuration described in detail above is merely a specific example for carrying out the present invention. Therefore, it goes without saying that various modifications can be appropriately made within the scope of the gist of the present invention.

[Appendix]
Hereinafter, the electronic medical record input system according to the present invention realized by the above-described embodiment, a program for causing a computer to execute an electronic medical record creation process, and a characteristic configuration of a computer-readable information recording medium on which the program is recorded will be additionally described. To do.

[Additional Item 1]
A server with a database for storing each patient's electronic medical record;
The server is capable of communicating via a network, and has a display means for displaying an input screen for inputting information to the electronic medical record. The information input to the input screen is transmitted to the server through the network to transmit the electronic medical record. Including an electronic medical record input terminal to be created,
A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen An electronic medical chart input system for inputting a test result into an electronic medical chart for a Hess test for identifying a disease of an eye movement of a subject's eye with reference to a Hess figure formed by connecting straight points between ,
The display means displays an input template screen for a user to input the plurality of instruction points obtained in the Hess test in a predetermined order, and receives input of the plurality of instruction points on the input template screen. Display control means for displaying the straight line forming the Hess figure on the input template screen as the inspection result,
On the screen and the input template screen, the nine reference points are displayed in a grid of 3 rows and 3 columns, and the input order of the indication points corresponding to these reference points is center, upper, upper right, Right, bottom right, bottom, bottom left, left, top left,
The display control means, as the straight line forming the Hess figure, center and top, center and bottom, center and right, center and left, top and top right, top and top left, bottom and bottom right, bottom and bottom left, right And an upper right, a right and a lower right, a left and an upper left, and a straight line connecting instruction points associated with each other by a combination of left and lower left are displayed on the input template screen.

[Appendix 2]
A server with a database for storing each patient's electronic medical record;
The server is capable of communicating via a network, and has a display means for displaying an input screen for inputting information to the electronic medical record. The information input to the input screen is transmitted to the server through the network to transmit the electronic medical record. Including an electronic medical record input terminal to be created,
A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen An electronic medical chart input system for inputting a test result into an electronic medical chart for a Hess test for identifying a disease of an eye movement of a subject's eye with reference to a Hess figure formed by connecting straight points between ,
The display means displays an input template screen for a user to input the plurality of instruction points obtained in the Hess test in a predetermined order, and receives input of the plurality of instruction points on the input template screen. Display control means for displaying the straight line forming the Hess figure on the input template screen as the inspection result;
An input order setting means for setting the input order of the indication points for the input template screen;
An electronic medical record input system characterized by comprising:

  The input order setting means described in supplementary item 2 is configured by an input device such as a keyboard 14 and a mouse 15 of the electronic medical record input terminal 10 shown in FIG.

[Additional Item 3]
A server with a database for storing each patient's electronic medical record;
The server is capable of communicating via a network, and has a display means for displaying an input screen for inputting information to the electronic medical record. The information input to the input screen is transmitted to the server through the network to transmit the electronic medical record. Including an electronic medical record input terminal to be created,
A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen An electronic medical record input system for inputting a test result into an electronic medical chart for a Hess test for identifying a disease of an eye movement of a subject's eye with reference to a Hess figure formed by connecting straight points between ,
An input template screen for a user to input the plurality of instruction points obtained in the Hess test in a predetermined order is displayed on the display means, and the input of the plurality of instruction points to the input template screen is received. Display control means for displaying the straight line forming the Hess figure on the input template screen as the inspection result;
When a plurality of instruction points with the first input order are input on the input template screen, a displacement between the instruction point last input among the plurality of instruction points and the instruction point input immediately before is calculated. Displacement calculating means for
Displacement determining means for determining whether the displacement calculated by the displacement calculating means is equal to or greater than a predetermined allowable value;
When the displacement determination means determines that the displacement is greater than or equal to the predetermined allowable value, the input template screen is set to a state in which the instruction point acquired by the retest of the Hess test can be input. Inspection setting means;
An electronic medical record input system characterized by comprising:

