JP7387343B2 - Image processing device, image processing program - Google Patents

Description

The present invention relates to an image processing device that forms a tomographic image of an eye to be examined , and an image processing program .

OCT (Optical Coherence Tomography) devices that utilize multi-wavelength light wave interference are widely used in ophthalmological diagnosis and the like to obtain tomographic images of the retina in the fundus of the examined eye and tomographic images of the anterior segment of the eye such as the cornea. .

In order to analyze the layer structure of the retina on the acquired tomographic images, segmentation is performed by image processing and layer boundaries are automatically detected. This automatically detected layer boundary information is used to measure the layer thickness of a predetermined layer and to generate a two-dimensional front image of a predetermined layer from a three-dimensional tomographic image.

Segmentation of tomographic images of the eye to be examined may not yield good results, especially in diseased eyes, and Patent Document 1 discloses a manual correction method in which the examiner corrects automatic detection by segmentation. There is.

JP2008-73099

However, the operability when performing manual correction is not sufficient, and further improvement in operability is desired.

In view of the above problems, an object of the present invention is to provide an image processing device and an image processing program that can efficiently perform manual correction of the position of a layer boundary on a tomographic image.

The image processing device according to the first aspect of the disclosure of this specification includes :
a display control means for superimposing a tomographic image of the eye to be examined on the display means and a line indicating the first layer boundary on the tomographic image;
layer boundary line correction means for correcting a line indicating the first layer boundary;
an operation reception means for accepting operations from an operator;
An image processing device having:
The layer boundary line correction means,
an operation of setting a new editing point at a position different from the line indicating the first layer boundary using the operation receiving means in a state where the line indicating the first layer boundary is displayed superimposed on the tomographic image; a first layer boundary line correction mode that receives and generates a line indicating a second layer boundary passing through the new edit point and at least two reference points on the line indicating the first layer boundary;
The operation accepting means receives an operation for moving a first editing point among a plurality of editing points displayed at regular intervals on a line indicating the first layer boundary superimposed on the tomographic image, and moves the first editing point. A second layer boundary passing through the first editing point and a second editing point and a third editing point that are different from the first editing point among the plurality of editing points. a second layer boundary line correction mode that generates a line indicating the
This is an image processing device having:
Further, an image processing program according to another aspect of the disclosure of this specification includes :
displaying a tomographic image of the eye to be examined and a line indicating the first layer boundary on the display means, superimposed on the tomographic image;
An image processing program comprising: a layer boundary line correction step of correcting a line indicating the first layer boundary,
The layer boundary line correction step
accepting an operation for setting a new edit point at a position different from the line indicating the first layer boundary while the line indicating the first layer boundary is displayed superimposed on the tomographic image;
a first layer boundary line correction mode that generates a line indicating a second layer boundary passing through the new editing point and at least two reference points on the line indicating the first layer boundary;
Accepting an operation to move a first editing point among a plurality of editing points displayed at regular intervals on a line indicating the first layer boundary superimposed on the tomographic image, A line indicating a second layer boundary passing through the edit point and a second edit point and a third edit point that are different from the first edit point among the plurality of edit points is generated. a second layer boundary line correction mode;
This is an image processing program having a layer boundary line correction step.

According to the present invention, when the segmentation result of a tomographic image requires correction, it becomes possible to efficiently perform the correction and improve operability.

FIG. 1 is an overall configuration diagram of this embodiment. FIG. 3 is an explanatory diagram of the measurement optical system of the present example. This is an example of an OCTA report screen. FIG. 3 is a selection example of depth range definition for OCTA image generation. It is an example of depth range definition of OCTA image generation. This is an example of selecting a fundus front image. This is an example of selecting an image to be superimposed on the SLO image. This is an example of selecting the upper surface reference and the lower surface reference. This is an example of an enlarged display screen of an OCTA image. This is an example of an enlarged display screen of a fundus front image from an OCTA report. This is an example of an enlarged display screen of a tomographic image from an OCTA report. This is an example of a layer thickness map report screen. This is an example of a layer thickness map selection. This is an example of selecting a fundus front image. This is an example of an enlarged display screen of a layer thickness map. This is an example of an enlarged display screen of a fundus front image from a layer thickness map report. This is an example of an enlarged display screen of a tomographic image from a layer thickness map report. This is an example of a layer correction screen. This is an example of a screen for layer correction on an enlarged display screen of a tomographic image. This is an example of a screen when making corrections in the Correction mode. This is an example of a screen when making corrections in the Correction mode. This is an example of layer boundary correction in Correction mode. This is an example of a screen when making corrections in Drawing mode. This is an example of a screen when making corrections in Drawing mode. This is an example where there is an error in segmentation in Drawing mode. This is an example of layer boundary modification in Drawing mode. This is an example of layer boundary modification in Drawing mode. This is a display example of a tomographic image taken at a wide angle. This is an example of enlarging and displaying a tomographic image taken at a wide angle. This is an example of selecting an operation mode on an enlarged tomographic image display screen. This is an example of a report screen where the size can be changed for each display element. This is an example in which a line indicating a second layer boundary is generated based on an automatically set line indicating the first layer boundary and one editing point. This is an example in which a line indicating a second layer boundary is generated from a line indicating an automatically set first layer boundary and a plurality of editing points.

Hereinafter, exemplary embodiments for carrying out the present invention will be described in detail with reference to the accompanying drawings.

(Body configuration)
FIG. 1 is a side view of the optical coherence tomography apparatus in this embodiment.

100 is a measurement optical system for acquiring an anterior segment image, an SLO fundus image of the eye to be examined, and a tomographic image. Reference numeral 101 denotes a stage section that allows the measurement optical system 100 to move back and forth and left and right. Reference numeral 102 denotes a base portion that houses a spectrometer, which will be described later.

Reference numeral 103 is a control unit that controls the stage unit, alignment operation, and configures tomographic images, and is, for example, a personal computer. Reference numeral 104 denotes a storage unit that stores tomographic imaging programs, patient information, imaging data, statistical information of a normal database, and the like. Note that although the storage unit exists inside the control unit 103 in FIG. 1, the storage unit 104 may exist in a server or the like outside of the control unit 103.

Reference numeral 105 denotes an input unit for issuing instructions to the control unit 103, and specifically includes a keyboard and a mouse. 106 is a display unit such as a monitor.

In this embodiment, the image processing apparatus has a configuration including a control unit 103 having a storage unit inside and an input unit 105, but the storage unit 104 is external and the configuration of the control unit 103 and input unit 105 is or may include a display section 106. Further, although the input section 105 and the display section 106 are configured as separate bodies in FIG. 1, they may be configured as an integrated unit such as a touch panel. Furthermore, when the optical coherence tomography apparatus in this embodiment has a configuration in which the image acquisition section and the image processing section are integrated, it may have a configuration including 100 to 106.

(Configuration of measurement optical system and spectrometer)
The configuration of the measurement optical system and spectrometer of this example will be explained using FIG. 2.

First, the inside of the measurement optical system 100 will be explained. An objective lens 201 is placed facing the eye 200 to be examined, and a first dichroic mirror 202 and a second dichroic mirror 203 are placed on its optical axis. These dichroic mirrors provide wavelength bands in the optical path 250 of the OCT optical system, the optical path 251 for the SLO optical system and fixation lamp, which serves both the observation of the subject's eye and the acquisition of the SLO fundus image, and the optical path 252 for anterior eye observation. It is branched separately.

The optical path 251 for the SLO optical system and fixation lamp includes an SLO scanning means 204, lenses 205 and 206, a mirror 207, a third dichroic mirror 208, a photodiode 209, an SLO light source 210, and a fixation lamp 211.

The mirror 207 is a prism in which a perforated mirror or a hollow mirror is vapor-deposited, and separates the illumination light from the SLO light source 210 and the return light from the eye to be examined. The third dichroic mirror 208 separates each wavelength band into optical paths to the SLO light source 210 and the fixation lamp 211 .

The SLO scanning means 204 scans the eye 200 with light emitted from the SLO light source 210 and the fixation lamp 211, and is composed of an X scanner that scans in the X direction and a Y scanner that scans in the Y direction. There is. In this embodiment, since it is necessary to perform high-speed scanning, the X scanner is composed of a polygon mirror, and the Y scanner is composed of a galvanometer mirror.

The lens 205 is driven by a motor (not shown) for focusing the SLO optical system and fixation lamp. SLO light source 210 generates light at a wavelength around 780 nm. Photodiode 209 detects the return light from the eye to be examined. The fixation lamp 211 generates visible light to encourage the subject to fixate.

The light emitted from the SLO light source 210 is reflected by the third dichroic mirror 208, passes through the mirror 207, passes through the lenses 206 and 205, and is scanned on the eye 200 by the SLO scanning means 204. After the return light from the eye 200 to be examined returns along the same path as the projection light, it is reflected by the mirror 207 and guided to the photodiode 209, whereby an SLO fundus image is obtained.

The light emitted from the fixation lamp 211 passes through the third dichroic mirror 208 and the mirror 207, passes through the lenses 206 and 205, and is scanned on the eye 200 by the SLO scanning means 204. At this time, by blinking the fixation light 211 in accordance with the movement of the SLO scanning means, an arbitrary shape is created at an arbitrary position on the subject's eye 200, and the subject's fixation is encouraged.

Lenses 212 and 213, a split prism 214, and a CCD 215 for anterior eye observation that detects infrared light are arranged in the optical path 252 for anterior eye observation. This CCD 215 is sensitive to the wavelength of irradiation light for anterior eye observation (not shown), specifically around 970 nm. The split prism 214 is arranged at a position conjugate with the pupil of the eye to be examined 200, and can detect the distance of the measurement optical system 100 in the Z direction (front-back direction) with respect to the eye to be examined 200 as a split image of the anterior segment of the eye. can.

The optical path 250 of the OCT optical system constitutes the OCT optical system as described above, and is for capturing a tomographic image of the eye 200 to be examined. More specifically, the purpose is to obtain an interference signal for forming a tomographic image. 216 is an XY scanner for scanning light on the eye to be examined. Although the XY scanner 216 is illustrated as one mirror, it is a galvano mirror that scans in two XY axis directions.

217 and 218 are lenses, of which the lens 217 is driven by a motor (not shown) in order to focus the light from the OCT light source 220 emitted from the fiber 224 connected to the optical coupler 219 onto the eye 200 to be examined. Ru. By this focusing, the return light from the eye 200 to be examined is simultaneously formed into a spot image and incident on the tip of the fiber 224.

Next, the configuration of the optical path from the OCT light source 220, the reference optical system, and the spectrometer will be explained. 220 is an OCT light source, 221 is a reference mirror, 222 is a dispersion compensation glass, 223 is a lens, 219 is an optical coupler, 224 to 227 are single mode optical fibers connected to and integrated with the optical coupler, and 230 is a spectrometer. be.

These configurations constitute a Michelson interference system. The light emitted from the OCT light source 220 passes through the optical fiber 225 and is split via the optical coupler 219 into measurement light on the optical fiber 224 side and reference light on the optical fiber 226 side. The measurement light is irradiated onto the eye 200 to be observed, which is the object of observation, through the optical path of the OCT optical system described above, and reaches the optical coupler 219 through the same optical path due to reflection and scattering by the eye.

On the other hand, the reference light reaches the reference mirror 221 and is reflected through the optical fiber 226, the lens 223, and the dispersion compensating glass 222 inserted to match the dispersion of the measurement light and the reference light. Then, it returns along the same optical path and reaches the optical coupler 219.

The measurement light and the reference light are combined by the optical coupler 219 to become interference light. Here, interference occurs when the optical path length of the measurement light and the optical path length of the reference light become almost the same. The reference mirror 221 is held so as to be adjustable in the optical axis direction by a motor and a drive mechanism (not shown), and it is possible to match the optical path length of the reference light to the optical path length of the measurement light, which changes depending on the eye 200 to be examined. The interference light is guided to a spectrometer 230 via an optical fiber 227.

Further, 228 is a polarization adjustment section provided in the optical fiber 224 on the measurement light side. Reference numeral 229 denotes a polarization adjustment section on the reference light side provided in the optical fiber 226. These polarization adjustment units have several parts in which optical fibers are wound around in a loop. By rotating this loop-shaped portion around the longitudinal direction of the fiber, it is possible to twist the fiber and adjust the polarization states of the measurement light and the reference light to match each other.

The spectrometer 230 includes lenses 232 and 234, a diffraction grating 233, and a line sensor 231. The interference light emitted from the optical fiber 227 becomes parallel light through the lens 234 , is separated by the diffraction grating 233 , and is imaged onto the line sensor 231 by the lens 232 .

Next, the surroundings of the OCT light source 220 will be described. The OCT light source 220 is an SLD (Super Luminescent Diode), which is a typical low coherent light source. The center wavelength is 855 nm, and the wavelength bandwidth is approximately 100 nm. Here, the bandwidth is an important parameter because it affects the resolution of the obtained tomographic image in the optical axis direction.

As for the type of light source, SLD is selected here, but it is sufficient that it can emit low coherent light, and ASE (Amplified Spontaneous Emission) or the like may be used. Considering that the eye is to be measured, near-infrared light is suitable as the center wavelength. Furthermore, since the center wavelength affects the lateral resolution of the obtained tomographic image, it is desirable that the center wavelength be as short as possible. For both reasons, the center wavelength was set at 855 nm.

In this embodiment, a Michelson interference system is used as the interference system, but a Mach-Zehnder interference system may also be used. Depending on the difference in light intensity between the measurement light and the reference light, it is desirable to use a Mach-Zehnder interference system when the difference in light intensity is large, and to use a Michelson interference system when the difference in light intensity is relatively small.

With the above configuration, it is possible to obtain a tomographic image of the eye to be examined, and also to obtain an SLO fundus image of the eye to be examined with high contrast even with near-infrared light.

(Method of capturing tomographic images)
A method for capturing tomographic images using an optical coherence tomography apparatus will be described.

The optical coherence tomography apparatus can capture a tomographic image of a predetermined portion of the eye 200 by controlling the XY scanner 216. Here, the locus of scanning the tomographic image acquisition light in the subject's eye is called a scan pattern. This scan pattern includes, for example, a cross scan that scans vertically and horizontally with one point as the center, and a 3D scan that scans to fill the entire area and obtains a three-dimensional tomographic image as a result. Cross scanning is suitable when you want to make detailed observations of a specific region, and 3D scanning is suitable when you want to observe the layer structure and layer thickness of the entire retina.

Here, an imaging method when performing a 3D scan will be described. First, measurement light is scanned in the X direction in the figure, and the line sensor 231 captures information on a predetermined number of images from the imaging range in the X direction of the eye to be examined. The brightness distribution on the line sensor 231 obtained at a certain position in the X direction is subjected to Fast Fourier Transform (FFT), and the linear brightness distribution obtained by FFT is converted into density information to be displayed on the monitor 106. . This is called an A-scan image.

A two-dimensional image in which the plurality of A-scan images are arranged is called a B-scan image. After capturing a plurality of A-scan images to form one B-scan image, the scanning position in the Y direction is moved and scanning in the X direction is performed again to obtain a plurality of B-scan images.

By displaying a plurality of B-scan images or a three-dimensional tomographic image constructed from a plurality of B-scan images on the monitor 106, the examiner can diagnose the eye to be examined. Here, an example has been shown in which a three-dimensional tomographic image is obtained by obtaining a plurality of B-scan images in the X direction, but a three-dimensional tomographic image may be obtained by obtaining a plurality of B-scan images in the Y direction.

(segmentation)
The human retina consists of the vitreous body, internal limiting membrane (ILM), nerve fiber layer (NFL), ganglion cell layer (GCL), inner plexiform layer (IPL), inner nuclear layer (INL), and outer plexiform layer (OPL). It has a layered structure such as the outer nuclear layer (ONL), the inner-outer segment junction of the photoreceptor layer (IS/OS), the retinal pigment epithelium (RPE), the choroid, and Bruch's membrane (BM).

By detecting the layer structure of the retina through image processing from a tomographic image obtained using an optical coherence tomography device, it is possible to segment the layer structure of the retina and automatically detect layer boundaries. Segmentation can be performed using various known methods, so detailed explanation will be omitted.

(Method for generating fundus front image)
An EnFace image, which is a two-dimensional image, can be generated from a three-dimensional tomographic image, based on two arbitrary planes in the depth direction (Z direction), and information in the range between them is projected onto the XY plane. Since the EnFace image can be generated using various known methods, detailed explanation will be omitted. Since the EnFace image is generated by setting two arbitrary planes in the depth direction, it is possible to structurally visualize a predetermined layer.

A projection image can be generated by integrating the entire three-dimensional tomographic image in the depth direction (Z direction). Since the Projection image can be generated using various known methods, detailed explanation will be omitted. Projection images can structurally visualize the entire retinal layer.

