JP2006122160A - Ophthalmic measurement apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ophthalmic measurement apparatus capable of accurately obtaining an actual distance on an eye fundus. <P>SOLUTION: The eye fundus is photographed by a photographing optical system in which a mask determining the photographing range of the eye fundus is arranged at an eye fundus conjugate position, and it is displayed on a display part 50. Two points P1 and P2 are specified on a displayed fundus image, the size of the mask on the eye fundus calculated in accordance with the diopter of an eye to be examined and an ocular axial length is read, and from a coordinate distance d1 on the display image of the mask and a coordinate distance d2 on the display image between the two specified points, the actual distance of d2 on the eye fundus is computed. In such constitution, since the actual distance on the eye fundus is obtained on the basis of the information of the eye to be examined affecting a photographing magnification and the information of the photographing optical system, the actual distance on the eye fundus can be accurately obtained. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an ophthalmologic measurement apparatus, and more particularly to an ophthalmologic measurement apparatus that calculates an actual fundus distance from a fundus image on a screen.

  There is a demand for a fundus camera to look at the photographed fundus photograph to determine the size of the lesion and the distance on the retina from the lesion to the macula. As described in Patent Document 1, photodynamic therapy (PDT therapy) for irradiating a lesion with a laser beam in a spot shape and treating age-related macular degeneration is known. This is because an actual distance on the retina is required to form a simple laser spot. When treating a lesion by irradiating it with spot light, it is a problem whether the spot size of the light beam to be irradiated is too large or too small. It is required to form with. Generally, it is said that a spot size having a maximum lesion diameter of +1 mm is optimal. For that purpose, the maximum diameter of the lesioned part must be accurately measured in advance, and the size of the lesioned part maximum diameter + 1 mm must be set as the light spot size.

  Conventionally, in order to obtain the distance between predetermined points on the retina, it is assumed that the morbid diopter is 0 diopter, and the actual length from the captured image is determined from the specifications of the optical system of the fundus camera used for photographing. The conversion magnification to be determined is determined, and the magnification is applied to the captured image to obtain the length on the retina. In this case, there are of course individual differences in the optical system of the fundus camera, so in order to eliminate this, a model eye with an eye diopter of 0 diopter is used and masked when it is photographed with the fundus camera. The conversion magnification was determined by determining the length of the retina that could be captured in full by simulation.

However, the diopter of the actual eye to be examined varies, and the axial length and corneal curvature also vary. Further, a problem has been pointed out that the focal length (magnification) of the fundus camera changes due to the focus operation of the fundus camera (Patent Document 2). Therefore, in the conventional distance calculation assuming that the affected eye diopter is 0 diopter, it is difficult to obtain an accurate actual distance on the fundus with many errors.
JP 2000-60893 JP 2003-225208 A (paragraph [0003])

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an ophthalmologic measurement apparatus that can accurately determine the actual distance on the fundus.

The present invention (Claim 1)
An imaging optical system for acquiring an electronic image of the fundus, a display unit for displaying the captured electronic image of the fundus, a designation unit for designating a point on the image displayed on the display unit, or a circle on the image An ophthalmologic measurement apparatus comprising: a drawing unit that draws the image; and a calculation unit that calculates an actual distance on the fundus between the specified predetermined points or a real distance on the fundus corresponding to the diameter of the drawn circle. There,
Based on the information about the eye diopter, information about the eye axis length of the eye to be examined, part or all of the information about the eye cornea curvature of the eye to be examined, and information on the photographing optical system, Is calculated.

The present invention (Claim 6)
A photographing optical system for photographing a fundus electronic image in which a mask for defining a fundus photographing range is arranged at a fundus conjugate position, display means for displaying the photographed electronic image, and an image displayed on the display means A designating means for designating a point or a drawing means for drawing a circle on the image, and an actual distance on the fundus between the designated predetermined points or an actual distance on the fundus corresponding to the diameter of the drawn circle is calculated. An ophthalmologic measuring device comprising a computing means,
Storage means for storing the size of the mask on the fundus calculated according to the eye information to be examined that affects the imaging magnification is provided,
The arithmetic means calculates the mask size on the fundus according to the eye information to be examined read from the storage means, the coordinate distance on the display screen of the mask, and the coordinate distance on the display screen between specified predetermined points. Alternatively, the actual distance on the fundus is calculated based on the coordinate distance on the display screen corresponding to the diameter of the drawn circle.