[Additional Item 4]
A server with a database for storing each patient's electronic medical record;
The server is capable of communicating via a network, and has a display means for displaying an input screen for inputting information to the electronic medical record. The information input to the input screen is transmitted to the server through the network to transmit the electronic medical record. Including an electronic medical record input terminal to be created,
A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen An electronic medical chart input system for inputting a test result into an electronic medical chart for a Hess test for identifying a disease of an eye movement of a subject's eye with reference to a Hess figure formed by connecting straight points between ,
The display means displays an input template screen for a user to input the plurality of instruction points obtained in the Hess test in a predetermined order, and receives input of the plurality of instruction points on the input template screen. Display control means for displaying the straight line forming the Hess figure on the input template screen as the inspection result;
When a plurality of indicating points corresponding to the same reference point are input on the input template screen, a displacement between the indicating point input last and the indicating point input immediately before the specified indicating point Displacement calculating means for calculating
Displacement determining means for determining whether the displacement calculated by the displacement calculating means is equal to or greater than a predetermined allowable value;
When the displacement determining means determines that the displacement is greater than or equal to the predetermined allowable value, the input template screen is set to a state in which the instruction point obtained by retesting the Hess test can be input. Inspection setting means,
The display control means, in response to the indication point obtained by performing the re-inspection based on the setting by the re-inspection setting means being input to the input template screen, the Hess figure related to the re-inspection An electronic medical record input system, wherein the straight line forming the line is displayed on the input template screen.

[Additional Item 5]
The electronic medical record input system according to claim 4, wherein the display control means displays the Hess figure related to the reexamination together with the Hess figure already displayed on the input template screen.

[Additional Item 6]
Corresponding to the setting of the re-examination by the re-examination setting means, the straight line based on the designated point acquired by the re-examination is the straight line already displayed on the input template screen. The electronic medical chart input system according to item 5, further comprising display color setting means for displaying in different colors.

[Additional Item 7]
A server with a database for storing each patient's electronic medical record;
The server is capable of communicating via a network, and has a display means for displaying an input screen for inputting information to the electronic medical record. The information input to the input screen is transmitted to the server through the network to transmit the electronic medical record. Including an electronic medical record input terminal to be created,
A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen An electronic medical chart input system for inputting a test result into an electronic medical chart for a Hess test for identifying a disease of an eye movement of a subject's eye with reference to a Hess figure formed by connecting straight points between ,
The display means displays an input template screen for a user to input the plurality of instruction points obtained in the Hess test in a predetermined order, and receives input of the plurality of instruction points on the input template screen. Display control means for displaying the straight line forming the Hess figure on the input template screen as the inspection result;
When a plurality of indicating points corresponding to the same reference point are input on the input template screen, a displacement between the indicating point input last and the indicating point input immediately before the specified indicating point Displacement calculating means for calculating
Displacement determining means for determining whether the displacement calculated by the displacement calculating means is equal to or greater than a predetermined allowable value;
When the displacement determining means determines that the displacement is greater than or equal to the predetermined allowable value, the input template screen is set to a state in which the instruction point obtained by retesting the Hess test can be input. Inspection setting means;
Counting means for counting the number of times the displacement is determined to be greater than or equal to a predetermined tolerance by the displacement determining means;
Inspection number storage means for storing the number of times counted by the counting means;
An electronic medical record input system characterized by comprising:

  The counting means described in the supplementary item 7 is configured by the control means 11 of the electronic medical record input terminal 10 that executes the inspection number counting program of the control program 100. The examination number storage means is constituted by the storage means 12 of the electronic medical record input terminal 10.