When a two-dimensional image is generated from a three-dimensional tomographic image in an arbitrary plane perpendicular to the depth direction (Z direction), a C-Scan image can be generated. C-Scan images can be generated using various known methods, so detailed explanations will be omitted.

(How to generate an OCTA image)
A moving position is detected from a plurality of three-dimensional tomographic images obtained by scanning the same part of the eye to be examined multiple times at predetermined time intervals, and three-dimensional motion contrast data (aniogram) is generated. An OCTA image can be generated by projecting this three-dimensional motion contrast data on two arbitrary planes in the depth direction (Z direction) and projecting the motion contrast data in the range between them onto the XY plane. Since OCTA images can be generated using various known methods, detailed explanations will be omitted.

(Projection artifact reduction processing)
When an OCTA image is generated, there are projection artifacts such as shadows of blood vessels in the upper layer being depicted in the lower layer. Therefore, in OCTA image generation, it is desirable to have a configuration that can reduce projection artifacts. Since the projection artifact reduction process can be performed using various known methods, detailed explanation will be omitted.

(OCTA report screen)
A display example of the OCTA report screen will be explained with reference to FIG.

The OCTA report screen 1000 displays information 1001 about the left and right eyes of the subject's eye, imaging date and time 1002, imaging conditions 1003, and the like.

At 1010, an SLO fundus image is displayed.

At 1020, a fundus front image generated from the three-dimensional tomographic image is displayed.

OCTA images are displayed at 1030 and 1040.

At 1050 and 1060, tomographic images are displayed.

In this embodiment, the OCTA image displayed at 1030 is set as OCTA Image 1, and the OCTA image displayed at 1040 is set as OCTA Image 2, and OCTA images generated in different depth ranges are displayed vertically side by side for comparison. It is also possible to set the same depth range for OCTA Image1 and OCTA Image2.

The tomographic image 1050 displays depth range information corresponding to OCTA Image1, and the tomographic image 1060 displays depth range information corresponding to OCTA Image2.

At 1031 and 1041, a depth range for generating an OCTA image can be selected from a plurality of depth range definitions, as shown in FIG. The depth range definitions that can be selected here include, for example, as shown in FIG. 5, the top and bottom surfaces in the depth direction (Z direction) for generating an OCTA image are set for each depth range definition. The depth range definition shown in FIG. 5 is an example, and it is also possible to add a depth range definition not shown in FIG. 5 as a depth range definition. Further, the upper surface reference and lower surface reference illustrated as depth range definitions are not limited to these, and can be changed. Although specific numerical values are not shown for the upper surface relative distance and the lower surface relative distance, they can be set arbitrarily.

Layer boundaries automatically detected by segmentation can be set as the top surface reference and the bottom surface reference. For the upper surface relative distance and the lower surface relative distance, relative distances in the depth direction (Z direction) from the upper surface reference and the lower surface reference can be set as positive or negative values, respectively.

The upper surface of the depth range in which an OCTA image is generated is a surface separated by a relative distance from the upper surface reference in the depth direction (Z direction). Similarly, the lower surface of the depth range for generating an OCTA image is a surface that is separated by a lower surface relative distance in the depth direction (Z direction) from the lower surface reference.

For the upper surface reference and the lower surface reference, not only the layer boundary automatically detected by segmentation but also a surface perpendicular to the depth direction (Z direction) can be set, for example, by setting Line. In this case, the upper surface relative distance and the lower surface relative distance can be set using the upper end or lower end of the three-dimensional tomographic image in the depth direction (Z direction) as a reference.

The OCTA image generated with the depth range definition selected at 1031 is displayed at 1030 as OCTA Image1. Further, the depth range definition information selected in 1031 is displayed in the depth range information of OCTA Image 1 in 1051, 1052, 1053, and 1054. 1051, 1052, 1053, and 1054 display the top reference, top relative distance, bottom reference, and bottom relative distance of the depth range definition selected in 1031, respectively.

The depth range definition information selected in 1031 is also superimposed and displayed on the tomographic image 1050. Reference numeral 1055 indicates a surface that is away from the top surface relative distance from the top surface reference of the depth range selected in 1031, that is, the top surface of the depth range in which the OCTA image is to be generated. Reference numeral 1056 indicates a surface that is a lower surface relative distance away from the lower surface reference of the depth range selected in 1031, that is, the lower surface of the depth range in which the OCTA image is to be generated.

The OCTA image generated with the depth range definition selected at 1041 is displayed at 1040 as OCTA Image2. Further, the information on the depth range definition selected at 1041 is displayed in the depth range information of OCTA Image 2 at 1061, 1062, 1063, and 1064. 1061, 1062, 1063, and 1064 display the top reference, top relative distance, bottom reference, and bottom relative distance of the depth range definition selected in 1041, respectively.

The depth range definition information selected at 1041 is also superimposed and displayed on the tomographic image at 1060. Reference numeral 1065 indicates a surface that is separated by a relative upper surface distance from the upper surface reference of the depth range selected in 1041, that is, the upper surface of the depth range in which the OCTA image is to be generated. Reference numeral 1066 indicates a surface that is a lower surface relative distance away from the lower surface reference of the depth range selected in 1041, that is, the lower surface of the depth range in which the OCTA image is to be generated.

An EnFace image generated in the same depth range as the depth range definition selected in 1031 as EnFace Image1, an EnFace image generated in the same depth range as the depth range definition selected in 1041 as EnFace Image2, and a fundus front image displayed in 1020. can be selected from EnFace Image1, En FaceImage2, and Projection Image, as shown in FIG.

When EnFace Image1 is selected, an EnFace image generated from the three-dimensional tomographic image is displayed at 1020 with the same depth range as the depth range definition of OCTA Image1 selected at 1031.

When EnFace Image2 is selected, an EnFace image generated from the three-dimensional tomographic image is displayed at 1020 with the same depth range as the depth range definition of OCTA Image2 selected at 1041.

When Projection Image is selected, a projection image generated by integrating the entire three-dimensional tomographic image in the depth direction (Z direction) is displayed at 1020.

In displaying the SLO fundus image at 1010, the image 1012 to be superimposed and displayed on the SLO fundus image can be selected from OCTA Image1, OCTA Image2, EnFace Image1, EnFace Image2, and Projection Image at 1011, as shown in FIG. For example, when OCTA Image1 is selected, the OCTA image of OCTA Image1 is superimposed and displayed at 1012 on the SLO fundus image 1010. Note that when SLO Image is selected, only the SLO fundus image is displayed at 1010, and the superimposed image at 1012 is not displayed.

At 1031, 1041, changing the depth range definition selection updates all corresponding displays. For example, when the depth range definition selection of 1031 is changed, the depth range information of OCTA Image 1 of 1051, 1052, 1053, and 1054 is updated. 1055 and 1056 indicating the upper and lower surfaces of the depth range for generating the OCTA image superimposed on the tomographic image 1050 are also updated. An OCTA image is generated with the selected depth range definition, and the OCTA image displayed at 1030 is also updated. When EnFace Image 1 is displayed in the fundus front image 1020, the EnFace image is generated in the same depth range as the selected depth range definition, and the display in 1020 is also updated. If OCTA Image1 or EnFace Image1 is displayed in 1012 superimposed on the SLO fundus image, the display in 1012 is also updated.

Information indicating the depth range of OCTA Image 1 is displayed. At 1051, 1052, 1053, and 1054, it is also possible to individually change the depth range definition settings selected at 1031 and set an arbitrary depth range. .

The upper surface reference 1051 and the lower surface reference 1053 can be selected from layer boundaries automatically detected by segmentation, as shown in FIG. Furthermore, it is also possible to select a Line that specifies a plane perpendicular to the depth direction (Z direction) instead of the automatically detected layer boundary.

The upper surface relative distance 1052 and the lower surface relative distance 1054 can be set to arbitrary positive or negative values.

If at least one of 1051, 1052, 1053, and 1054 is changed and there is a change from the depth range information selected in 1031, to indicate that it is different from the depth range definition selected in 1031, for example, 1031 is not the name of the depth range definition shown in FIG. 5, but a different name, for example, Custom.

Even when 1051, 1052, 1053, and 1054 are changed individually, 1055 and 1056, which indicate the upper and lower surfaces of the depth range for generating the OCTA image superimposed on the tomographic image 1050, are updated. Further, the corresponding OCTA Image1 and EnFace Image1 are generated with the changed depth range, and all the corresponding displays are updated.

By moving 1055 and 1056, which are displayed superimposed on the tomographic image 1050 and indicate the top and bottom surfaces of the depth range for generating an OCTA image, using the mouse, you can change the relative distance of the top surface to the selected top surface reference, and the bottom surface reference. It is also possible to change the relative distance to the lower surface.

Even when these are changed individually, all the corresponding displays are updated in the same way as when changing the depth range definition selection.

The same applies to 1061, 1062, 1063, 1064, 1065, and 1066 where information indicating the depth range of OCTA Image 2 is displayed, so the explanation will be omitted.

1057 and 1067 indicate which B-scan of all the B-scans of the three-dimensional tomographic image is displayed by the tomographic images 1050 and 1060, respectively, and the corresponding B-scan position is indicated. , an OCTA image, and a fundus front image.

The B-scan position corresponding to the B-scan displayed at 1057 can be displayed as an arrow at 1032 at 1030 where the OCTA image of OCTA Image 1 is displayed.

The B-scan position corresponding to the B-scan displayed at 1067 can be displayed as an arrow at 1042 at 1040 where the OCTA image of OCTA Image 2 is displayed.

In the fundus front image 1020, when EnFace Image 1 is selected at 1021, the B-scan position corresponding to the B-scan displayed at 1057 can be displayed as an arrow at 1022. Similarly, when EnFace Image 2 is selected at 1021, the B-scan position corresponding to the B-scan displayed at 1067 can be displayed as an arrow at 1022.

In 1012 superimposed on the SLO fundus image 1010, when OCTA Image 1 or EnFace Image 1 is selected in 1011, the B-scan position corresponding to the B-scan displayed in 1057 is displayed as an arrow in 1013. can. Similarly, when OCTA Image 2 or EnFace Image 2 is selected at 1011, the B-scan position corresponding to the B-scan displayed at 1067 can be displayed as an arrow at 1013.

The display of the arrow indicating the B-scan position can be switched on or off by checking or unchecking the Show Lines checkbox 1004. Switching the display on and off is not limited to this method, and may also be switched using the context menu of right-clicking the mouse. The display may be configured to be always displayed without switching the display on or off.

The B scan displayed on the tomographic images 1050 and 1060 can be changed by operating the mouse wheel on the tomographic images 1050 and 1060, respectively. In addition, by moving the arrow indicating the B-scan position on the image 1012 superimposed on the OCTA images 1030, 1040, the fundus front image 1020, and the SLO fundus image 1010 by operating the mouse, you can obtain a tomographic image corresponding to the displayed image. You can also change the B-scan displayed on the screen. Note that when changing the B-scan position displayed on the tomographic image, the corresponding display is updated in conjunction.

For example, when EnFace Image 1 is displayed on the fundus front image 1020, if you move the arrow indicating the B scan position displayed on the fundus front image 1020 with a mouse operation, the B scan position displayed on the OCTA image 1030 will be moved. An arrow 1032 indicating the arrow 1032 also moves in conjunction. At the same time, the tomographic image displayed in tomographic image 1050 is updated to the corresponding B-scan, and the display of the B-scan position in 1057 is also updated. Note that when OCTA Image 1 or EnFace Image 1 is displayed at 1012 superimposed on the SLO fundus image, the arrow at 1012 also moves in conjunction.

Although an example has been described in which the B scans displayed in the tomographic images 1050 and 1060 are changed respectively, they may be changed synchronously.

Although not shown in the tomographic images 1050 and 1060, three-dimensional motion contrast data (aniogram) can be displayed superimposed on the tomographic images in any color and with any transparency.

The angiogram display can be turned on or off, for example, using a right-click context menu of the mouse. The method of selecting the angiogram display is not limited to this, and for example, the selection may be made by checking or unchecking a check box (not shown).

The selection of the angiogram display may be set individually for the tomographic images 1050 and 1060, or may be set synchronously.

Although not shown, projection artifact reduction processing can also be applied to the OCTA images 1030 and 1040 and the tomographic images 1050 and 1060.

Turning the projection artifact reduction process on or off can be selected, for example, from a context menu when right-clicking the mouse. The selection method for the projection artifact reduction process is not limited to this, and for example, the selection may be made by checking or unchecking a check box (not shown).

The selection state of the projection artifact reduction process is synchronized between the OCTA image 1030 and the tomographic image 1050, and is synchronized between the OCTA image 1040 and the tomographic image 1060.

For example, when projection artifact reduction processing is turned on for the OCTA image 1030, the projection artifact reduction processing is applied to the OCTA image 1030 and the tomographic image 1050, and the image display is updated.

Information indicating whether the projection artifact reduction process is on or off may be displayed superimposed on the tomographic image, for example.

Noise reduction processing using machine learning can also be applied to the OCTA images 1030 and 1040. For example, when a button (not shown) is operated to turn on noise reduction processing using machine learning, the noise reduction processing using machine learning is applied to the OCTA image, and the display of the OCTA image is updated.

Noise reduction processing using machine learning may be applied to the OCTA images 1030 and 1040 synchronously or may be applied individually.

In the OCTA images 1030 and 1040, the brightness and contrast of the OCTA images can be changed by operating the mouse. For example, when the mouse is clicked on an OCTA image, the brightness can be changed when the mouse is moved up and down, and the contrast can be changed when the mouse is moved left and right.

Similarly to the OCTA images 1030 and 1040, the brightness and contrast of the tomographic images 1050 and 1060 and the fundus front image 1020 can be changed by operating the mouse.

Measurement results such as the distance between two points and the area of a region can be displayed in a superimposed manner on the OCTA images 1030 and 1040. Turning the measurement result display on or off can be selected from the right-click context menu for each of the OCTA images 1030 and 1040. The selection method for displaying measurement results is not limited to this, and for example, selection may be made by checking or unchecking check boxes (not shown).

Similarly to the OCTA images 1030 and 1040, the tomographic images 1050 and 1060 and the frontal fundus image 1020 can display measurement results such as the distance between two points and the area of a region in a superimposed manner.

Although the measurement result display can be individually turned on or off, the present invention is not limited to this. The display of the measurement results may be fixed to ON or OFF only for a predetermined image. Furthermore, the on/off state of the measurement result display may be synchronized between predetermined images.

The display method of the tomographic images to be displayed on the tomographic images 1050 and 1060 can be selected.

For example, display according to the display area or display at the actual aspect ratio can be selected from the context menu when right-clicking the mouse.

When printing or outputting an OCTA report by pressing a print button or an output button (not shown) from the OCTA report screen 1000, an angiogram display, projection artifact reduction processing, noise reduction processing using machine learning, and B scan position are displayed. The displayed arrows, brightness, contrast, measurement result display, etc., are printed and output in the state they were in when the button was pressed.

Although not shown, C-Scan Image 1 and C-Scan Image 2 can be selected in 1011 and 1021, and a 2-dimensional image is generated from a 3-dimensional tomographic image on an arbitrary plane perpendicular to the depth direction (Z direction). It may also be possible to display C-Scan images.

When C-Scan Image 1 is selected, the position in the depth direction (Z direction) at which the C-Scan image is generated is displayed on the tomographic image 1050, and when C-Scan Image 2 is selected, the C-Scan image is displayed. The generated position in the depth direction (Z direction) is displayed on the tomographic image 1060.

By moving the position in the depth direction (Z direction) where the C-Scan image is generated using a mouse operation, a C-Scan image generated on an arbitrary plane can also be displayed.

When a C-Scan image is displayed at 1020, the position in the depth direction (Z direction) at which the C-Scan image is generated may be changed by operating the mouse wheel.

A C-Scan image is generated and the display of the C-Scan image is updated in accordance with a change in the depth direction (Z direction) position at which the C-Scan image is generated.

(Enlarged display of OCTA image from OCTA report screen)
When an OCTA image is double-clicked on the OCTA report screen 1000, the screen changes to an enlarged OCTA image display screen 2000 shown in FIG.

On the enlarged OCTA image display screen 2000, an OCTA image is displayed at 2010, and a tomographic image is displayed at 2020.

On the enlarged OCTA image display screen 2000, information on the depth range of the OCTA image double-clicked on the OCTA report screen 1000 is displayed in 2021, 2022, 2023, 2024, and 2025, and the OCTA image generated in that depth range is displayed in 2010. Is displayed. Further, the upper and lower surfaces of the depth range are displayed superimposed on the tomographic image 2020.