  In the present invention, the focusing lens emits light according to information such as the eye diopter to be examined, the eye length of the eye to be examined, the corneal curvature of the eye to be examined, the photographing magnification of the photographing optical system, and the eye diopter to be examined. Since the actual distance on the fundus is obtained based on information of the photographing optical system such as a change in photographing magnification caused by moving in the axial direction, the actual distance on the fundus can be obtained accurately. .

  The present invention relates to position information of a focus lens (focusing lens) or the previously measured eye diopter, one of the three pieces of information of the separately measured eye axis length and the separately measured corneal curvature. Using a part or all (usually two), the distance between predetermined points on the fundus from the fundus image or the distance on the fundus corresponding to the diameter of the circle drawn on the fundus image Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 shows the structure of a fundus camera main body 30 that captures a fundus image used in the present invention as an electronic image. The light reflected by the illumination lamp 1 and the mirror 1 ′ includes a filter 2 and a condenser lens 3. , Through the strobe 4 and the condenser lens 5, and then reflected by the total reflection mirror 6, followed by the lens 7, the ring slit 8 for forming ring-shaped illumination, the relay lens 9, and the total reflection with a hole having a hole in the center. After being reflected by the mirror 10, the light enters the fundus Er of the eye E through the objective lens 11.

  Reflected light from the fundus Er is received through the objective lens 11, passes through the hole of the perforated total reflection mirror 10, passes through the focusing lens (focus lens) 15, and the zoom lens 14 (14 ′) and returns. Incident on the mirror 16. The return mirror 16 is inserted at the position shown in the figure at the time of observation, the fundus image is guided to the observation unit 19 via the mirror 17 and the lens group 18, and the fundus is observed by the examiner. When photographing or measuring the actual distance on the fundus according to the present invention, the return mirror 16 is retracted from the optical path, and the fundus image is transferred to the CCD camera (through the mask 32 and the imaging lens 33 for defining the fundus photographing range). The photoelectric conversion element 31 receives the light and the fundus is photographed as an electronic image. The mask 32 is a mask having a circular opening, and both the mask 32 and the light receiving surface of the CCD camera 31 are disposed at the fundus conjugate position. Further, in this photographing optical system, the focusing lens 15 is movable in the optical axis direction in order to adjust the fluctuation of the image forming position depending on the eye diopter.

  Further, at the time of fluorescent photographing, the exciter filter 13 and the barrier filter 22 are inserted into the optical path.

  Upon receiving an operation signal from the operation unit 23, the CPU 12 turns on / off the lamp 1, inserts / removes the filters 2, 13, 22 in accordance with the photographing mode, light emission of the strobe 4 synchronized with the operation of the shutter 32, and scaling. It controls the exchange of the lenses 14, 14 ', the insertion / removal of the return mirror 16, etc., and captures the time information of the timer 21 that is activated at the start of fluorescent photographing and the position information of the focusing lens 15 that is moved manually, The shooting mode is determined from the operation unit 23, shutter 32, timer information, and the like. For example, when the filter 2 is inserted, it is a special imaging mode (for example, infrared fluorescent imaging), and when the exciter filter 13 and / or the barrier filter 22 is inserted, or when the timer 21 is activated. Is a fluorescent photographing mode, and if the variable magnification lenses 14 and 14 ′ are exchanged, it is determined that the zooming mode is selected, and the type of the determined photographing mode is transmitted to the image processing unit 40. Further, the CPU 12 controls the operation of the CCD camera 31.

  The fundus image obtained by the CCD camera 31 is subjected to appropriate image processing in accordance with the photographing mode and photographing conditions by the image processing unit 40, and the fundus image subjected to the image processing is stored in the data recording / storing unit (storage means) 41. It is stored in association with the eye identification information to be examined, and is displayed as an image on the display unit (display means) 50.

  The display unit 50 is provided with a touch panel (point specifying means) 51. As will be described later, when the actual distance between two points on the fundus retina is obtained, the panel is touched to specify a location corresponding to the two points. To do.

  In addition, a data input unit (input unit) 43 is provided, and information such as the eye diopter, the axial length, and the corneal curvature radius is input via the data input unit 43. This is an operation that involves entering data into the database, using the keyboard while looking at the screen. In addition, various types of information relating to the fundus can be taken into the data recording / storing unit 41 via the network 44 or can be sent from the data recording / storing unit 41 to the network 44.