[Additional Item 8]
A server with a database for storing each patient's electronic medical record;
The server is capable of communicating via a network, and has a display means for displaying an input screen for inputting information to the electronic medical record. The information input to the input screen is transmitted to the server through the network to transmit the electronic medical record. Including an electronic medical record input terminal to be created,
A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen An electronic medical chart input system for inputting a test result into an electronic medical chart for a Hess test for identifying a disease of an eye movement of a subject's eye with reference to a Hess figure formed by connecting straight points between ,
Display control means for causing the display means to display an input template screen for the user to input the plurality of indication points obtained in the Hess test in a predetermined order;
Monocular disease data in which the correspondence between the formation state of the Hess figure and the disease for a single eye to be examined is stored, and the binocular data in which the correspondence between the formation state of the Hess figure and the disease for both the left and right eye is stored Disease data storage means for storing disease data;
A disease corresponding to the formation state of the Hess figure formed based on the indication point input on the input template screen is selected from the monocular disease data and / or the binocular disease data and displayed on the display means. Diagnostic result display control means for causing
An electronic medical record input system characterized by comprising:

[Additional Item 9]
The diagnostic result display control means selects a disease for both eyes to be examined with reference to the binocular disease data after selecting a disease for the single eye to be examined with reference to the monocular disease data. The electronic medical record input system according to appendix 8.

[Appendix 10]
A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen A program that causes a computer to execute a process for inputting a test result into an electronic medical record for a Hess test that identifies a disease of eye movement of the eye to be examined by referring to a Hess figure formed by connecting straight line points between Because
A screen display step for causing a predetermined display means to display an input template screen for a user to input the plurality of indication points obtained in the Hess test in a predetermined order;
A display control step of receiving the input of the plurality of instruction points on the input template screen and displaying the straight line forming the Hess figure on the input template screen as the inspection result;
On the screen and the input template screen, the nine reference points are displayed in a grid of 3 rows and 3 columns, and the input order of the indication points corresponding to these reference points is center, upper, upper right, Right, bottom right, bottom, bottom left, left, top left,
The display control step includes the center and top, center and bottom, center and right, center and left, top and top right, top and top left, bottom and bottom right, bottom and bottom left, And a straight line connecting designated points associated with each combination of left and upper right, left and upper left, and left and lower left are displayed on the input template screen.

[Additional Item 11]
A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen A program that causes a computer to execute a process for inputting a test result into an electronic medical record for a Hess test that identifies a disease of eye movement of the eye to be examined by referring to a Hess figure formed by connecting straight line points between Because
An input order setting step for setting the input order in response to a request for setting the input order of the pointing points on an input template screen for a user to input the plurality of pointing points obtained in the Hess test in a predetermined order When,
A screen display step for displaying the input template screen on a predetermined display means;
In response to the plurality of designated points being input in accordance with the set input order with respect to the displayed input template screen, the straight line forming the Hess figure is displayed on the input template screen as the inspection result. A display control step for displaying the program.

[Additional Item 12]
A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen A program that causes a computer to execute a process for inputting a test result into an electronic medical record for a Hess test that identifies a disease of eye movement of the eye to be examined by referring to a Hess figure formed by connecting straight line points between Because
A screen display step for causing a predetermined display means to display an input template screen for a user to input the plurality of indication points obtained in the Hess test in a predetermined order;
A display control step of receiving input of the plurality of instruction points on the input template screen and displaying the straight line forming the Hess figure on the input template screen as the inspection result;
When a plurality of instruction points with the first input order are input on the input template screen, a displacement between the instruction point last input among the plurality of instruction points and the instruction point input immediately before is calculated. A displacement calculating step,
A displacement determining step of determining whether or not the displacement calculated by the displacement calculating step is greater than or equal to a predetermined allowable value;
When the displacement determining step determines that the displacement is greater than or equal to the predetermined allowable value, the input template screen is set to a state in which the instruction point obtained by retesting the Hess test can be input. Inspection setting step;
A program characterized by comprising:

[Additional Item 13]
A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen A program that causes a computer to execute a process for inputting a test result into an electronic medical record for a Hess test that identifies a disease of eye movement of the eye to be examined by referring to a Hess figure formed by connecting straight line points between Because
A screen display step for causing a predetermined display means to display an input template screen for a user to input the plurality of indication points obtained in the Hess test in a predetermined order;
A display control step of receiving input of the plurality of instruction points on the input template screen and displaying the straight line forming the Hess figure on the input template screen as the inspection result;
When a plurality of indicating points corresponding to the same reference point are input on the input template screen, a displacement between the indicating point input last and the indicating point input immediately before the specified indicating point A displacement calculating step for calculating
A displacement determining step of determining whether or not the displacement calculated by the displacement calculating step is greater than or equal to a predetermined allowable value;
When the displacement determining step determines that the displacement is greater than or equal to the predetermined allowable value, the input template screen is set to a state in which the instruction point obtained by retesting the Hess test can be input. Inspection setting step;
In response to the indication point by the reinspection based on the setting in the reinspection setting step being input to the input template screen, the straight line forming the Hess figure related to the reinspection is used as the inspection result. Steps to be displayed on the input template screen;
A program characterized by comprising:

[Additional Item 14]
The program according to claim 13, wherein the display control step displays the Hess graphic related to the reexamination together with the Hess graphic already displayed on the input template screen.

[Appendix 15]
15. The supplementary item 14, wherein the display control step displays the straight line forming the Hess figure related to the reexamination in a color different from the straight line already displayed on the input template screen. Program.

[Additional Item 16]
A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen A program that causes a computer to execute a process for inputting a test result into an electronic medical record for a Hess test that identifies a disease of eye movement of the eye to be examined by referring to a Hess figure formed by connecting straight line points between Because
A screen display step for causing a predetermined display means to display an input template screen for a user to input the plurality of indication points obtained in the Hess test in a predetermined order;
A display control step of receiving input of the plurality of instruction points on the input template screen and displaying the straight line forming the Hess figure on the input template screen as the inspection result;
When a plurality of indicating points corresponding to the same reference point are input on the input template screen, a displacement between the indicating point input last and the indicating point input immediately before the specified indicating point A displacement calculating step for calculating
A displacement determining step of determining whether or not the displacement calculated by the displacement calculating step is greater than or equal to a predetermined allowable value;
When the displacement determining step determines that the displacement is greater than or equal to the predetermined allowable value, the input template screen is set to a state in which the instruction point obtained by retesting the Hess test can be input. Inspection setting step;
A counting step for counting the number of times the displacement is determined to be greater than or equal to a predetermined allowable value in the displacement determining step;
An inspection number storage step for storing the counted number of times;
The program according to appendix 21, wherein the program is provided.

[Additional Item 17]
A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen A program that causes a computer to execute a process for inputting a test result into an electronic medical record for a Hess test that identifies a disease of eye movement of the eye to be examined by referring to a Hess figure formed by connecting straight line points between Because
The computer stores monocular disease data in which the correspondence between the formation state of the Hess figure for a single eye to be examined and the disease is stored, and / or the formation state and disease of the Hess figure for both the left and right eye to be examined. Binocular disease data that stores correspondence is stored,
A screen display step for causing a predetermined display means to display an input template screen for a user to input the plurality of indication points obtained in the Hess test in a predetermined order;
The disease corresponding to the formation state of the Hess figure formed based on the indication point input on the input template screen is selected from the monocular disease data and / or the binocular disease data, and the selected A diagnostic result display control step for displaying a disease on the display means as the test result;
A program characterized by comprising:

[Appendix 18]
The diagnostic result display control step selects a disease for both eyes to be examined with reference to the binocular disease data after selecting a disease for the single eye to be examined with reference to the monocular disease data. Item 18. The program according to item 17.

[Appendix 19]
A computer-readable information recording medium in which the program according to any one of Supplementary Items 10 to 18 is recorded.