An example will be explained in which the OCTA image 1030 of OCTA Image 1 is double-clicked on the OCTA report screen 1000 and the screen changes.

In 2021, the depth range definition selected in 1031 is displayed at the time of screen transition.

In 2022, the top reference selected in 1051 is displayed at the time of screen transition.

In 2023, the top surface relative distance selected in 1052 at the time of screen transition is displayed.

In 2024, the bottom reference selected in 1053 is displayed at the time of screen transition.

In 2025, the lower surface relative distance selected in 1054 at the time of screen transition is displayed.

The upper surface of the depth range for generating an OCTA image, which is displayed in 2022 and 2023, is displayed superimposed on the tomographic image 2020 as 2026.

The lower surface of the depth range for generating an OCTA image, which is displayed at 2024 and 2025, is displayed superimposed on the tomographic image 2020 as 2027.

2021, 2022, 2023, 2024, and 2025 are selectable like the OCTA report screen 1000.

Similar to the OCTA report screen 1000, 2021 allows selection of a depth range definition for generating an OCTA image, as shown in FIG. At 2021, changing the selection of depth range definitions for generating OCTA images updates all corresponding displays. When the depth range definition selection in 2021 is changed, the depth range information for generating OCTA images 2022, 2023, 2024, and 2025 is updated. 2026 and 2027 indicating the upper and lower surfaces of the depth range for generating the OCTA image superimposed on the tomographic image 2020 are also updated. An OCTA image is generated with the selected depth range definition, and the OCTA image displayed in 2010 is also updated.

In 2022, 2023, 2024, and 2025, where information indicating the depth range for generating an OCTA image is displayed, you can individually change the depth range definition settings selected in 2021 to set an arbitrary depth range. You can also do that. In addition, by moving 2026 and 2027, which are displayed superimposed on the tomographic image 2020 and indicate the upper and lower surfaces of the depth range for generating an OCTA image, with a mouse operation, the relative distance of the upper surface with respect to the selected upper surface reference, It is also possible to change the relative distance of the lower surface to the lower surface reference. Since it is the same as the OCTA report screen 1000, detailed explanation will be omitted.

If you change the information indicating the depth range for generating an OCTA image on the OCTA image enlargement display screen 2000, when you return to the OCTA report screen 1000, the information on that depth range will change to the depth for generating the OCTA image on the OCTA report screen 1000. Applies to range information.

2028 indicates which B-scan of all the B-scans of the 3D tomographic image is displayed in the tomographic image displayed in 2020, and corresponds to the OCTA image double-clicked on the OCTA report screen 1000. Displays the B-scan position displayed on the tomographic image. For example, when the OCTA image 1030 of OCTA Image 1 is double-clicked on the OCTA report screen 1000 to change the screen, the B-scan position displayed at 1057 is displayed.

The corresponding B-scan position is displayed in the OCTA image 2010 as an arrow 2011. The display of the arrow indicating the B-scan position can be switched on or off by checking or unchecking the Show Lines checkbox 2001. Switching the display on and off is the same as in the OCTA report screen 1000, so a detailed explanation will be omitted.

The B scan displayed on the tomographic image 2020 can be changed by operating the mouse wheel on the tomographic image 2020, similarly to the OCTA report screen 1000. Furthermore, the B-scan displayed on the tomographic image 2020 can be changed by moving the arrow 2011 indicating the B-scan position in the OCTA image 2010 with a mouse operation. Note that when changing the B-scan displayed on the tomographic image, the corresponding display is updated in conjunction.

If you change the B-scan displayed in the tomographic image 2020 on the OCTA image enlargement display screen 2000, when you return to the OCTA report screen 1000, the B-scan position will correspond to the OCTA image that was double-clicked on the OCTA report screen 1000. applied to tomographic images. All corresponding displays are also updated.

Although not shown in the tomographic image 2020, similarly to the OCTA report screen 1000, three-dimensional motion contrast data (aniogram) can be displayed superimposed on the tomographic image in any color and with any transparency. The method for selecting the angiogram display is the same as that for the OCTA report screen 1000, so a detailed explanation will be omitted.

The selection state of on/off of the angiogram display is inherited from the selection state at the time of screen transition on the OCTA report screen 1000 and the enlarged OCTA image display screen 2000.

When the OCTA image enlarged display screen 2000 is displayed, the selected state of the angiogram display of the tomographic image corresponding to the OCTA image double-clicked on the OCTA report screen 1000 is applied to the angiogram display of the tomographic image 2020. For example, in the OCTA report screen 1000, when the angiogram display of the tomographic image 1050 is turned on and the OCTA image 1030 is double-clicked to transition to the enlarged OCTA image display screen 2000, the tomographic image 1050 is displayed in the tomographic image 2020. The selected state is inherited and the angiogram display is turned on.

If you change the selection state of the angiogram display of the tomographic image 2020 on the OCTA image enlargement display screen 2000, when you return to the OCTA report screen 1000, the selection state corresponds to the OCTA image that was double-clicked on the OCTA report screen 1000. applied to tomographic images. Note that when the angiogram display is synchronized between the tomographic images 1050 and 1060 on the OCTA report screen 1000, this is also applied to the tomographic images to be synchronized.

Similar to the OCTA report screen 1000, projection artifact reduction processing can also be applied to the OCTA image 2010 and the tomographic image 2020.

The selection, display, and synchronization of the projection artifact reduction process are the same as in the OCTA report screen 1000, so detailed explanations will be omitted.

The on/off selection state of the projection artifact reduction process is inherited from the selection state at the time of screen transition on the OCTA report screen 1000 and the enlarged OCTA image display screen 2000.

When transitioning to the enlarged OCTA image display screen 2000, the selected state of the projection artifact reduction process for the OCTA image double-clicked on the OCTA report screen 1000 is applied to the projection artifact reduction process for the OCTA image 2010 and tomographic image 2020. For example, on the OCTA report screen 1000, when the projection artifact reduction process for the OCTA image 1030 is turned on and the OCTA image 1030 is double-clicked to transition to the enlarged OCTA image display screen 2000, the OCTA image 2010, the tomographic image 2020 In this case, the selection state in the OCTA image 1030 is inherited, and the projection artifact reduction process is turned on.

If you change the selection state of projection artifact reduction processing for the OCTA image 2010 or tomographic image 2020 on the OCTA image enlargement display screen 2000, when you return to the OCTA report screen 1000, the selection state will be changed by double-clicking on the OCTA report screen 1000. It is applied to the OCTA image and the corresponding tomographic image.

Noise reduction processing using machine learning can also be applied to the OCTA image 2010. The selection and display of noise reduction processing using machine learning is the same as in the OCTA report screen 1000, so detailed explanation will be omitted.

The selection state of whether noise reduction processing using machine learning is turned on or off is inherited from the selection state at the time of screen transition on the OCTA report screen 1000 and the enlarged OCTA image display screen 2000.

When transitioning to the enlarged OCTA image display screen 2000, the selected state of noise reduction processing using machine learning for the OCTA image double-clicked on the OCTA report screen 1000 is applied to the noise reduction processing using machine learning for the OCTA image 2010. be done. For example, on the OCTA report screen 1000, when noise reduction processing using machine learning for the OCTA image 1030 is turned on, when the OCTA image 1030 is double-clicked to transition to the OCTA enlarged display screen 2000, the OCTA image 2010: The selection state in the OCTA image 1030 is inherited, and noise reduction processing using machine learning is turned on.

If you change the selection state of noise reduction processing using machine learning for OCTA images on the OCTA image enlargement display screen 2000, when you return to the OCTA report screen 1000, the selection state will be changed by double-clicking on the OCTA report screen 1000. applied to OCTA images. Note that when noise reduction processing using machine learning is synchronized on the OCTA images 1030 and 1040 on the OCTA report screen 1000, it is also applied to the OCTA images to be synchronized.

In the OCTA image 2010, the brightness and contrast of the OCTA image can be changed. The method for changing the brightness and contrast is the same as in the OCTA report screen 1000, so a detailed explanation will be omitted.

For the brightness and contrast of the OCTA image, the values at the time of screen transition are carried over between the OCTA report screen 1000 and the OCTA image enlarged display screen 2000. When transitioning to the OCTA image enlarged display screen 2000, the brightness and contrast values of the OCTA image double-clicked on the OCTA report screen 1000 are applied to the OCTA image 2010.

If the brightness and contrast of the OCTA image are changed on the OCTA image enlargement display screen 2000, when returning to the OCTA report screen 1000, those values are applied to the OCTA image that was double-clicked on the OCTA report screen 1000.

In the tomographic image 2020, the brightness and contrast of the tomographic image can be changed. The method for changing the brightness and contrast is the same as in the OCTA report screen 1000, so a detailed explanation will be omitted.

As for the brightness and contrast values of the tomographic image, the values at the time of screen transition are carried over between the OCTA report screen 1000 and the OCTA image enlarged display screen 2000. When transitioning to the OCTA image enlarged display screen 2000, the brightness and contrast values of the tomographic image corresponding to the OCTA image double-clicked on the OCTA report screen 1000 are applied to the tomographic image 2020. For example, when 1030 of OCTA Image 1 is double-clicked, the brightness and contrast values of the tomographic image 1050 are applied.

If you change the brightness or contrast of a tomographic image on the OCTA image enlargement display screen 2000, when you return to the OCTA report screen 1000, the values will change to the tomographic image corresponding to the OCTA image that was double-clicked on the OCTA report screen 1000. Applicable.

Measurement results such as the distance between two points and the area of a region can be displayed in a superimposed manner on the OCTA image 2010. Regarding the measurement result display, since it is the same as the OCTA report screen 1000, detailed explanation will be omitted.

As with other settings, a configuration in which the settings of the OCTA report screen 1000 are inherited is also possible, but an example in which the settings are not inherited will be described here.

The setting of the OCTA report screen 1000 is not inherited and the measurement result display for the OCTA image is turned on or off by default.

The ON/OFF status of displaying measurement results for OCTA images set on the OCTA image enlarged display screen 2000 is not carried over to the OCTA report screen 1000, and the setting before transition to the OCTA image enlarged display screen 2000 is maintained.

The tomographic image 2020 can display measurement results such as the distance between two points and the area of a region in a superimposed manner. Regarding the measurement result display, since it is the same as the OCTA report screen 1000, detailed explanation will be omitted.

As with other settings, a configuration in which the settings can be changed is also possible, but here an example will be described in which the settings cannot be changed.

The ON/OFF setting of the measurement result display for the tomographic image 2030 does not take over the setting of the OCTA report screen 1000, but is fixed to ON, and the setting cannot be changed.

An EnFace image can also be displayed superimposed on the OCTA image 2010.

When displaying the EnFace image in a superimposed manner, the transparency of the EnFace image can be changed by operating the mouse wheel, for example. The transparency of the EnFace image is not limited to this, and may be changed by button operation, slider operation, etc. (not shown).

When the transparency is set to 100%, only the OCTA image is displayed, and when it is set to 0%, only the EnFace image is displayed.

Regarding the superimposed display of the EnFace image, it is applied only to the display of the OCTA image on the enlarged display screen. Even if you return to the OCTA report screen, it will not be applied to the OCTA image on the OCTA report screen.

When printing or outputting from the enlarged OCTA image display screen 2000 by pressing a print button or an output button (not shown), the angiogram display, projection artifact reduction processing, noise reduction processing using machine learning, and B scan position are displayed. The displayed arrows, brightness, contrast, measurement result display, superimposed display of the EnFace image, etc., are printed and output in the state when the button is pressed.

When the Close button 2030 is pressed, the screen returns to the OCTA report screen.

(Enlarged display of fundus front image from OCTA report screen)
When the EnFace image is displayed in the fundus front image 1020 on the OCTA report screen 1000, if the fundus front image 1020 is double-clicked, the screen changes to an enlarged fundus front image display screen 3000 shown in FIG.

On the enlarged fundus front image display screen 3000, a fundus front image is displayed at 3010, and a tomographic image is displayed at 3020.

On the enlarged fundus front image display screen 3000, information on the depth range of the EnFace image double-clicked on the OCTA report screen 1000 is displayed in 3021, 3022, 3023, 3024, and 3024, and the EnFace image generated in that depth range is displayed in 3010. will be displayed. Further, the upper and lower surfaces of the depth range are displayed superimposed on the tomographic image 3020.

An example will be described in which when EnFace Image1 is displayed on the fundus front image 1020 of the OCTA report screen 1000, the screen changes by double-clicking the fundus front image 1020.

At 3021, the depth range definition selected at 1031 is displayed at the time of screen transition.

At 3022, the top reference selected at 1051 is displayed at the time of screen transition.

In 3023, the top surface relative distance selected in 1052 at the time of screen transition is displayed.

At 3024, the bottom reference selected at 1053 is displayed at the time of screen transition.

In 3025, the lower surface relative distance selected in 1054 at the time of screen transition is displayed.

The upper surface of the depth range for generating the EnFace image, which is displayed at 3022, 3023, 3024, and 3025, is superimposed and displayed at 3026 on the tomographic image 3020. The lower surface of the depth range for generating the EnFace image is superimposed and displayed as 3027 on the tomographic image 3020.

3021, 3022, 3023, 3024, and 3025 are selectable like the OCTA report screen 1000.

Similar to the OCTA report screen 1000, 3021 allows selection of a depth range definition for generating an EnFace image, as shown in FIG. At 3021, changing the selection of depth range definitions for generating EnFace images updates all corresponding displays. When the depth range definition selection 3021 is changed, the depth range information of the EnFace images 3022, 3023, 3024, and 3025 is updated. 3026 and 3027 indicating the upper and lower surfaces of the depth range for generating the EnFace image superimposed on the tomographic image 3020 are also updated. An EnFace image is generated with the selected depth range definition, and the EnFace image displayed at 3010 is also updated.

In 3022, 3023, 3024, and 3025, where information indicating the depth range for generating the EnFace image is displayed, you can individually change the depth range definition settings selected in 3021 to set an arbitrary depth range. You can also do that. In addition, by moving 3026 and 3027, which are superimposed on the tomographic image 3020 and indicate the upper and lower surfaces of the depth range for generating the EnFace image, by operating the mouse, the relative distance of the upper surface with respect to the selected upper surface reference, It is also possible to change the relative distance of the lower surface to the lower surface reference. Since it is the same as the OCTA report screen 1000, detailed explanation will be omitted.

When the information indicating the depth range for generating the EnFace image is updated on the EnFace image enlargement display screen 3000, when returning to the OCTA report screen 1000, the information on the depth range is changed to the depth for generating the OCTA image on the OCTA report screen 1000. Applies to range information.

3028 indicates which B-scan of all the B-scans of the 3D tomographic image is displayed in the tomographic image displayed in 3020, and corresponds to the EnFace image double-clicked on the OCTA report screen 1000. Displays the B-scan position displayed on the tomographic image. For example, if EnFace Image 1 is displayed on the fundus front image 1020 on the OCTA report screen 1000, and the screen changes by double-clicking the fundus front image 1020, the B scan position displayed on the tomographic image 1057 will not be displayed. Ru.

The corresponding B-scan position is displayed as an arrow 3011 in the EnFace image 3010. The display of the arrow indicating the B-scan position can be switched on or off by checking or unchecking the Show Lines checkbox 3001. Switching the display on and off is the same as in the OCTA report screen 1000, so a detailed explanation will be omitted.

The B scan displayed on the tomographic image 3020 can be changed by operating the mouse wheel on the tomographic image 3020, similarly to the OCTA report screen 1000. Furthermore, the B-scan displayed on the tomographic image 3020 can be changed by moving the arrow 3011 indicating the B-scan position in the frontal fundus image 3010 using a mouse. Note that when changing the B-scan displayed on the tomographic image, the corresponding display is updated in conjunction.

If you change the B-scan displayed on the tomographic image 3020 on the EnFace image enlargement display screen 3000, when you return to the OCTA report screen 1000, the B-scan position will correspond to the EnFace image that was double-clicked on the OCTA report screen 1000. applied to tomographic images. All corresponding displays are also updated.

Although not shown in the tomographic image 3020, similarly to the OCTA report screen 1000, three-dimensional motion contrast data (aniogram) can be displayed superimposed on the tomographic image in any color and with any transparency. The method for selecting the angiogram display is the same as that for the OCTA report screen 1000, so a detailed explanation will be omitted.

The selection state of on/off of the angiogram display is inherited from the selection state at the time of screen transition on the OCTA report screen 1000 and the enlarged fundus front image display screen 3000.