  The calculation unit (calculation means) 42 calculates the actual distance between the two specified points based on the point indication on the touch panel, the input data, the shooting condition information, the type of the fundus camera, and the like. The calculation data is stored in the data recording storage unit 41 in association with the eye identification information together with other related fundus image data.

  Generally, if the photographing magnification is known (if it is fixed), the actual distance between two points on the fundus can be immediately known from the captured image. However, when measuring the distance between two points on the fundus retina, since the eye to be examined forms part of the optical system, the imaging magnification varies due to individual differences, and accurate distance measurement cannot be performed.

  There are three factors that cause this individual difference: eye diopter, eye axis length to be examined, and eye cornea curvature to be examined. For accurate measurement, it is necessary to know these factors for each eye to be examined. . These three elements are related to each other, and if two of them are known, the remaining one can be derived, so that ray tracing (computer simulation) using a model eye (model eye) as shown in FIG. The distance ratio radius of the entire cornea is obtained with respect to the eye diopter and the axial length, and is stored in the data recording storage unit 41 as a table, for example.

  On the other hand, the magnification of the optical system of the imaging device may also vary depending on the eye diopter (see Patent Document 2). This occurs when the focusing lens 15 is moved in the direction of the optical axis in order to correct the shift of the imaging position due to the eye diopter by performing focus adjustment during imaging. If the shooting magnification changes, the shooting range naturally changes. Therefore, for example, the diopter x is changed, the retinal shooting range y that changes as the shooting magnification changes is calculated, and the relationship is depicted in FIG. The relationship is as shown.

  The diopter is determined by the corneal curvature radius and the axial length. However, even with the same diopter, if the corneal curvature radius is different, the imaging magnification changes and the imaging range changes. This relationship is shown in FIG. 4 in which the diopter is selected from three types of 0D (diopter = 0) and ± 10D (diopter = ± 10), and the imaging range (y) is shown with respect to the corneal curvature radius (x). Has been.

  Since these variations are within the optical design selection range (within the designer's discretion), they vary depending on the fundus camera. Of course, if the fundus camera has a scaling function, it is obvious that the imaging magnification changes accordingly.

  Therefore, in the present invention, information relating to the diopter of the eye to be measured, information relating to the axial length of the eye to be examined, and information relating to the corneal curvature of the eye to be examined are input from the data input unit 43, and the three pieces of information are also included. The actual distance of the fundus is calculated based on a part or all of the above and information on the photographing optical system including the focusing lens 15, the variable magnification lens 14 (14 '), the mask 32, and the like.

  As information on the photographing optical system, information on the size of the mask 32, information on fluctuations in photographing magnification caused by the movement of the focusing lens 15 in the optical axis direction, information on magnification by the variable magnification lens 14 (14 ′), and the like. Based on this information, the fundus imaging range determined by the mask 32 is determined from information on the eye diopter, eye axis length to be examined, and corneal curvature of the eye to be examined. Further, since this imaging range corresponds to the size of the mask image on the screen of the display unit, the calculation unit 42 is designated with the imaging range of the fundus and the coordinate distance of the mask image on the screen. Based on the coordinate distance between the two points on the screen, the actual distance on the fundus between the two specified points is calculated.

  In order to facilitate the calculation, a model A eye fundus camera with known specifications such as mask size and photographing magnification is used in advance, a model eye is used, a virtual light source is placed on the mask, and the diopter and eye The light source image on the retina is traced by ray tracing by changing the axial length, and the retinal imaging range is obtained. Then, as shown in FIG. 5, this is stored in the data record storage unit 41 in the form of a table. According to this table, for example, with a fundus camera of model A having a predetermined mask size and photographing magnification (corresponding to an angle of view of 50 degrees), the diopter of the eye to be examined is “0” and the axial length is “24 mm”. It can be seen that the imaging range of the retina is “13.07 mm” (corresponding to the size of the mask on the retina). Since this mask appears as a mask image 32 'in the display section 50 of the mask 32 shown in FIG. 7, it can be seen that the actual distance on the retina having the diameter d1 of the opening of the mask is "13.07 mm".

  Preferably, a table as shown in FIG. 5 is created for each type of fundus camera and stored in the data recording storage unit 41.