It is a block diagram which shows an example of a structure of embodiment of the electronic medical record input system which concerns on this invention. It is the schematic which shows an example of the input template screen by which the test result of the Hess test displayed by embodiment of the electronic medical record input system which concerns on this invention is input. It is the schematic for demonstrating an example of the display process of the input template screen displayed by embodiment of the electronic medical record input system which concerns on this invention. It is a figure which shows an example of schematic structure of the disease data referred in order to diagnose the disease of the eye to be examined by embodiment of the electronic medical record input system which concerns on this invention. FIG. 4A shows monocular disease data, and FIG. 4B shows binocular disease data. It is the schematic which showed an example of the structure of the control program performed in order to perform the process by embodiment of the electronic medical record input system which concerns on this invention. It is the flowchart which showed an example of the process sequence performed by embodiment of the electronic medical record input system which concerns on this invention. It is the flowchart which showed an example of the process sequence performed by embodiment of the electronic medical record input system which concerns on this invention. It is the schematic for demonstrating an example of the display process of the input template screen displayed by embodiment of the electronic medical record input system which concerns on this invention. It is a figure which shows an example of schematic structure of the input screen displayed by embodiment of the electronic medical record input system which concerns on this invention. It is a figure which shows an example of schematic structure of the input screen displayed by embodiment of the electronic medical record input system which concerns on this invention. It is the flowchart which showed the other process sequence performed by embodiment of the electronic medical record input system which concerns on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Server 5 Database 10 Electronic medical record input terminal 11 Control means 12 Storage means 100 Control program 101 Straight line calculation program 102 Input order setting program 103 Inside / outside frame determination program 104 Point point displacement calculation program 105 Point point displacement determination program 106 Reexamination setting program 107 Display color setting program 108 Exam number count program 109 Disease selection program 110 Point / reference point displacement calculation program 200 Input template data 300 Coordinate system setting information 400 In-frame region setting information 500 Input order setting information 600 Point point related information 700 Monocular disease Data 800 Binocular disease data 13 Monitor device 14 Keyboard 15 Mouse 1000 Input template screen 1000L Left eye input template 1000 Right eye input template 1001L, 1001R effective display frame 2000 input screen 2001 Disease specific button 2002 Comments display unit

Claims (17)