When the enlarged fundus front image display screen 3000 is displayed, the selected state of the angiogram display of the tomographic image corresponding to the EnFace image double-clicked on the OCTA report screen 1000 is applied to the angiogram display of the tomographic image 3020. For example, on the OCTA report screen 1000, with the angiogram display of the tomographic image 1050 turned on and EnFace Image 1 displayed on the fundus front image 1020, double-click the fundus front image 1020 to transition to the enlarged fundus front image display screen 3000. At this time, the selection state in the tomographic image 1050 is inherited in the tomographic image 3020, and the angiogram display is turned on.

If you change the selection state of the angiogram display of the tomographic image 3020 on the fundus frontal image enlargement display screen 3000, when you return to the OCTA report screen 1000, the selection state changes to the EnFace image that was double-clicked on the OCTA report screen 1000. applied to the corresponding tomographic image. Note that when the angiogram display is synchronized between the tomographic images 1050 and 1060 on the OCTA report screen 1000, this is also applied to the tomographic images to be synchronized.

Similar to the OCTA report screen 1000, projection artifact reduction processing can also be applied to the tomographic image 3020.

The selection, display, and synchronization of the projection artifact reduction process are the same as in the OCTA report screen 1000, so detailed explanations will be omitted.

The ON/OFF selection state of the projection artifact reduction process is inherited from the selection state at the time of screen transition on the OCTA report screen 1000 and the enlarged fundus front image display screen 3000.

When transitioning to the enlarged display screen 3000 of the fundus frontal image, the projection artifact reduction process for the tomographic image 3020 is performed when the selection state of the projection artifact reduction of the OCTA image and tomographic image corresponding to the fundus frontal image double-clicked on the OCTA report screen 1000 is changed. Applicable. For example, on the OCTA report screen 1000, with the projection artifact reduction processing of the OCTA image 1030 turned on, EnFace Image1 is displayed on the fundus front image 1020, and by double-clicking the fundus front image 1020, an enlarged display screen of the fundus front image is displayed. 3000, the selection state in the OCTA image 1030 is inherited in the tomographic image 3020, and the projection artifact reduction process is turned on.

If you change the selection state of projection artifact reduction processing for the tomographic image 3020 on the fundus frontal image enlargement display screen 3000, when you return to the OCTA report screen 1000, the selection state changes to EnFace that was double-clicked on the OCTA report screen 1000. It is applied to the corresponding OCTA image and tomographic image.

In the EnFace image 3010, the brightness and contrast of the EnFace image can be changed. The method for changing the brightness and contrast is the same as in the OCTA report screen 1000, so a detailed explanation will be omitted.

For the brightness and contrast of the EnFace image, the values at the time of screen transition are carried over to the OCTA report screen 1000 and the enlarged fundus front image display screen 3000. When the screen changes to the enlarged fundus front image display screen 3000, the brightness and contrast values of the EnFace image double-clicked on the OCTA report screen 1000 are applied to the EnFace image 3010.

When the brightness and contrast of the EnFace image are changed on the fundus front image enlargement display screen 3000, when returning to the OCTA report screen 1000, those values are applied to the EnFace image that was double-clicked on the OCTA report screen 1000.

In the tomographic image 3020, the brightness and contrast of the tomographic image can be changed. The method for changing the brightness and contrast is the same as in the OCTA report screen 1000, so a detailed explanation will be omitted.

As for the brightness and contrast values of the tomographic image, the values at the time of screen transition are carried over to the OCTA report screen 1000 and the enlarged fundus front image display screen 3000. When the enlarged display screen 3000 of the fundus frontal image is displayed, the brightness and contrast of the tomographic image corresponding to the EnFace image double-clicked on the OCTA report screen 1000 are applied to the tomographic image 3020. For example, when EnFace Image 1 is displayed on the fundus front image 1020 and the fundus front image 1020 is double-clicked, the brightness and contrast values of the tomographic image 1050 are applied.

If you change the brightness and contrast of the tomographic image on the fundus front image enlargement display screen 3000, when you return to the OCTA report screen 1000, the values will be changed to the tomographic image corresponding to the EnFace image that was double-clicked on the OCTA report screen 1000. Applies to.

The EnFace image 3010 can display measurement results such as the distance between two points and the area of a region in a superimposed manner. Regarding the measurement result display, since it is the same as the OCTA report screen 1000, detailed explanation will be omitted.

As with other settings, a configuration in which the settings of the OCTA report screen 1000 are inherited is also possible, but an example in which the settings are not inherited will be described here.

The setting of the OCTA report screen 1000 is not inherited and the measurement result display for the EnFace image is turned on or off by default.

The ON/OFF state of measurement result display for the EnFace image set on the EnFace image enlargement display screen 2000 is not carried over to the OCTA report screen 1000, and the setting before transition to the EnFace image enlargement display screen 3000 is maintained.

The tomographic image 3020 can display measurement results such as the distance between two points and the area of a region in a superimposed manner. Regarding the measurement result display, since it is the same as the OCTA report screen 1000, detailed explanation will be omitted.

As with other settings, a configuration in which the settings can be changed is also possible, but here an example will be described in which the settings cannot be changed.

The ON/OFF setting of the measurement result display for the tomographic image 3020 does not take over the setting of the OCTA report screen 1000, but is fixed to ON, and the setting cannot be changed.

When printing or outputting from the enlarged fundus front image display screen 3000 by pressing a print button or an output button (not shown), an angiogram display, projection artifact reduction processing, an arrow indicating the B-scan position, brightness, contrast, and measurement are displayed. The result display, etc., is printed and output in the state when the button is pressed.

When the Close button 3030 is pressed, the screen returns to the OCTA report screen.

In this embodiment, an example of an EnFace image is used as the fundus front image 1020, but the fundus front image may be enlarged and displayed for a projection image or a C-Scan image.

In the case of a projection image, since the entire three-dimensional tomographic image is integrated, the depth ranges 3021, 3022, 3023, 3024, and 3025 are hidden or invalidly displayed. 3026 and 3027 indicating the upper and lower surfaces of the depth range on the tomographic image are also not displayed in a superimposed manner.

In the case of a C-Scan image, 3021, 3022, 3023, 3024, and 3025 indicating the depth range are hidden or invalid because a two-dimensional image of an arbitrary surface perpendicular to the depth direction (Z direction) is generated. will be displayed. 3026 and 3027 indicating the upper and lower surfaces of the depth range on the tomographic image are also not displayed in a superimposed manner.

In the case of a C-Scan image, the position in the depth direction (Z direction) at which the C-Scan image is generated is displayed on the tomographic image 3020, and by moving the position using the mouse, the C-Scan can be performed on any plane. Images can also be displayed. The display and operations related to C-Scan are the same as those on the OCTA report screen 1000, so detailed explanations will be omitted.

Although not shown, the enlarged fundus front image display screen 3000 may be configured so that the displayed fundus front image can be switched using a context menu when right-clicking the mouse.

(Enlarged display of tomographic image from OCTA report screen)
When a tomographic image is double-clicked on the OCTA report screen 1000, the screen changes to an enlarged tomographic image display screen 4000 shown in FIG.

On the enlarged tomographic image display screen 4000, a tomographic image is displayed at 4010.

When transitioning from the OCTA report screen 1000 to the enlarged tomographic image display screen 4000, an OCTA image corresponding to the tomographic image double-clicked on the OCTA report screen 1000 is displayed in 4020.

An example will be described in which a tomographic image 1050 corresponding to the OCTA image 1030 of OCTA Image 1 is double-clicked on the OCTA report screen 1000 to change the screen.

Displayed at 4020 is an OCTA image generated using the depth range information for generating the OCTA image selected at 1031, 1051, 1052, 1053, and 1054 at the time of screen transition.

4011 indicates which B-scan of all the B-scans of the 3D tomographic image is displayed in the tomographic image displayed in 4010, and is displayed on the tomographic image double-clicked on the OCTA report screen 1000. Displays the B-scan position.

The corresponding B-scan position is displayed in the OCTA image 4020 as an arrow 4021. In this embodiment, the B-scan position is always displayed, but a Show Lines checkbox is provided, and by checking or unchecking the check box, the display of the arrow indicating the B-scan position can be turned on or off. You can also do it. You can also switch using the right-click context menu of the mouse.

The B scan displayed on the tomographic image 4010 can be changed by operating the mouse wheel on the tomographic image 4010, similarly to the OCTA report screen 1000. Furthermore, the B-scan displayed on the tomographic image 4010 can be changed by moving the arrow 4021 indicating the B-scan position in the OCTA image 4020 using a mouse. Note that when changing the B-scan displayed on the tomographic image, the corresponding display is updated in conjunction.

If you change the B-scan displayed on the tomographic image 4010 on the tomographic image enlargement display screen 4000, when you return to the OCTA report screen 1000, the B-scan position will be applied to the tomographic image that was double-clicked on the OCTA report screen 1000. be done. All corresponding displays are also updated.

Although not shown in the tomographic image 4010, similarly to the OCTA report screen 1000, three-dimensional motion contrast data (aniogram) can be displayed superimposed on the tomographic image in any color and with any transparency. The method for selecting the angiogram display is the same as that for the OCTA report screen 1000, so a detailed explanation will be omitted.

The selection state of on/off of the angiogram display is inherited from the selection state at the time of screen transition on the OCTA report screen 1000 and the enlarged tomographic image display screen 4000.

When the tomographic image enlargement display screen 4000 is displayed, the selected state of the angiogram display of the tomographic image double-clicked on the OCTA report screen 1000 is applied to the angiogram display of the tomographic image 4010. For example, when the angiogram display of the tomographic image 1050 is turned on on the OCTA report screen 1000 and the tomographic image 1050 is double-clicked to transition to the tomographic image enlargement display screen 4000, the tomographic image 4010 is displayed as the tomographic image 1050. The selected state is inherited and the angiogram display is turned on.

If the selection state of the angiogram display of the tomographic image 4010 is changed on the tomographic image enlargement display screen 4000, when returning to the OCTA report screen 1000, the selected state is applied to the tomographic image that was double-clicked on the OCTA report screen 1000. be done. Note that when the angiogram display is synchronized between the tomographic images 1050 and 1060 on the OCTA report screen 1000, this is also applied to the tomographic images to be synchronized.

Similar to the OCTA report screen 1000, projection artifact reduction processing can also be applied to the tomographic image 4010 and the OCTA image 4020.

The selection, display, and synchronization of the projection artifact reduction process are the same as in the OCTA report screen 1000, so detailed explanations will be omitted.

The on/off selection state of the projection artifact reduction process is inherited from the selection state at the time of screen transition on the OCTA report screen 1000 and the tomographic image enlargement display screen 4000.

When transitioning to the enlarged tomographic image display screen 4000, the selected state of the projection artifact reduction process for the tomographic image double-clicked on the OCTA report screen 1000 is applied to the projection artifact reduction process for the tomographic image 4010 and OCTA image 4020. For example, on the OCTA report screen 1000, when the projection artifact reduction process for the tomographic image 1050 is turned on and the tomographic image 1050 is double-clicked to transition to the tomographic image enlargement display screen 4000, the tomographic image 4010, the OCTA image 4020 In this case, the selection state in the tomographic image 1050 is inherited, and the projection artifact reduction process is turned on.

If you change the selection state of projection artifact reduction processing for the tomographic image 4010 or OCTA image 4020 on the tomographic image enlargement display screen 4000, when you return to the OCTA report screen 1000, the selected state will be changed by double-clicking on the OCTA report screen 1000. It is applied to the tomographic image and the corresponding OCTA image.

Noise reduction processing using machine learning can also be applied to the OCTA image 4020. The selection and display of noise reduction processing using machine learning is the same as in the OCTA report screen 1000, so detailed explanation will be omitted.

The selection state of whether noise reduction processing using machine learning is turned on or off is inherited from the selection state at the time of screen transition on the OCTA report screen 1000 and the tomographic image enlargement display screen 4000.

When transitioning to the enlarged tomographic image display screen 4000, the noise reduction process using machine learning for the OCTA image 4020 is the noise reduction process using machine learning for the OCTA image corresponding to the tomographic image double-clicked on the OCTA report screen 1000. The selection state of is applied. For example, on the OCTA report screen 1000, with noise reduction processing using machine learning for the OCTA image 1030 turned on, double-click the tomographic image 1050 corresponding to the OCTA image 1030 to transition to the tomographic image enlargement display screen 4000. At this time, in the OCTA image 4020, the selection state in the OCTA image 1030 is inherited, and the noise reduction process using machine learning is turned on.

If you change the selection state of noise reduction processing using machine learning for OCTA images on the tomographic image enlargement display screen 4000, when you return to the OCTA report screen 1000, the selection state will be changed by double-clicking on the OCTA report screen 1000. The method is applied to an OCTA image corresponding to a tomographic image. Note that when noise reduction processing using machine learning is synchronized on the OCTA images 1030 and 1040 on the OCTA report screen 1000, it is also applied to the OCTA images to be synchronized.

In the tomographic image 4010, the brightness and contrast of the tomographic image can be changed. The method for changing the brightness and contrast is the same as in the OCTA report screen 1000, so a detailed explanation will be omitted.

As for the brightness and contrast values of the tomographic image, the values at the time of screen transition are carried over between the OCTA report screen 1000 and the tomographic image enlarged display screen 4000. When the tomographic image enlargement display screen 4000 is displayed, the brightness and contrast values of the tomographic image double-clicked on the OCTA report screen 1000 are applied to the brightness and contrast of the tomographic image 4010.

When the brightness and contrast of a tomographic image are changed on the tomographic image enlargement display screen 4000, when returning to the OCTA report screen 1000, those values are applied to the tomographic image that was double-clicked on the OCTA report screen 1000.

In the OCTA image 4020, the brightness and contrast of the OCTA image can be changed. The method for changing the brightness and contrast is the same as in the OCTA report screen 1000, so a detailed explanation will be omitted.

As for the brightness and contrast values of the OCTA image, the values at the time of screen transition are carried over between the OCTA report screen 1000 and the tomographic image enlarged display screen 4000. When the tomographic image enlargement display screen 4000 is displayed, the brightness and contrast values of the OCTA image corresponding to the tomographic image double-clicked on the OCTA report screen 1000 are applied to the OCTA image 4020. For example, when a tomographic image 1050 corresponding to 1030 of OCTA Image 1 is double-clicked, the brightness and contrast values of the OCTA image 1030 are applied.

If you change the brightness and contrast of the OCTA image on the tomographic image enlargement display screen 4000, when you return to the OCTA report screen 1000, the values will change to the OCTA image corresponding to the tomographic image that was double-clicked on the OCTA report screen 1000. Applicable.

The tomographic image 4010 can display measurement results such as the distance between two points and the area of a region in a superimposed manner. Regarding the measurement result display, since it is the same as the OCTA report screen 1000, detailed explanation will be omitted.

As with other settings, a configuration in which the settings of the OCTA report screen 1000 are inherited is also possible, but an example in which the settings are not inherited will be described here.

The setting of the OCTA report screen 1000 is not inherited and the measurement result display for the tomographic image is turned on or off by default.

The ON/OFF state of displaying measurement results for tomographic images set on the tomographic image enlargement display screen 4000 is not carried over to the OCTA report screen 1000, and the setting before the transition to the tomographic image enlargement display screen 4000 is maintained.

Measurement results such as the distance between two points and the area of a region can be displayed in a superimposed manner on the OCTA image 4020. Regarding the measurement result display, since it is the same as the OCTA report screen 1000, detailed explanation will be omitted.

As with other settings, a configuration in which the settings can be changed is also possible, but here an example will be described in which the settings cannot be changed.

The ON/OFF setting of the measurement result display for the OCTA image 4020 does not take over the setting of the OCTA report screen 1000, but is fixed to OFF, and the setting cannot be changed.

The display method of the tomographic image displayed on the tomographic image 4010 can be selected.

For example, display according to the display area or display at the actual aspect ratio can be selected from the context menu when right-clicking the mouse. The selection of the display method is not limited to this, and may be configured to be selected using radio buttons (not shown) or the like.

The aspect ratio of the display area of the tomographic image 4010 may be different from the aspect ratio of the display area of the tomographic images 1050 and 1060 on the OCTA report screen. In this case, if the tomographic images are displayed in the actual aspect ratio, the aspect ratios of the displayed tomographic images will be the same, but if the tomographic images are displayed in accordance with the display area, the aspect ratios of the displayed tomographic images will be different. Therefore, if the tomographic images 1050 and 1060 on the OCTA report screen are displayed in accordance with the display area, the tomographic image displayed in the tomographic image 4010 may be displayed in a manner that is adjusted to fit the display area of the tomographic image in the OCTA report screen 1000. It would be better if you could also choose to maintain the aspect ratio of the display. You can also make that setting the default.

The tomographic image 2020 of the OCTA image enlarged display screen 2000 and the tomographic image 3020 of the fundus front image enlarged display screen 3000 described above may also be configured in the same manner.