  With the above configuration, the first example in which the diopter of the affected eye and the axial length are known, the second example in which the diopter and corneal curvature of the affected eye are known, and the diopter of the affected eye is unknown A method for obtaining the actual distance between two points of the fundus image on the screen will be described for the third example.

  First, in the first example, the diopter of the affected eye has already been measured with a refraction inspection instrument (autorefractometer) or the like, and the axial length has been measured with an ultrasonic diagnostic apparatus (A mode) or the like. When the data record storage unit 41 is associated with the identification information (ID-No and left eye / right eye) and is stored in a database, these values are obtained from the identification information of the eye to be examined input via the data input device. read out. If the database is not available, the measured diopter and axial length are directly input from the data input unit 43.

  Also, depending on the model, the shooting magnification varies, or there is a variation in magnification due to diopter, and the fundus image shooting range (mask size on the fundus image) varies, so as described above, for each model, A table as shown in FIG. 5 is stored in the data recording storage unit 41. Therefore, by inputting the model of the fundus camera to be used from the data input unit 43 and reading a table corresponding to the model, the calculation unit 42 obtains an imaging range from the diopter and the axial length of the eye to be examined.

  For example, as shown in FIG. 6, when a fundus camera model “A”, a diopter “+2.0 diopter”, and an axial length “22.0 mm” are input, an imaging range “11” on the retina is shown in FIG. .87 mm "is obtained. The value of the retinal imaging range corresponds to the actual distance of the diameter d1 of the mask image 32 'as shown in FIG. Therefore, when the two points P1 and P2 in the vicinity of the lesion 61 in the fundus image 60 are designated via the touch panel 51, the calculation unit 42 determines the coordinate distance d2 between the two points P1 and P2 from the coordinate value of P1 and the coordinate value of P2. And by specifying the points P3 and P4 of the mask image, the coordinate distance d1 corresponding to the diameter is obtained. And the calculating part 42 can obtain | require the real distance of d2 by proportional calculation from the ratio of d1 and d2, and the real distance (11.87 mm) of d1. In FIG. 7, the actual distance “2.5 mm” is displayed on the display unit 50, and the obtained actual distance between the two points P <b> 1 and P <b> 2 on the retina is image information specifying a predetermined point or an image of a predetermined point. The data is stored in the data recording storage unit 41 together with the coordinate information of P1 and P2 above.

  Next, in a second example in which the eye diopter is known but the axial length is not known, the corneal curvature may be known from the measurement result with a keratometer or the like. In such a case, since the data record storage unit 41 stores data as shown in FIG. 2, a cell corresponding to a known corneal curvature is obtained from the horizontal line of diopter from this data, The axial length corresponding to the cell is obtained. If the axial length is known, the actual distance on the fundus can be obtained from the distance between two predetermined points on the fundus image by the same method as in the first example.

  On the other hand, in the case of the third example in which the eye diopter is unknown, the diopter is obtained using information obtained when the fundus camera is focused. In this case, a scale is provided on the adjustment knob of the focusing lens 15, and the position of the focusing lens is detected by inputting a number at the time of focusing or as shown in FIG. By making it output, diopter can be input. When the axial length is known, the method is the same as in the first example, and when the corneal curvature radius is known, the axial length is obtained according to the second example, and according to the first example, Find the actual distance.

  In the above-described embodiment, two points are specified from the touch panel 51 to determine the lesion, but as shown in FIG. 8, a circle surrounding the lesion 61 is drawn by the CPU 12 or the drawing unit of the calculation unit 42. The actual distance on the fundus corresponding to the diameter of the circle (distance d4 between P5 and P6) may be calculated.

  In the embodiment of FIG. 1, the focusing lens 15 may be electrically controlled by a stepping motor or the like from the operation unit 23 via the CPU 12 instead of manually. In this case, the position of the focusing lens can be known without providing a position detection mechanism.

  The data input unit 43 is generally a keyboard or the like on which an operator inputs a numerical value. However, if the data input unit 43 is replaced with a system connected to another measurement device via the network 44, the measurement result of the other measurement device is directly used as the network 44. Can be used for calculation, or can be read from the data recording storage unit 41 and used for calculation.

  Further, the mask 32, the lens 33, and the CCD 31 are separately configured. However, if the mask can be attached to the light receiving surface of the CCD 31, or if an electronic mask process is performed, the mask 32 and the lens 33 are not necessary. This light receiving surface may be placed at the position of the mask 32.