A server with a database for storing each patient's electronic medical record;
The server is capable of communicating via a network, and has a display means for displaying an input screen for inputting information to the electronic medical record. The information input to the input screen is transmitted to the server through the network to transmit the electronic medical record. Including an electronic medical record input terminal to be created,
A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen An electronic medical chart input system for inputting a test result into an electronic medical chart for a Hess test for identifying a disease of an eye movement of a subject's eye with reference to a Hess figure formed by connecting straight points between ,
The display means displays an input template screen for a user to input the plurality of instruction points obtained in the Hess test in a predetermined order, and receives input of the plurality of instruction points on the input template screen. An electronic medical record input system comprising display control means for displaying the straight line forming the Hess figure on the input template screen as the inspection result.   The display control means has a straight line calculation means for calculating the length and inclination of the straight line based on the coordinates of the designated point in the coordinate system set on the input template screen, and the calculation result by the straight line calculation means The electronic medical record input system according to claim 1, wherein the straight line is displayed on the input template screen based on the information.   In response to the indication point being input outside the effective display frame set in the input template screen, the display control means, instead of the straight line connecting the indication point and another indication point, The electronic medical record input system according to claim 1, wherein an arrow in a direction from the other indication point toward the indication point is displayed. When a plurality of indicating points are input to the input template screen with respect to the same reference point, the displacement between the indicating point last input among the indicating points and the indicating point input immediately before it Displacement calculating means for calculating
Displacement determining means for determining whether the displacement calculated by the displacement calculating means is equal to or greater than a predetermined allowable value;
Re-inspection setting means for setting the input template screen in a state in which an instruction point by re-inspection of the Hess test can be input when the displacement is determined by the displacement determination means to be equal to or greater than the predetermined allowable value. When,
The electronic medical record input system according to claim 1, further comprising:   Corresponding to the setting of the re-inspection by the re-inspection setting means, the display apparatus further comprises display color setting means for displaying a plurality of designated points corresponding to the same reference point in different colors. The electronic medical record input system according to claim 4, characterized in that: A server with a database for storing each patient's electronic medical record;
The server is capable of communicating via a network, and has a display means for displaying an input screen for inputting information to the electronic medical record. The information input to the input screen is transmitted to the server through the network to transmit the electronic medical record. Including an electronic medical record input terminal to be created,
A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen An electronic medical chart input system for inputting a test result into an electronic medical chart for a Hess test for identifying a disease of an eye movement of a subject's eye with reference to a Hess figure formed by connecting straight points between ,
Display control means for causing the display means to display an input template screen for the user to input the plurality of indication points obtained in the Hess test in a predetermined order;
Disease data storage means for storing disease data in which the correspondence between the formation state of the Hess graphic and the disease is stored;
Diagnosis result display control means for selecting a disease corresponding to the state of formation of the Hess figure formed based on the indication point input on the input template screen from the disease data and displaying it on the display means as the examination result When,
An electronic medical record input system characterized by comprising:   The diagnostic result display control means has a straight line calculation means for calculating the length and inclination of the straight line forming the Hess figure based on the coordinates of the designated point in the coordinate system set on the input template screen. The electronic medical record input system according to claim 6, wherein the disease is selected from the disease data based on the coordinates of the indication point and the calculation result by the straight line calculation unit and displayed on the display unit. .   The diagnostic result display control means has indicated point / reference point displacement calculating means for calculating a displacement between the indicated point input on the input template screen and the corresponding reference point. 7. The electronic medical record input system according to claim 6, wherein the disease is selected from the disease data based on the calculation result by the reference point displacement calculating means and displayed on the display means. A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen A program that causes a computer to execute a process for inputting a test result into an electronic medical record for a Hess test that identifies a disease of eye movement of the eye to be examined by referring to a Hess figure formed by connecting straight line points between Because
A screen display step for causing a predetermined display means to display an input template screen for a user to input the plurality of indication points obtained in the Hess test in a predetermined order;
A display control step of receiving input of the plurality of instruction points on the input template screen and displaying the straight line forming the Hess figure on the input template screen as the inspection result;
A program characterized by comprising:   The display control step includes a straight line calculation step of calculating a length and a slope of the straight line based on the coordinates of the indication point in the coordinate system set on the input template screen, and the input based on the calculation result The program according to claim 9, wherein the straight line is displayed on a template screen.   In response to the indication point being input outside a predetermined effective display frame of the input template screen, the display control step is configured to replace the indication point and another indication point instead of the straight line. The program according to claim 9, wherein an arrow in a direction from another indication point toward the indication point is displayed. When a plurality of indicating points are input to the input template screen with respect to the same reference point, the displacement between the indicating point last input among the indicating points and the indicating point input immediately before it A displacement calculating step for calculating
A displacement determining step of determining whether or not the displacement calculated by the displacement calculating step is greater than or equal to a predetermined allowable value;
Re-inspection setting step for setting the input template screen in a state in which an instruction point by re-inspection of the Hess test can be input when the displacement is determined to be greater than or equal to the predetermined allowable value in the displacement determination step. When,
The program according to claim 9, further comprising:   In response to the setting of the re-inspection in the re-inspection setting step, the method further comprises a step of displaying a plurality of designated points corresponding to the same reference point in different colors. The program according to claim 12. A plurality obtained by instructing the subject on the position on the screen, which is localized by the other eye when one eye of the subject is fixed at each of a plurality of reference points provided on the screen A program that causes a computer to execute a process for inputting a test result into an electronic medical record for a Hess test that identifies a disease of eye movement of the eye to be examined by referring to a Hess figure formed by connecting straight line points between Because
A screen display step for causing a predetermined display means to display an input template screen for a user to input the plurality of indication points obtained in the Hess test in a predetermined order;
The disease corresponding to the formation state of the Hess figure formed based on the indication point input on the input template screen is selected from disease data in which the correspondence between the formation state of the Hess figure and the disease is stored. A diagnostic result display control step for displaying the selected disease on the display means as the test result;
A program characterized by comprising:   The diagnostic result display control step includes a step of calculating the length and inclination of the straight line forming the Hess figure based on the coordinates of the indication point in the coordinate system set on the input template screen, The program according to claim 14, wherein the disease is selected from the disease data based on the coordinates of the designated point and the calculated length and inclination of the straight line and is displayed on the display unit.   The diagnostic result display control step includes a step of calculating a displacement with respect to the corresponding reference point with respect to the indication point input on the input template screen, and based on the calculated displacement, the disease state is calculated from the disease state data. The program according to claim 14, wherein the program is selected and displayed on the display means. A computer-readable information recording medium in which the program according to any one of claims 9 to 16 is recorded.

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