On the tomographic image enlargement display screen 4000, by checking or unchecking the Show Layer Boundary checkbox 4001, display of layer boundaries automatically detected by segmentation can be turned on or off.

When the Show Layer Boundary checkbox is checked, a line indicating a layer boundary automatically detected by segmentation is superimposed on the tomographic image 4010, although not shown. Each layer boundary is displayed as a solid line in a predetermined color, making it possible to identify the layer boundary.

The Layer button 4030 allows editing of lines indicating layer boundaries. Editing of lines indicating layer boundaries will be described later.

When printing or outputting by pressing the print button or output button (not shown) from the enlarged display screen of the tomographic image, the angiogram display, projection artifact reduction processing, arrow indicating the B-scan position, brightness, contrast, and measurement result display are displayed. , layer boundaries, etc. are printed and output in the state when the button is pressed.

When the Close button 4040 is pressed, the screen returns to the OCTA report screen.

In the present embodiment, an example has been described in which when the OCTA report screen 1000 transitions to the enlarged tomographic image display screen 4000, an OCTA image corresponding to the tomographic image double-clicked on the OCTA report screen 1000 is displayed in 4020. Not limited to.

When transitioning from the OCTA report screen 1000 to the enlarged tomographic image display screen 4000, the EnFace image corresponding to the tomographic image double-clicked on the OCTA report screen 1000 may be displayed in 4020.

Further, in step 4020, the configuration may be such that the OCTA image, EnFace image, Projection image, and C-Scan image can be switched using a right mouse click context menu or the like.

(Direct transition between enlarged display screens of OCTA report)
After returning from the OCTA image enlarged display screen 2000 to the OCTA report screen 1000 by pressing the Close button 2030, it is also possible to transition to the tomographic image enlarged display screen 4000. Direct transition will improve operability.

By double-clicking the tomographic image 2020 on the OCTA image enlarged display screen 2000, the screen can be directly changed to the tomographic image enlarged display screen 4000.

If the tomographic image 3020 is double-clicked on the enlarged display screen 3000 of the fundus frontal image, the screen can be directly changed to the enlarged display screen 4000 of the tomographic image.

When the OCTA image enlarged display screen 2000 directly transitions to the tomographic image enlarged display screen 4000, the OCTA image is displayed on 4020 of the tomographic image enlarged display screen 4000.

When the enlarged fundus front image display screen 2000 directly transitions to the enlarged tomographic image display screen 4000, the enlarged tomographic image display screen 4000 4020 displays the fundus that was displayed on the enlarged fundus front image display screen at the time of the screen transition. Display the front image.

When 4020 is double-clicked on the tomographic image enlarged display screen 4000, the screen changes to an enlarged display screen corresponding to the image displayed at 4020.

When an OCTA image is displayed in 4020, the screen changes to an OCTA enlarged display screen 2000.

If the front image of the fundus is displayed in 4020, the screen changes to an enlarged display screen 3000 of the front image of the fundus. When the screen changes to the enlarged fundus front image display screen 3000, the fundus front image displayed in 4020 is displayed in 3010.

In addition, the values and selection states that are inherited when transitioning from the OCTA report screen to various enlarged display screens are also inherited when directly transitioning between various enlarged display screens.

Note that values that are not carried over when transitioning from the OCTA report screen to various enlarged display screens are not carried over when directly transitioning between the various enlarged display screens.

(Thickness map report screen)
Image analysis data called a layer thickness map, which displays the thickness of a specific layer as a change in color based on layer boundaries detected through segmentation, is effective for diagnosis.

A display example of the layer thickness map report screen will be explained with reference to FIG. 12.

The layer thickness map report screen 5000 displays information 5001 about the left and right eyes of the subject's eye, photography date and time 5002, photography conditions 5003, and the like.

At 5010, an SLO fundus image is displayed.

At 5020, a fundus front image generated from the three-dimensional tomographic image is displayed.

At 5030, a tomographic image is displayed.

In 5031, 5032, 5033, and 5034, information on the depth range for measuring layer thickness is displayed.

In 5031, the upper surface reference of the upper surface of the depth range in which the layer thickness is measured is displayed, and in 5032, the relative distance of the upper surface from the upper surface reference is displayed. In 5033, the lower surface reference of the lower surface of the depth range for measuring the layer thickness is displayed, and in 5034, the lower surface relative distance from the lower surface reference is displayed.

Regarding the depth range for measuring the layer thickness, it is the same as in steps 1051, 1052, 1053, and 1054 for displaying and setting information on the depth range for generating an OCTA image on the OCTA report screen 1000, so a detailed explanation will be omitted.

Information on the depth range for measuring layer thickness is also superimposed and displayed on the tomographic image 5030. Reference numeral 5035 indicates a surface separated by a relative distance from the upper surface reference of 5031 to the upper surface of 5032, that is, the upper surface of the depth range in which the layer thickness is measured. 5036 indicates a surface separated by a relative distance from the lower surface reference of 5033 to the lower surface of 5034, that is, the lower surface of the depth range in which the layer thickness is measured.

A layer thickness map 5011 can be displayed superimposed on the SLO fundus image 5010.

As shown in FIG. 13, by switching the selection 5012, display of the SLO fundus image 5010 can be selected.

When Thickness Map is selected, a layer thickness map 5011 is displayed superimposed on the SLO fundus image. When the layer thickness map is displayed, a color scale 5013 is displayed.

When SLO Image is selected, only the SLO fundus image is displayed. When only the SLO fundus image is displayed, the color scale 5013 is not displayed.

A color scale of 5013 indicates a color corresponding to each layer thickness.

The layer thickness map 5011 measures the layer thickness in the depth range in which the layer thicknesses are measured and is displayed and set at 5031, 5032, 5033, and 5034, and for each layer thickness, the SLO fundus is shown in the color indicated by the color scale 5013. It is superimposed on the image and displayed transparently.

The transparency of the layer thickness map can be changed, for example, by operating the mouse wheel. The transparency of the layer thickness map is not limited to this, and may be changed by operating a button or a slider (not shown).

When the transparency is set to 100%, only the SLO fundus image is displayed, and when it is set to 0%, the SLO fundus image behind the layer thickness map is not displayed.

The fundus front image displayed in 5020 can be switched from Projection Image, EnFace Image, and C-Scan Image, as shown in FIG.

When Projection Image is selected, a projection image generated by integrating the entire three-dimensional tomographic image in the depth direction (Z direction) is displayed at 5020.

When EnFace Image is selected, an EnFace image generated from a three-dimensional tomographic image is displayed at 5020 in the same depth range as the depth range in which the layer thickness is measured.

When C-Scan Image is selected, a C-Scan image generated from a three-dimensional tomographic image as a two-dimensional image on an arbitrary plane perpendicular to the depth direction (Z direction) is displayed at 5020. In the case of a C-Scan image, the position in the depth direction (Z direction) at which the C-Scan image is generated is displayed on the tomographic image 5030, and by moving the position using the mouse, the C-Scan can be performed on any plane. Images can also be displayed. The display and operations related to C-Scan are the same as those on the OCTA report screen 1000, so detailed explanations will be omitted.

Similar to the depth range for generating the OCTA image on the OCTA report screen 1000, the depth range for measuring the layer thickness can be changed individually at 5031, 5032, 5033, and 5034.

The upper surface reference 5031 and the lower surface reference 5033 can be selected from layer boundaries automatically detected by segmentation, as shown in FIG. Furthermore, it is also possible to select a Line that specifies a plane perpendicular to the depth direction (Z direction) instead of the automatically detected layer boundary.

The upper surface relative distance 5032 and the lower surface relative distance 5034 can be set to any positive or negative value.

When at least one of 5031, 5032, 5033, and 5034 is changed, it is desirable to display a message indicating that the depth range for measuring layer thickness has been changed.

Even when 5031, 5032, 5033, and 5034 are changed individually, 5035 and 5036, which indicate the upper and lower surfaces of the depth range for measuring the layer thickness superimposed on the tomographic image 5030, are updated. When the layer thickness map is displayed, the layer thickness is measured in the changed depth range and the layer thickness map is updated. The color scale is also updated.

By moving 5035 and 5036, which are superimposed on the tomographic image 5030 and indicate the top and bottom surfaces of the depth range in which layer thickness is to be measured, using the mouse, you can determine the relative distance of the top surface to the selected top surface reference and the bottom surface reference. It is also possible to change the relative distance to the lower surface.

Even when these are changed individually, all the corresponding displays are updated in the same way as when the selection of the depth range definition for generating the OCTA image is changed.

The SLO fundus image of 5010 can be saved as a file with a name.

In step 5011, when SLO Image is selected and only the SLO fundus image is displayed, if the file is saved with a name, only the SLO fundus image is saved.

When Thickness Map is selected in step 5011 and the layer thickness map 5011 is displayed superimposed on the SLO fundus image, if a file is saved with a name, an image in which the layer thickness map is displayed superimposed on the SLO fundus image is saved. When saving an image in which a layer thickness map is superimposed on an SLO fundus image, the color scale is also saved. The transparency of the layer thickness map is the value used when saving the file with a name.

5037 indicates which B-scan of all the B-scans of the 3D tomographic image is displayed in the tomographic image displayed in 5030, and the corresponding B-scan position is shown in the SLO fundus image, fundus front view, It can be displayed superimposed on the image.

The B-scan position corresponding to the B-scan displayed at 5037 is displayed as an arrow at 5014 on the SLO fundus image at 5010, and as an arrow at 5022 on the front fundus image at 5020.

The display of the arrow indicating the B-scan position can also be switched on or off by checking or unchecking the Show Lines checkbox 5004. Switching the display on and off is the same as in the OCTA report screen 1000, so a detailed explanation will be omitted.

The B scan displayed on the tomographic image 5030 can be changed by operating the mouse wheel on the tomographic image 5030, similarly to the OCTA report screen 1000. Furthermore, the B-scan displayed on the tomographic image can be changed by moving the arrow indicating the B-scan position on the SLO fundus image 5010 and the front fundus image 5020 by operating the mouse. Note that when changing the B-scan displayed on the tomographic image, the corresponding display is updated in conjunction.

For example, when the EnFace Image is displayed on the front fundus image 5020, if you move the arrow indicating the B scan position displayed on the front fundus image 5020 using the mouse, the B scan displayed on the SLO fundus image 5010 will change. An arrow 5014 indicating the position also moves in conjunction. At the same time, the tomographic image displayed in tomographic image 5030 is changed to the corresponding B-scan, and the B-scan position of 5037 is also updated.

In the frontal fundus image 5020 and the tomographic image 5030, the brightness and contrast can be changed by operating the mouse, similarly to the OCTA images 1030 and 1040. Regarding changes in brightness and contrast, since they are the same as in the OCTA report screen 1000, detailed explanations will be omitted.

Similar to the OCTA images 1030 and 1040, measurement results such as the distance between two points and the area of a region can be displayed superimposed on the fundus frontal image 5020 and the tomographic image 5030. Regarding the measurement result display, since it is the same as the OCTA report screen 1000, detailed explanation will be omitted.

The display method of the tomographic image displayed on the tomographic image 5030 can be selected.

For example, display according to the display area or display at the actual aspect ratio can be selected from the context menu when right-clicking the mouse.

When printing or outputting a layer thickness map report by pressing a print button or an output button (not shown) on the layer thickness map report screen 5000, display of the layer thickness map, information on the depth range for measuring layer thickness, and the layer thickness map are displayed. The transparency of the thickness map, the color scale of the layer thickness map, the arrow indicating the B-scan position, the brightness, the contrast, etc. are printed and output in the state at the time the button is pressed.

When adding an option to display only the thickness map 5012, for example, Thickness Map Only, and selecting Thickness Map Only, the SLO fundus image may not be displayed in 5010, and only the thickness map 5011 may be displayed. When displaying only the layer thickness map 5011, only the layer thickness map is displayed without transparent display. If you want to display only the layer thickness map, if you save the file with a name, only the layer thickness map will be saved along with the color scale.

Although not shown, similarly to the depth range definition for generating an OCTA image, a plurality of depth range definitions for measuring layer thickness may be set, and the depth range definition for measuring layer thickness may be selectable. The selection of the depth range definition for measuring the layer thickness is not limited to this, and may be selected from the context menu of right-clicking the mouse.

5012, a plurality of definitions for measuring layer thickness in different depth ranges may be added so that they can be selected. For example, it is possible to select Thickness Map1 and Thickness Map2, and by selecting these, it is also possible to switch the display of layer thickness maps in different depth ranges.

5012, a plurality of maps of comparison results between the layer thickness measurement results and the normal eye database may be added so that they can be selected. For example, Comparison Map 1 and Comparison Map 2 can be selected, and the result of comparing the layer thicknesses measured in the depth ranges of Thickness Map 1 and Thickness Map 2 with the normal eye database can be displayed as a map.

If the depth range definition for measuring layer thickness allows different selections, selecting a different depth range definition will update all corresponding displays. Information on the depth range for measuring layer thicknesses 5031, 5032, 5033, and 5034 is updated. 5035 and 5036, which indicate the upper and lower surfaces of the depth range in which layer thickness is measured and are displayed superimposed on the tomographic image 5030, are also updated. When the layer thickness map is displayed in a superimposed manner, the layer thickness map is generated with the selected depth range definition, and the layer thickness map displayed in 5011 is also updated. Color scale 5013 is also updated. When the results of comparison with the normal eye database are displayed as a map, they are updated in the same way.

When the EnFace image is displayed at 5020, the EnFace image is generated with the selected depth range definition, and the EnFace image displayed at 5020 is also updated.

(Enlarged display of layer thickness map from layer thickness map report screen)
When the SLO fundus image 5010 is double-clicked on the layer thickness map report screen 5000, the screen changes to an enlarged layer thickness map display screen 6000 shown in FIG.

On the enlarged layer thickness map display screen 6000, an SLO fundus image is displayed at 6010, and a tomographic image is displayed at 6020.

If you double-click the SLO fundus image 5010 when the layer thickness map 5011 is displayed superimposed on the SLO fundus image 5010 on the layer thickness map report screen 5000, the SLO fundus image 5010 will be displayed on the layer thickness map enlarged display screen 6000. The image is displayed, and the layer thickness map 6011 is displayed superimposed. When displaying the layer thickness map, a color scale 6012 is also displayed.

In this case, on the layer thickness map enlarged display screen 6000, information on the depth range for measuring layer thickness when double-clicking the SLO fundus image 5010 on the layer thickness map report screen 5000 is displayed in 6021, 6022, 6023, and 6024. A layer thickness map 6011 measured in that depth range is displayed superimposed on the SLO fundus image. Further, the upper and lower surfaces of the depth range are displayed superimposed on the tomographic image 6020.

At 6021, the top reference selected at 5031 is displayed at the time of screen transition.

At 6022, the top surface relative distance selected at 5032 is displayed at the time of screen transition.

At 6023, the bottom reference selected at 5033 is displayed at the time of screen transition.

At 6024, the lower surface relative distance selected at 5034 is displayed at the time of screen transition.

The upper surface of the depth range in which the layer thickness is measured, which is displayed at 6021 and 6022, is superimposed and displayed at 6025 on the tomographic image 6020.

The lower surface of the depth range in which the layer thickness is measured, designated by 6023 and 6024, is superimposed and displayed as 6026 on the tomographic image 6020.

In 6021, 6022, 6023, and 6024 where information indicating the depth range for measuring the layer thickness is displayed, it is also possible to individually change and set an arbitrary depth range, similar to the layer thickness map report screen 5000. . In addition, by moving 6025 and 6026, which are superimposed on the tomographic image 6020 and indicate the upper and lower surfaces of the depth range in which the layer thickness is to be measured, by operating the mouse, the relative distance of the upper surface with respect to the selected upper surface reference can be determined. It is also possible to change the relative distance of the lower surface to the lower surface reference. Since it is the same as the layer thickness map report screen 5000, detailed explanation will be omitted.

If you change the information indicating the depth range for measuring the layer thickness on the layer thickness map enlarged display screen 6000, when you return to the layer thickness map report screen 1000, the information on that depth range will be changed to the layer on the layer thickness map report screen 5000. Applies to depth range information for measuring thickness.

Similar to the layer thickness map report screen 5000, the transparency of the layer thickness map can be changed. Regarding changing the transparency of the layer thickness map, since it is the same as the layer thickness map report screen 5000, detailed explanation will be omitted.

The transparency of the layer thickness map is inherited from the value at the time of screen transition on the layer thickness map report screen 5000 and the layer thickness map enlarged display screen 6000.

When the layer thickness map enlarged display screen 6000 is displayed, the transparency value of the layer thickness map 6010 when double-clicked on the layer thickness map report screen 5000 is applied.