  Further, the predetermined point designating means may be a mouse or a means conforming to a mouse as found in a normal computer, instead of a touch panel system that designates directly from the screen.

It is the block diagram which showed the structure of the ophthalmic measurement apparatus of this invention. It is a table | surface figure which shows the relationship between a diopter, an axial length, and a corneal curvature radius. It is a graph which shows the relationship between a diopter and a retina imaging | photography range. It is the graph which showed the relationship between a corneal curvature radius and a retina imaging | photography range according to diopter. It is a table | surface figure which shows the relationship between a diopter, an axial length, and a retina imaging | photography range. It is a screen figure which shows a data input screen. It is a screen figure when calculating | requiring the real distance on the fundus between two points on the designated fundus. It is a screen figure when calculating | requiring the real distance on the fundus corresponding to the diameter of the drawn circle.

Explanation of symbols

12 CPU
14, 14 'zoom lens 15 focusing lens
16 mask 31 CCD
40 Image processing device 41 Data recording / storing unit 42 Calculation unit 43 Data input unit

Claims (10)

An imaging optical system for acquiring an electronic image of the fundus, a display unit for displaying the captured electronic image of the fundus, a designation unit for designating a point on the image displayed on the display unit, or a circle on the image In an ophthalmologic measurement apparatus comprising: a drawing unit that draws an image; and a calculation unit that calculates an actual distance on the fundus between the specified predetermined points or an actual distance on the fundus corresponding to the diameter of the drawn circle ,
The computing means is based on information on the eye diopter, information on the eye axis length of the eye to be examined, part or all of information on the eye cornea curvature of the eye to be examined, and information on the photographing optical system, and the actual distance on the fundus An ophthalmologic measuring apparatus characterized by calculating   The ophthalmic measurement apparatus according to claim 1, wherein the information on the photographing optical system includes information on a size of a mask arranged at a fundus conjugate position in the photographing optical system.   The information of the photographing optical system includes variation information of photographing magnification that is generated when the focusing lens for adjusting the variation of the imaging position depending on the eye diopter moves in the optical axis direction. The ophthalmologic measurement apparatus according to claim 1 or 2.   The ophthalmic measurement apparatus according to claim 1, wherein the photographing optical system has a zooming function, and information on the photographing optical system includes zooming information.   The ophthalmologic measurement apparatus according to claim 3 or 4, wherein the information on the eye diopter to be examined includes movement information of the focusing lens in the optical axis direction. A photographing optical system for photographing a fundus electronic image in which a mask for defining a fundus photographing range is arranged at a fundus conjugate position, a display unit for displaying a photographed electronic image, and an image displayed on the display unit A designating means for designating a point or a drawing means for drawing a circle on the image, and an actual distance on the fundus between the designated predetermined points or an actual distance on the fundus corresponding to the diameter of the drawn circle is calculated. In an ophthalmologic measurement apparatus comprising a computing means,
Storage means for storing the size of the mask on the fundus calculated according to the eye information to be examined that affects the imaging magnification is provided,
The calculation means includes a mask size on the fundus corresponding to the eye information to be examined read from the storage means, a coordinate distance on the display screen of the mask, and a coordinate distance on the display screen between specified predetermined points. Alternatively, the fundus measurement apparatus calculates an actual distance on the fundus based on a coordinate distance on the display screen corresponding to the diameter of the drawn circle.   The ophthalmologic measurement apparatus according to claim 6, wherein the eye information to be examined that affects the imaging magnification is a test eye diopter, a test eye axial length, a test eye corneal curvature, or a combination thereof.   The mask size on the fundus stored in the storage means is determined by the imaging magnification of the imaging optical system and the focusing lens in the optical axis direction for focusing for each eye diopter and eye axis length to be examined. The ophthalmologic measurement apparatus according to claim 6, wherein the ophthalmologic measurement apparatus is calculated in consideration of a change in imaging magnification caused by the operation.   The ophthalmic imaging apparatus according to claim 6, wherein the mask size is calculated using a model eye. Using the model eye, the relationship between the eye diopter, eye length of the eye to be examined, and corneal curvature of the eye to be examined is calculated in the form of a table, and one other information is obtained from the table based on any two pieces of information. The ophthalmic measurement apparatus according to claim 7, wherein the ophthalmologic measurement apparatus is provided.