When the transparency of the layer thickness map is changed on the layer thickness map enlarged display screen 6000, that value is applied to the layer thickness map on the layer thickness map report screen 5000 when returning to the layer thickness map report screen 5000.

If you double-click the SLO fundus image 5010 when only the SLO fundus image is displayed in the SLO fundus image 5010 of the layer thickness map report screen 5000, the SLO fundus image 6010 will be displayed on the layer thickness map enlarged display screen 6000. only is displayed. When only the SLO fundus image is displayed, the color scale 6012 is not displayed.

When displaying only the SLO fundus image, information on the depth range in which the layer thickness is measured may be hidden or displayed in an invalid manner.

The SLO fundus image 6010 can be saved as a file with a name, similar to the layer thickness map report screen 5000.

In 6010, when only the SLO fundus image is displayed, if a file is saved with a name, only the SLO fundus image is saved.

In 6010, when the layer thickness map 5011 is displayed superimposed on the SLO fundus image, if a file is saved with a name, an image in which the layer thickness map is displayed superimposed on the SLO fundus image is saved. When saving an image in which a layer thickness map is superimposed on an SLO fundus image, the color scale is also saved. The transparency of the layer thickness map is the value used when saving the file with a name.

6027 indicates which B-scan the tomographic image displayed in 6020 is displaying among all B-scans of the 3D tomographic image, and double the SLO fundus image 5010 on the layer thickness map report screen 5000. When clicked, the B scan position displayed in 5037 is displayed.

The corresponding B-scan position is displayed as an arrow 6013 on the SLO fundus image 6010. The display of the arrow indicating the B-scan position can be switched on or off by checking or unchecking the Show Lines checkbox 6001. Switching the display on and off is the same as in the layer thickness map report screen 5000, so a detailed explanation will be omitted.

The B scan displayed on the tomographic image 6020 can be changed by operating the mouse wheel on the tomographic image 6020, similarly to the layer thickness map report screen 5000. Furthermore, the B-scan displayed on the tomographic image 6020 can be changed by moving the arrow 6013 indicating the B-scan position in the SLO fundus image 6010 using a mouse. Note that when changing the B-scan displayed on the tomographic image, the corresponding display is updated in conjunction.

If you change the B-scan displayed on the tomographic image 6020 on the layer thickness map enlarged display screen 6000, when you return to the layer thickness map report screen 5000, the B-scan position will be applied to the tomographic image on the layer thickness map report screen 5000. be done. All corresponding displays are also updated.

In the tomographic image 6020, the brightness and contrast of the tomographic image can be changed by operating the mouse. Regarding the brightness and contrast changes, since they are the same as those on the layer thickness map report screen 5000, detailed explanations will be omitted.

As for the brightness and contrast values of the tomographic image, the values at the time of screen transition are carried over to the layer thickness map report screen 5000 and the layer thickness map enlarged display screen 6000. When transitioning to the enlarged layer thickness map display screen 6000, the brightness and contrast of the tomographic image 6020 are applied to the brightness and contrast of the tomographic image 5030 when double-clicking the SLO fundus image 5010 on the layer thickness map report screen 5000. be done.

When the brightness and contrast of the tomographic image are changed on the layer thickness map enlarged display screen 6000, those values are applied to the tomographic image on the layer thickness map report screen 5000 when returning to the layer thickness map report screen 5000.

The tomographic image 6020 can display measurement results such as the distance between two points and the area of a region in a superimposed manner. Regarding the measurement result display, since it is the same as the layer thickness map report screen 5000, detailed explanation will be omitted.

As with other settings, a configuration in which the settings can be changed is also possible, but here an example will be described in which the settings cannot be changed.

The ON/OFF setting of the measurement result display for the tomographic image 6020 does not take over the setting of the layer thickness map report screen 5000, but is fixed to ON, and the setting cannot be changed.

When printing or outputting from the layer thickness map enlarged display screen 6000 by pressing a print button or an output button (not shown), display of the layer thickness map, information on the depth range for measuring the layer thickness, information on the layer thickness map, etc. The transparency, color scale of the layer thickness map, arrow indicating the B-scan position, brightness, contrast, etc. are printed and output in the state when the button is pressed.

When the Close button 6030 is pressed, the screen returns to the layer thickness map report screen.

Although not shown in the enlarged layer thickness map display screen 6000, similarly to the layer thickness map report screen 5000, the image displayed on the layer thickness map 6010 may be configured to be switchable. For example, the configuration may be configured such that selections such as displaying only the SLO fundus image, displaying the layer thickness map superimposed on the SLO fundus image, etc. can be switched using a context menu when right-clicking the mouse. It may be configured such that only the layer thickness map can be displayed.

Similarly to the layer thickness map report screen 5000, it may be possible to switch between displaying layer thickness maps in different depth ranges. Further, the configuration may be such that the results of comparison with the normal eye database can be displayed on a map.

(Enlarged display of fundus front image from layer thickness map report screen)
When the fundus front image 5020 is double-clicked on the layer thickness map report screen 5000, the screen changes to an enlarged fundus front image display screen 7000 shown in FIG.

On the enlarged fundus front image display screen 7000, a fundus front image is displayed at 7010, and a tomographic image is displayed at 7020.

On the enlarged fundus front image display screen 7000 , the fundus front image that was displayed when the fundus front image 5020 was double-clicked on the layer thickness map report screen 5000 is displayed in 7010 .

When the EnFace image is displayed on the fundus front image 5020 and the user double-clicks on the EnFace image, the EnFace image is displayed on the fundus oculi front image 5020 .

When the Projection image is displayed on the fundus front image 5020 and the Projection image is double-clicked, the Projection image is displayed in 7010 .

When the C-Scan image is displayed in the fundus front image 5020 and the C-Scan image is double-clicked, the C-Scan image is displayed in 7010 .

An example of double-clicking the fundus front image 5020 when the EnFace image is displayed on the fundus front image 5020 of the layer thickness map report screen 5000 will be described.

Since the EnFace image is generated in the same depth range as the depth range for measuring the layer thickness on the layer thickness map report screen 5000, the information on the depth range for measuring the layer thickness that was displayed on the layer thickness map report screen 5000 is , 7021, 7022, 7023, and 7024, and the EnFace image generated in that depth range is displayed at 7010. Further, the upper and lower surfaces of the depth range are displayed superimposed on the tomographic image 7020.

In 7021, the top reference selected in 5031 is displayed at the time of screen transition.

At 7022, the top relative distance selected at 5032 is displayed at the time of screen transition.

In 7023, the bottom reference selected in 5033 is displayed at the time of screen transition.

In 7024, the lower surface relative distance selected in 5034 is displayed at the time of screen transition.

The upper surface of the depth range in which the EnFace image is generated, which is displayed in 7021 and 7022, is superimposed and displayed as 7025 on the tomographic image 7020.

The lower surface of the depth range in which the EnFace image is generated, which is displayed in 7023 and 7024, is superimposed and displayed as 7026 on the tomographic image 7020.

In 7021, 7022, 7023, and 7024 where information indicating the depth range for generating the EnFace image is displayed, similarly to the layer thickness map report screen 5000, it is also possible to individually change and set an arbitrary depth range. . In addition, by moving 7025 and 7026, which are superimposed on the tomographic image 7020 and indicate the upper and lower surfaces of the depth range for generating the EnFace image, by operating the mouse, the relative distance of the upper surface with respect to the selected upper surface reference, It is also possible to change the relative distance of the lower surface to the lower surface reference. Since it is the same as the layer thickness map report screen 5000, detailed explanation will be omitted.

If the information indicating the depth range for generating the EnFace image is changed on the fundus front image enlargement display screen 7000, when returning to the layer thickness map report screen 5000, the information on that depth range will be changed to the layer thickness map report screen 5000. Applies to depth range information for measuring thickness.

An example will be described in which a projection image is displayed on the fundus front image 5020 on the layer thickness map report screen 5000.

In the case of a projection image, since the entire three-dimensional tomographic image is integrated, the depth ranges 7021, 7022, 7023, and 7024 are hidden or invalidly displayed. 7025 and 7026, which indicate the upper and lower surfaces of the depth range on the tomographic image, are also not displayed in a superimposed manner.

An example will be described in which a C-Scan image is displayed in the fundus front image 5020 on the layer thickness map report screen 5000.

In the case of a C-Scan image, since a two-dimensional image of an arbitrary surface perpendicular to the depth direction (Z direction) is generated, 7021, 7022, 7023, and 7024 indicating the depth range are hidden or disabled. Become. 7025 and 7026, which indicate the upper and lower surfaces of the depth range on the tomographic image, are also not displayed in a superimposed manner.

In the case of a C-Scan image, the position in the depth direction (Z direction) at which the C-Scan image is generated is displayed on the tomographic image 7020, and by moving the position using the mouse, the C-Scan can be performed on any plane. Images can also be displayed. The display and operations related to C-Scan are the same as those on the layer thickness map report screen 5000, so detailed explanations will be omitted.

The fundus front image displayed in 7010 can be selected from EnFace image, Projection image, and C-Scan image in 7002, similar to 5021 of layer thickness map report screen 5000.

7027 indicates which B-scan of all the B-scans of the 3D tomographic image is displayed in the tomographic image displayed in 7020. When clicked, the B scan position displayed in 5037 is displayed.

The corresponding B-scan position is displayed as an arrow 7011 on the fundus front image 7010. The display of the arrow indicating the B-scan position can be switched on or off by checking or unchecking the Show Lines checkbox 7001. Switching the display on and off is the same as in the layer thickness map report screen 5000, so a detailed explanation will be omitted.

The B scan displayed on the tomographic image 7020 can be changed by operating the mouse wheel on the tomographic image 7020, similarly to the layer thickness map report screen 5000. Furthermore, the B-scan displayed on the tomographic image 7020 can be changed by moving the arrow 7011 indicating the B-scan position in the frontal fundus image 7010 using a mouse. Note that when changing the B-scan displayed on the tomographic image, the corresponding display is updated in conjunction.

If you change the B-scan displayed on the tomographic image 7020 on the tomographic image enlargement display screen 7000, when you return to the layer thickness map report screen 5000, the B-scan position will be applied to the tomographic image on the layer thickness map report screen 5000. Ru. All corresponding displays are also updated.

In the tomographic image 7020, the brightness and contrast of the tomographic image can be changed by operating the mouse. Regarding the brightness and contrast changes, since they are the same as those on the layer thickness map report screen 5000, detailed explanations will be omitted.

As for the brightness and contrast values of the tomographic image, the values at the time of screen transition are carried over to the layer thickness map report screen 5000 and the enlarged fundus front image display screen 7000. When transitioning to the enlarged fundus front image display screen 7000, the brightness and contrast of the tomographic image 7020 are applied to the brightness and contrast of the tomographic image 5030 when double-clicking the fundus front image 5010 on the layer thickness map report screen 5000. be done.

If the brightness and contrast of the tomographic image are changed on the fundus front image enlargement display screen 7000, the values are applied to the tomographic image on the thickness map report screen 5000 when returning to the thickness map report screen 5000.

Measurement results such as the distance between two points and the area of a region can be displayed in a superimposed manner on the fundus front image 7010. Regarding the measurement result display, since it is the same as the layer thickness map report screen 5000, detailed explanation will be omitted.

As with other settings, a configuration in which the settings of the layer thickness map report screen 5000 are inherited is also possible, but here, an example will be described in which the settings are not inherited.

The setting of the layer thickness map report screen 5000 is not inherited and the measurement result display for the fundus front image is turned on or off by default.

The ON/OFF setting of measurement result display for the fundus front image set on the fundus front image enlarged display screen 7000 is not carried over to the layer thickness map report screen 5000, and the setting before transitioning to the fundus front image enlarged display screen 7000 is maintained. do.

The tomographic image 7020 can display measurement results such as the distance between two points and the area of a region in a superimposed manner. Regarding the measurement result display, since it is the same as the layer thickness map report screen 5000, detailed explanation will be omitted.

As with other settings, a configuration in which the settings can be changed is also possible, but here an example will be described in which the settings cannot be changed.

The ON/OFF setting of the measurement result display for the tomographic image 7020 does not take over the setting of the layer thickness map report screen 5000, but is fixed to ON, and the setting cannot be changed.

When printing or outputting from the enlarged fundus front image display screen 7000 by pressing a print button or an output button (not shown), information on the depth range for generating the EnFace image, an arrow indicating the B-scan position, brightness, and contrast are displayed. etc., are printed and output in the state when the button is pressed.

When the Close button 7030 is pressed, the screen returns to the layer thickness map report screen.

(Enlarged display of tomographic image from layer thickness map report screen)
When a tomographic image is double-clicked on the layer thickness map report screen 5000, the screen changes to an enlarged tomographic image display screen 8000 shown in FIG.

On the tomographic image enlargement display screen 8000, a tomographic image is displayed at 8010.

When transitioning from the layer thickness map report screen 5000 to the enlarged tomographic image display screen 8000, the SLO fundus image is displayed at 8020, and the layer thickness map 8021 is also superimposed. A color scale 8022 of the layer thickness map is also displayed.

An example will be described in which the tomographic image 5030 is double-clicked to change the screen with the Thickness Map selected in 5012 of the layer thickness map report screen 5000.

At 8020, an SLO fundus image is displayed. The layer thickness map generated in the depth range for measuring the layer thickness selected in 5031, 5032, 5034, and 5045 at the time of screen transition is superimposed and displayed as the layer thickness map 8021 on the SLO fundus image 8020.

Similar to the layer thickness map report screen 5000, the transparency of the layer thickness map can be changed. Regarding changing the transparency of the layer thickness map, since it is the same as the layer thickness map report screen 5000, detailed explanation will be omitted.

The transparency of the layer thickness map is inherited from the value at the time of screen transition on the layer thickness map report screen 5000 and the tomographic image enlargement display screen 8000.

When the tomographic image enlargement display screen 8000 is displayed, the transparency value of the layer thickness map 8021 when double-clicked on the layer thickness map report screen 5000 is applied.

When the transparency of the layer thickness map 8021 is changed on the tomographic image enlargement display screen 8000, that value is applied to the layer thickness map on the layer thickness map report screen 5000 when returning to the layer thickness map report screen 5000.

8011 indicates which B-scan of all the B-scans of the 3D tomographic image is displayed in the tomographic image displayed in 8010. Displays the displayed B-scan position.

The corresponding B-scan position is displayed as an arrow 8023 in the SLO fundus image 8020. In this embodiment, the B-scan position is always displayed, but a Show Lines checkbox is provided, and by checking or unchecking the check box, the display of the arrow indicating the B-scan position can be turned on or off. You can also do it. You can also switch using the right-click context menu of the mouse.

The B scan displayed on the tomographic image 8010 can be changed by operating the mouse wheel on the tomographic image 8010, similarly to the layer thickness map report screen 5000. Furthermore, the B-scan displayed on the tomographic image 8010 can be changed by moving the arrow 8023 indicating the B-scan position in the SLO fundus image 8020 using the mouse. Note that when changing the B-scan displayed on the tomographic image, the corresponding display is updated in conjunction.

When changing the B-scan displayed on the tomographic image 8010 on the tomographic image enlargement display screen 8000, when returning to the layer thickness map report screen 5000, the B-scan position was double-clicked on the layer thickness map report screen 5000. Applied to tomographic images. All corresponding displays are also updated.

In the tomographic image 8010, the brightness and contrast of the tomographic image can be changed. The method of changing the brightness and contrast is the same as that of the layer thickness map report screen 5000, so a detailed explanation will be omitted.

As for the brightness and contrast values of the tomographic image, the values at the time of screen transition are carried over to the layer thickness map report screen 5000 and the tomographic image enlargement display screen 8000. When the tomographic image enlargement display screen 8000 is displayed, the brightness and contrast values of the tomographic image double-clicked on the layer thickness map report screen 5000 are applied to the brightness and contrast of the tomographic image 8010.

When the brightness and contrast of the tomographic image are changed on the tomographic image enlargement display screen 8000, when returning to the layer thickness map report screen 5000, those values are applied to the tomographic image that was double-clicked on the layer thickness map report screen 5000. be done.

The tomographic image 8010 can display measurement results such as the distance between two points and the area of a region in a superimposed manner. Regarding the measurement result display, since it is the same as the layer thickness map report screen 5000, detailed explanation will be omitted.

As with other settings, a configuration in which the settings of the layer thickness map report screen 5000 are inherited is also possible, but here, an example will be described in which the settings are not inherited.

The setting of the layer thickness map report screen 5000 is not inherited and the measurement result display for the tomographic image is turned on or off by default.

The ON/OFF state of displaying measurement results for a tomographic image set on the tomographic image enlargement display screen 8000 is not carried over to the layer thickness map report screen 5000, and the setting before transition to the tomographic image enlargement display screen 8000 is maintained.

The display method of the tomographic image displayed on the tomographic image 8010 can be selected.

For example, display according to the display area or display at the actual aspect ratio can be selected from the context menu when right-clicking the mouse. The selection of the display method is not limited to this, and may be configured to be selected using radio buttons (not shown) or the like.

The aspect ratio of the display area of the tomographic image 8010 may be different from the aspect ratio of the display area of the tomographic image 5030 on the layer thickness map report screen. In this case, if the tomographic images are displayed in the actual aspect ratio, the aspect ratios of the displayed tomographic images will be the same, but if the tomographic images are displayed in accordance with the display area, the aspect ratios of the displayed tomographic images will be different. Therefore, when the tomographic image 5030 on the layer thickness map report screen 5000 is displayed in accordance with the display area, the display area of the tomographic image on the layer thickness map report screen is It would be better if you could also choose to maintain the aspect ratio of the display according to the image. You can also make that setting the default.

The tomographic image 6020 of the layer thickness map enlarged display screen 6000 and the tomographic image 7020 of the fundus front image enlarged display screen 7000 described above may also be configured in the same manner.

On the tomographic image enlargement display screen 8000, by checking or unchecking the Show Layer Boundary checkbox 8001, display of layer boundaries automatically detected by segmentation can be turned on or off.

When the Show Layer Boundary checkbox is checked, a line indicating a layer boundary automatically detected by segmentation is superimposed on the tomographic image 8010, although not shown. Each layer boundary is displayed as a solid line in a predetermined color, making it possible to identify the layer boundary.

Layer buttons 8030 allow editing of layer boundaries. Editing of layer boundaries will be described later.

When printing or outputting by pressing the print button or output button (not shown) from the enlarged display screen of the tomographic image, the arrow indicating the B-scan position, brightness, contrast, measurement result display, layer boundary display, and map transparency are displayed. It is printed and output in the state when the button is pressed, such as the degree.

When the Close button 8040 is pressed, the screen returns to the layer thickness map report screen.

In this embodiment, an example has been described in which the screen is changed by double-clicking the tomographic image 5030 with the Thickness Map selected in 5012 of the layer thickness map report screen 5000, but the present invention is not limited to this.

If display of only the SLO image is selected in 5012 of the layer thickness map report screen 5000, only the SLO fundus image is displayed in 8020, as in the layer thickness map report screen 5000, and the layer thickness map 8021 and color scale 8022 are displayed. You may choose not to display it.

When displaying only the SLO image is selected in step 5012 of the layer thickness map report screen 5000, a map to be displayed by default may be set and that map may be displayed.

In 5012 of the layer thickness map report screen 5000, if it is possible to select a map for measuring layer thickness in different depth ranges, a map for comparing the layer thickness measurement results with the normal eye database, etc., the map selected in 5012 is displayed. Ru.

8020 may be configured such that a map for measuring layer thickness in different depth ranges and a map for comparison results between the layer thickness measurement results and the normal eye database can be switched using a right-click context menu of the mouse or the like.

If the selection of the map to be displayed in 8020 is changed on the tomographic image enlargement display screen 8000, the selection is applied to the layer thickness map on the layer thickness map report screen 5000 when returning to the layer thickness map report screen 5000.

8020 may be configured so that it can be switched to an EnFace image, a Projection image, or a C-Scan image using a right-click context menu of the mouse or the like.

(Direct transition between enlarged display screens of layer thickness map report)
After returning to the layer thickness map report screen 5000 from the layer thickness map enlarged display screen 6000 by pressing the Close button 6030, it is also possible to transition to the tomographic image enlarged display screen 8000. Operability will be improved if you can directly transition between display screens.

When the tomographic image 6020 is double-clicked on the layer thickness map enlarged display screen 6000, it is possible to directly transition to the tomographic image enlarged display screen 8000.

By double-clicking the tomographic image 7020 on the enlarged display screen 7000 of the fundus frontal image, the screen can be directly changed to the enlarged display screen 8000 of the tomographic image.

When you directly transition from the layer thickness map enlarged display screen 6000 to the tomographic image enlarged display screen 8000 while the layer thickness map is displayed on the layer thickness map enlarged display screen 6000, the tomographic image enlarged display screen 8000 An SLO fundus image is displayed at 8020, and a layer thickness map 8021 is also superimposed. A color scale 8022 is also displayed.

When the layer thickness map enlarged display screen 6000 displays only the SLO fundus image and the layer thickness map enlarged display screen 6000 directly transitions to the tomographic image enlarged display screen 8000, the tomographic image enlarged display screen In 8020 of 8000, only the SLO fundus image may be displayed, and the layer thickness map 8021 and color scale 8022 may not be displayed.

When you directly transition from the layer thickness map enlarged display screen 6000 to the tomographic image enlarged display screen 8000 while only the SLO fundus image is being displayed on the layer thickness map enlarged display screen 6000, the map to be displayed by default is changed. The SLO fundus image may be displayed on 8020 of the enlarged tomographic image display screen 8000, and a map to be displayed by default may be displayed superimposed on the layer thickness map 8021. In this case, the color scale 8022 of the map displayed by default is also displayed.

When there is a direct transition from the fundus frontal image enlarged display screen 7000 to the tomographic image enlarged display screen 8000, the tomographic image enlarged display screen 8000 8020 displays the fundus frontal image enlarged display screen 8000 at the time of the screen transition. Displays the fundus front image.

When 8020 is double-clicked on the tomographic image enlarged display screen 8000, a transition is made to an enlarged display screen corresponding to the image displayed at 8020.

If the SLO fundus image or the layer thickness map is displayed superimposed on the SLO fundus image at 8020, the screen changes to a layer thickness map enlarged display screen 6000. When the screen changes to the layer thickness map enlarged display screen 6000, the map displayed at 8020 is displayed at 6011.

When the front image of the fundus is displayed in 8020, the screen changes to an enlarged display screen 7000 of the front image of the fundus. When the screen changes to the enlarged fundus front image display screen 7000 , the fundus front image displayed at 8020 is displayed at 7010 .

In addition, the values and selection states that are inherited when transitioning from the layer thickness map report screen to various enlarged display screens are also inherited when directly transitioning between various enlarged display screens.

Note that values that are not inherited when transitioning from the layer thickness map report screen to various enlarged display screens are not inherited when directly transitioning between the various enlarged display screens.

(Correction of layer boundaries)
Correction of layer boundaries will be explained using an enlarged display screen 4000 of a tomographic image from an OCTA report in FIG. 11. In this embodiment, the explanation is omitted, but the same applies when transitioning from the layer thickness map report in FIG. 17 to the enlarged tomographic image display screen 8000.

When the examiner presses the Layer button 4030 in order to correct layer boundaries on the enlarged tomographic image display screen 4000 in FIG. As shown in FIG. 3, control is performed to display a layer boundary correction screen 4040 for selecting a layer boundary correction mode and a layer boundary to be corrected.

When the examiner presses the Layer button 4030, the layer boundary correction means turns on the Show Layer Boundary check box 4001 even if it is off, segments the layer structure of the retina, and displays the automatically detected layer. A line indicating the boundary is displayed superimposed on the tomographic image 4010.

As shown in FIG. 19, the layer boundary correction screen 4040 is always displayed while layer boundary correction is being performed.

As a result, it is possible to correct the line indicating the layer boundary on the tomographic image 4010 while the layer boundary correction screen 4040 is displayed, and it is also possible to correct the layer boundary correction while switching the layer boundary correction mode and the layer boundary to be corrected. It becomes possible to do this. Note that a configuration may be adopted in which the layer boundary correction screen 4040 is displayed by the examiner's operation.

On the layer boundary correction screen 4040, Drawing mode and Correction mode can be selected as layer boundary correction modes. Drawing mode allows the examiner to set the editing point at any position on the tomographic image 4010, so it is suitable when the correction point is large, while Correction mode allows the examiner to set the editing point at any position on the tomographic image 4010. This method is suitable for cases where the correction points are small because the editing points on the line indicating the correction points are moved one by one. Here, the editing point is a point designated as a point through which a line indicating a layer boundary passes, and is a point that can be moved by the examiner's operation.

(Drawing mode)
On the layer boundary correction screen 4040, when the examiner selects Drawing mode as the correction mode and selects ILM as the line indicating the layer boundary to be corrected, as shown in FIG. A line L indicating the layer boundary is automatically set and displayed as a dotted line.

In FIG. 23, ILM is selected as the layer boundary to be corrected. Layer boundaries that are not subject to correction remain displayed as solid lines. Note that each layer boundary is displayed in a predetermined color, so that each layer boundary can be identified.

When the line indicating the first layer boundary, which is the layer boundary to be corrected, is changed to IS/OS, the line indicating the layer boundary of IS/OS becomes a dotted line, as shown in Figure 24, and the line indicating the first layer boundary, which is the layer boundary to be corrected, is changed to IS/OS. Layer boundaries that are missing are displayed as solid lines.

In the Drawing mode, the layer boundary correction means accepts an operation for setting an editing point at any position on the tomographic image 4010 including the automatically set line L indicating the first layer boundary.
In Drawing mode, when the examiner clicks a desired position with the mouse to set an edit point, which is different from the line L indicating the first layer boundary, the set edit point and the first layer boundary are displayed. A line indicating a second layer boundary, which is a line indicating a new layer boundary, is generated and displayed based on at least two reference points on the line L.

For example, when the correct position of the line L indicating the layer boundary is the position shown in FIG. 23, the first layer set by automatic layer detection by segmentation of the region s (range W) as shown in FIG. An example of correction when the examiner corrects the line L indicating the layer boundary will be described.

The following is an example in which a line indicating the second layer boundary is generated and displayed when only one editing point is set for the automatically set line L indicating the first layer boundary.

FIG. 32(A) is a line L indicating the automatically set first layer boundary.

The examiner performs an operation to set the editing point p1 at a position different from the position of the automatically set line L indicating the first layer boundary, and the layer boundary line correction means receives this operation.

Then, on the B-scan image, the intersection point p1' between the straight line in the A-scan direction (depth direction of the eye to be examined) passing through the editing point p1 and the automatically set line L indicating the first layer boundary is identified and identified. A straight line in the A-scan direction that includes one of two points a predetermined distance t apart from the point p1' in the direction perpendicular to the A-scan direction, and a line L1 indicating the automatically set first layer boundary. The points p1L and p1R, which are the intersections of and, are automatically selected as reference points (FIG. 32(B)).

Then, connect the edit point p1 and the reference point p1L, and the edit point p1 and the reference point p1R, and connect the part from p1L to p1R on the automatically set line L indicating the first layer boundary between the reference point p1L and the edit point The line connecting p1 is changed to the line connecting edit point p1 and reference point p1R, and a line indicating the second layer boundary is generated and displayed (FIG. 32(C)).

At this time, p1L and p1 and p1 and p1R may each be connected by a line segment to generate a line indicating the second layer boundary, but it is preferable to draw a curved line by spline interpolation or the like. Then, when drawing a curve using spline interpolation, etc., in order to smoothly generate a line indicating the second layer boundary, the position to the left of p1L on the line L indicating the automatically set first layer boundary (automatically set A plurality of reference points p1L1, p1L2, ..., p1Ln are further automatically set from the position of the edit point p1 on the line L indicating the first layer boundary to the position beyond p1L in the direction toward the position of the reference point p1L). (FIG. 32(D)), it is desirable that the curve be a curve passing through p1, pL1, and p1L1 to p1Ln (FIG. 32(E)). Similarly, the line L indicating the automatically set first layer boundary Multiple reference points p1R1 are located on the right side of the upper p1R (a position beyond p1L in the direction from the edit point p1 position to the reference point p1R position on the line L indicating the automatically set first layer boundary). , p1R2, . The number of reference points p1L1, p1L2, ..., p1Ln is preferably set at a position on the left side of p1L on the line L indicating the automatically set first layer boundary. A plurality of points near the reference point p1L on the line L indicating the automatically set first layer boundary may be set as the reference point.Similarly, p1R on the line L indicating the automatically set first layer boundary may be set as the reference point. Although a plurality of reference points p1R1, p1R2, ..., p1Rn are set at positions on the right side, a plurality of points near the reference point p1R on the line L indicating the automatically set layer boundary may be set as the reference point. .

In addition, when drawing a curved line using spline interpolation or the like, if the left and right sides are connected separately based on the added edit point p1, the edit point p1 becomes a discontinuous point, so the added edit point p1, the reference point p1L, The curve connecting the reference point p1R on the right side may be a continuous curve.

Further, the layer boundary line correction means may be configured to accept an operation for selecting whether the set edit point p1 is a discontinuous point or a continuous point between the parts connected to the edit point p1.

Furthermore, of the line indicating the second layer boundary, which is the line indicating the new layer boundary, the part that has been corrected by setting the edit point p1 and the part that has not been manually corrected (i.e., the part that has not been manually corrected (i.e., the line that has been automatically set) The portion overlapping with the line L indicating the first layer boundary) can be displayed distinguishably in different display formats such as a solid line display and a dotted line display, as shown in FIGS. 32(C) and (E).

Next, a method for generating a line indicating the third layer boundary when two or more edit points are added, that is, when a new edit point is added to the line indicating the second layer boundary, will be described.

After the layer boundary line correction means receives an operation to set the edit point p1 at a position different from the line indicating the first layer boundary automatically set by the segmentation, and the line indicating the second layer boundary is generated, If the examiner performs an operation to additionally set an edit point p2, the generated second layer boundary will be The line indicating the second layer boundary is regarded as the line indicating the first layer boundary in the method in which the line indicating the second layer boundary is set as described above, and the edit point p2 and the line indicating the second layer boundary are A line indicating a third layer boundary is generated based on at least two reference points of .

The above is an example in which when setting multiple edit points, a new line indicating a layer boundary is generated each time an edit point is set, but after completing the setting of multiple edit points, a line indicating a new layer boundary is generated. A configuration may also be adopted in which lines indicating layer boundaries are generated. An example of such a case will be described below.

FIG. 33(A) is a line L indicating the automatically set first layer boundary.

The layer boundary line correction means receives an operation by the examiner to set editing points p1 and p2 at positions different from the positions on the line L indicating the automatically set first layer boundary.

Among the added edit points p1 and p2, a straight line in the A-scan direction that passes through edit point p1, which is the leftmost edit point in the direction perpendicular to the A-scan direction, and a line indicating the automatically set first layer boundary. An intersection point p1' between L and L is specified.

A reference point that is the intersection of a straight line in the A-scan direction that includes a point a predetermined distance t away from the identified point p1' in a direction perpendicular to the A-scan direction and a line L indicating the automatically set first layer boundary. Automatically select p1L.

Similarly, an intersection point p2' between a straight line in the A-scan direction passing through the edit point p2 and a line L indicating the automatically set first layer boundary is specified, and a line perpendicular to the A-scan direction from the specified point p2' is specified. The layer boundary line correction means automatically selects a reference point p2R, which is the intersection of a straight line in the A-scan direction including a point a predetermined distance t away from the line L indicating the automatically set first layer boundary (Fig. 33(B)).

Then, a line indicating the second layer boundary is generated and displayed by connecting the edit point p1 and the reference point p1L, the edit point p1 and the edit point p2, and the edit point p2 and the reference point p2R (FIG. 33(C) ).

At this time, the editing point p1 and the reference point p1L, and the editing point p2 and the reference point p2R may be connected by straight lines, but as in the case where there is only one editing point, curves may be drawn using spline interpolation etc. This is desirable. Then, when drawing a curve using spline interpolation, etc., in order to smoothly generate a line indicating the second layer boundary, the position to the left of p1L on the automatically set line L indicating the first layer boundary (automatically A plurality of reference points p1L1, p1L2, ..., p1Ln are placed on the right side from the position of the edit point p1 on the line L indicating the set first layer boundary to the position beyond p1L in the direction toward the position of the reference point p1L. A plurality of reference points p2R1, p2R2, ..., p2Rn are set at the position (a position beyond p2R in the direction from the position of the edit point p1 on the line L indicating the automatically set first layer boundary toward the position of the reference point p1L). It is desirable that the curve is automatically set and passes through p1 to pLn and p2 to p2Rn (Fig. 33 (E)). Here, the curve to the left of p1L on the line L indicating the automatically set first layer boundary is Multiple reference points p1L1, p1L2, ..., p1Ln, p2Rn were set at positions to the right of the reference points p1L1, p1L2, ..., p2R, but the reference points on the automatically set line indicating the first layer boundary were set. A plurality of points near p1L and p2R may be set as reference points.

The line indicating the second layer boundary, which is the line indicating the new layer boundary, connects the manually corrected part and the manually uncorrected part, in other words, the adjacent edit points of multiple edit points. A part and other parts can be displayed in different display formats, such as a solid line display and a dotted line display, so that they can be distinguished. Also, among the lines indicating the second layer boundary, the part that connects the edit point p1 added by mouse click and the reference point (p1L1 to p1L3) and the part that connects the edit point p2 and the reference point (p2R1 to p2R3) , you can display the same solid line as the manually corrected part, the same dotted line as the part not manually corrected, or a different display, such as a dashed-dotted line. good.

Furthermore, the layer boundary line correction means may accept an operation for selecting whether the set edit point p1 is a discontinuous point between parts connected to the edit point p1 or a continuous point, and the layer boundary line correction means may accept an operation for selecting whether the set edit point p1 is a discontinuous point between the parts connected to the edit point p1, or a continuous point, and the edit point p2 may also be selectable in the same way.

Then, the examiner performs an operation to set a further editing point, and it becomes possible to place a line indicating the second layer boundary at a desired position (FIG. 33(F)).

When setting multiple edit points, as shown in FIG. 26, the first edit point p1 and the last edit point p6 are set at positions on the automatically set line L1 indicating the first layer boundary. However, it is also possible to set the other edit points p2 to p5 at positions different from the position on the automatically set line L1 indicating the first layer boundary.

Furthermore, the set edit points can be individually moved or deleted to arbitrary positions. For example, as shown in Figure 27, if you click p1, p2, and p3 in that order, then select p2 and move it to the end of the dotted arrow, the horizontal direction between adjacent edit points will be a straight line, Alternatively, a curved line is drawn using spline interpolation or the like. In this way, it is also possible to change the horizontal order of edit points.

After that, editing points can be added between them, such as p4 and p5.

After the layer boundary correction is completed, when the examiner presses the OK button on the layer boundary correction screen 4040, all the layer boundary correction results, including the temporarily saved correction results, are saved.

When the reset button is pressed, the layer boundary correction results are reset for all tomographic images 4010 on which layer boundary correction has been performed, and the line returns to the line indicating the first layer boundary set by automatic detection by segmentation.

When the Cancel button is pressed, the state returns to the state before the Layer button was pressed.

When the layer boundary correction is completed and the examiner presses the OK button on the layer boundary correction screen 4040, the control unit 103 reflects the layer boundary correction results on the image displayed in 4020. The timing at which the layer boundary correction results are reflected in the image displayed in 4020 is not limited to this. It may be reflected when the tomographic image (B-scan image) to be displayed is changed, when the layer boundary correction mode is changed, or when the layer boundary to be corrected is changed. Further, it may be reflected every time an operation of adding an edit point or every time a movement operation is completed.

Even while the line indicating the layer boundary is being corrected, the displayed tomographic image can be changed by operating the mouse wheel or the like. If you change the tomographic image to be displayed before pressing the OK button, the correction results at that point are temporarily saved. Then, a line indicating the automatically set first layer boundary is drawn on the newly displayed tomographic image, and the layer boundary to be corrected is displayed as a dotted line. Additionally, if you change the layer boundary to be corrected, the correction results at that point will be temporarily saved, the display of the layer boundary that was the target of correction will be updated from a dotted line to a solid line, and the layer boundary that was newly targeted for correction will be displayed as a solid line. Updated to dotted line display. The display of the edit point of the layer boundary that was the target of correction disappears, and the edit point is displayed on the line that indicates the layer boundary that is the new target of correction due to the change.

Furthermore, when the layer boundary correction mode is changed to the Correction mode, the display is updated to the Correction mode, which will be described later.

(Correction mode)
On the layer boundary correction screen 4040, when the examiner selects the Correction mode and a line indicating a layer boundary to be corrected, as shown in FIG. The line indicating the layer boundary is displayed as a colored solid line to show that it is subject to correction, and multiple edit points p1, p2, ..., pn are displayed on the line indicating the layer boundary. Set at regular intervals.

Therefore, lines indicating layer boundaries to be edited are displayed in a distinguishable manner between the Correction mode and the Drawing mode. Note that the layer boundaries to be edited only need to be displayed in a way that allows them to be distinguished between the Drawing mode and the Correction mode, and are not limited to a combination of solid lines and dotted lines, but may also be a dashed line and a solid line, etc. You can differentiate by

In FIG. 20, ILM is selected as the layer boundary to be corrected. Note that each layer boundary is displayed in a predetermined color, making it possible to identify the layer boundary.

When the layer boundary to be corrected is changed to IS/OS, edit points p1, p2, . . . , pn are displayed at the layer boundary of IS/OS, as shown in FIG. 21.

In the Correction mode, a line indicating the second layer boundary is generated by moving automatically set edit points one by one using a mouse operation.

For example, as shown in FIG. 22, an example will be described in which the examiner wants to correct layer detection at edit points p1, p2, p3, and p4 among layer boundaries automatically detected by segmentation.

When moving edit points p1 to p4, the examiner selects edit point p1 by clicking with the mouse, and drags it vertically, or downward in the example of FIG. 22, to the desired layer boundary position. , a line indicating a second layer boundary passing through the edited point p1 after the movement and edit points other than p1 on the automatically set line indicating the first layer boundary is generated. At this time, it is preferable that editing points other than p1 on the automatically set line indicating the first layer boundary are not moved, but in order to form a gentle line indicating the second layer boundary, edit points near p1 are The editing point may also move. Similarly, editing points p2 to p4 can be similarly moved to change the line indicating the second layer boundary.

In the above example, in the correction mode, the edit point can only be moved in the vertical direction (A-scan direction), but it may also be movable in the left-right direction (direction perpendicular to the A-scan direction).

After the layer boundary correction is completed, when the examiner presses the OK button on the layer boundary correction screen 4040, all the layer boundary correction results, including the temporarily saved correction results, are saved.

When the reset button is pressed, the layer boundary correction results are reset for all tomographic images 4010 on which layer boundary correction has been performed, and the line returns to the line indicating the first layer boundary set by automatic detection by segmentation.

When the Cancel button is pressed, the state returns to the state before the Layer button was pressed.

When the layer boundary correction is completed and the examiner presses the OK button on the layer boundary correction screen 4040, the control unit 103 reflects the layer boundary correction results on the image displayed in 4020. The timing at which the layer boundary correction results are reflected in the image displayed in 4020 is not limited to this. It may be reflected when the tomographic image (B-scan image) to be displayed is changed, when the layer boundary correction mode is changed, or when the layer boundary to be corrected is changed. It may be reflected each time the edit point moving operation is completed.

Even while the line indicating the layer boundary is being corrected, the displayed tomographic image can be changed by operating the mouse wheel or the like. If you change the tomographic image to be displayed before pressing the OK button, the correction results at that point are temporarily saved. Then, a line indicating the automatically set first layer boundary is drawn on the newly displayed tomographic image, and an editing point is displayed at the layer boundary to be corrected. Additionally, if you change the layer boundary to be corrected, the correction results at that point will be temporarily saved, and the edit point of the layer boundary that was the correction target will disappear, indicating the layer boundary that has become the new correction target due to the change. Edit points appear on the line.

Further, when the layer boundary correction mode is changed to Drawing mode, the display is updated to the above-mentioned Drawing mode.

In this embodiment, the layer boundary line correction means operates in a Drawing mode that accepts an operation for setting an edit point at a position different from the automatically set line indicating the first layer boundary, and Although we have described an example that has a Correction mode that allows multiple edit points that are automatically set on a line indicating good.

In the third mode, for example, a line indicating the automatically set first layer boundary is combined with a line indicating the automatically set layer boundary and multiple edit points set at regular intervals on the line. , and is a mode in which the layer boundary line correction means accepts an operation to set an edit point at a position different from the line indicating the first layer boundary.

In that case, the layer boundary line correction means accepts an operation to set the interval between multiple edit points and an operation to delete an edit point set at a position different from the automatically set line indicating the first layer boundary. It may also be used as a configuration. It is also possible to set at least one of the multiple edit points set at regular intervals on the automatically set layer boundary line as a feature of the automatically set layer boundary line. be. Here, the characteristic part of the line indicating the automatically set layer boundary is, for example, an inflection point or an extreme value of the line indicating the automatically set layer boundary.

(Enlarged display during layer boundary correction)
When photographing is performed at a wide angle of view, it is difficult to correct layer boundaries when the entire photographed tomographic image is displayed, as shown in FIG. Therefore, as shown in FIG. 29, it is desirable to be able to correct the layer boundaries while the tomographic image is displayed in an enlarged manner.

For tomographic images, there are operations to change the brightness and contrast to make it easier to identify layer boundaries, so it is possible to make it possible to enlarge and reduce the tomographic image and to change the brightness and contrast. desirable.

For example, as shown in FIG. 30, the operation mode can be configured to be switched using a right-click context menu of the mouse.

When the brightness/contrast/tomographic image mode is selected, by clicking and dragging the mouse, you can change the brightness by moving up and down, and the contrast by moving left and right, and use the mouse wheel to change the B-scan to be displayed. .

When zoom in/palm mode is selected, rotate the mouse wheel forward to zoom in, rotate the mouse wheel backwards to zoom out, click and drag the mouse to zoom in, and the image area becomes larger than the display area. Can move position.

Rather than switching the operation mode, both operations can be performed in combination with keyboard operations.

For example, both operations can be performed by operating the mouse while holding down the shift key and control key.

By holding down the shift key and clicking and dragging the mouse, you can change the brightness by moving up and down, and change the contrast by moving left and right. Change the B-scan to be displayed using the mouse wheel while holding down the Shift key.

While holding down the control key, rotate the mouse wheel forwards to zoom in, and backwards to zoom out. Move the display position when the image area becomes larger than the display area due to enlargement by clicking and dragging the mouse while holding down the control key.

The method for enabling both operations is not limited to this, and may be performed by, for example, button operation, slider bar operation, etc. (not shown).

When the image area becomes larger than the display area due to enlargement, a scroll bar may be displayed, and the display position may be moved by operating the scroll bar.

Enlargement and reduction using the mouse wheel may not only be performed at equal intervals, but also the units of enlargement and reduction may be changed depending on the enlargement magnification.

For example, from 1x to 4x, enlarge or reduce in 0.5 unit increments of 1x, 1.5x, 2x, 2.5x, 3x, 3.5x, 4x, and so on. If the number exceeds the number of times, it may be expanded or reduced one unit at a time by 4 times, 5 times, or 6 times. If the magnification is further increased, the image may be enlarged or reduced by two units.

You can select and switch the display method of the tomographic image from, for example, display according to the display area, display at the actual aspect ratio, or display according to the display area of the tomographic image on the OCTA report screen, so the current display Enlarge or reduce the method while maintaining its aspect ratio.

For example, when switching the display method of the tomographic image from displaying according to the display area, displaying at the actual aspect ratio, or displaying according to the display area of the tomographic image on the OCTA report screen, the magnification rate is set to 1x. It is desirable to reset to .

The magnification factor is superimposed and displayed on the tomographic image so that the current magnification factor can be identified. The display of the enlargement magnification is not limited to this, and although not shown, it may be displayed at a position different from the display area of the tomographic image.

As an enlargement operation, a rectangular area may be drawn by a mouse operation, and the rectangular area may be enlarged to fit the display area.

Furthermore, when the Correction mode is selected on the layer boundary correction screen 4040, it is desirable to update the interval between editing points when enlarging. For example, regardless of the display magnification, by fixing the number of edit points displayed within the display screen before and after enlargement, the interval between the edit points can be updated. Furthermore, the edit points may be updated by determining the interval between the edit points according to the display magnification. Similarly, when zooming out, you can update the spacing between editing points.

On the other hand, when the Drawing mode is selected on the layer boundary correction screen 4040, the relative positional relationship between the editing point and other parts in the B-scan image is maintained before and after enlargement.

Note that when the Correction mode is selected on the layer boundary correction screen 4040, it is also possible to configure the image so that when it is enlarged, the interval between the edit points is not changed, and edit points can be added as in the Drawing mode. .

When printing or outputting by pressing a print button or an output button (not shown), in addition to the explanation on the tomographic image enlargement display screen, the enlarged display state, display position, etc. will also be changed according to the state at the time the button was pressed. , printed, output.

Although the enlarged display at the time of layer boundary correction has been described, the present invention is not limited to this, and the enlarged display may be similarly performed at the time of displaying a tomographic image, measurement of distance between two points, area measurement, etc.

(Screen transition during layer boundary correction)
On the tomographic image enlargement display screen 4000 shown in FIG. 19, if the user double-clicks 4020 to directly change the screen while layer boundaries are being corrected, the user can select whether or not to save the layer boundary correction results. Display a message. For example, there are choices such as saving layer boundary corrections, not saving layer boundary corrections, and canceling direct screen transitions.

While the layer boundary is being corrected, the double-click operation 4020 for direct screen transition may be disabled.

During layer boundary correction, it is desirable to disable the Close button 4030 so that the enlarged tomographic image display screen cannot be closed until the layer boundary correction is completed.

If the Close button 4030 is enabled even while layer boundaries are being corrected, when the Close button is pressed while layer boundaries are being corrected, a message must be displayed that allows the user to select whether or not to save the layer boundary corrections. be.

(OCTA report user operation flow)
With the above configuration, an example of screen transition by user operation in an OCTA report will be described.

If the user wishes to check the details of the OCTA image on the OCTA report screen 1000, double-click 1030 to transition to the enlarged OCTA image display screen 2000.

If it is not possible to determine whether it is an abnormal site or a segmentation error on the OCTA image enlarged display screen 2000, double-click 2020 to transition to the tomographic image enlarged display screen 4000.

On the tomographic image enlargement display screen 4000, the brightness and contrast of the tomographic image are adjusted to make layer boundaries easier to identify, and if there is an error in the segmentation results, the layer boundaries are corrected.

The layer boundary correction results can be easily confirmed using the 4020 OCTA image. To confirm the details of the layer boundary correction results, double-click the OCTA image 4020 to return to the enlarged OCTA display screen 1000.

After repeating these steps and completing the layer boundary correction, the screen returns to the OCTA report screen 1000.

In this embodiment, the screen starts with the screen transition to the OCTA image enlarged display screen 2000, but if it is determined that layer boundary correction is necessary at the time of displaying the OCTA report screen 1000, the tomographic image enlarged display screen 4000 is displayed. You may start from the screen transition to . You may start from the enlarged display screen 3000 of the fundus front image.

When checking the layer boundary correction results, change the display of 4020 to a frontal fundus image such as an EnFace image on the enlarged tomographic image display screen, perform a simple check, and then double-click the frontal fundus image of 4020. , the screen may be changed to an enlarged display screen 3000 of the frontal image of the fundus, and detailed confirmation may be made on the frontal image of the fundus.

(User operation flow for layer thickness map report)
With the above configuration, an example of screen transition by user operation in a layer thickness map report will be described.

If you want to check the details of the layer thickness map on the layer thickness map report screen 5000, select Thickness Map in 5012 and double-click 5010 with the layer thickness map superimposed to display the layer thickness map enlarged display screen. The screen transitions to 6000.

If it is not possible to determine whether it is an abnormal site or a segmentation error on the layer thickness map enlarged display screen 6000, double-click 6020 to transition to the tomographic image enlarged display screen 8000.

On the tomographic image enlargement display screen 8000, the brightness and contrast of the tomographic image are adjusted to make layer boundaries easier to identify, and if there is an error in the segmentation result, the layer boundaries are corrected.

The layer boundary correction results can be easily confirmed using the layer thickness map 8020. To confirm the details of the layer boundary correction results, double-click the layer thickness map 8020 to return to the layer thickness map enlarged display screen 6000.

After repeating these steps and completing the layer boundary correction, the screen returns to the layer thickness map report screen 5000.

In this embodiment, the screen transition starts with the screen transition to the layer thickness map enlarged display screen 6000, but if it is determined that layer boundary correction is necessary at the time of displaying the layer thickness map report screen 5000, the tomographic image is enlarged. The process may start from the screen transition to the display screen 8000. You may start from the enlarged display screen 7000 of the fundus front image.

When checking the layer boundary correction results, change the display of 8020 to a frontal fundus image such as an EnFace image on the enlarged tomographic image display screen 8000, perform a simple check, and then double-click the frontal fundus image of 8020. However, the screen may be changed to an enlarged display screen 7000 of the front image of the fundus, and detailed confirmation may be made on the front image of the fundus.

In this embodiment, an example of screen transition has been described, but the present invention is not limited to this.

For example, the OCTA image enlarged display screen 2000 may be configured so that the display positions of the OCTA image 2010 and the tomographic image 2020 can be switched, such that the tomographic image is displayed at 2010 and the OCTA image is displayed at 2020. . If the display position is changed, displays other than images will also be updated.

Similarly, screen transitions are performed for the enlarged fundus front image display screen 3000, the enlarged tomographic image display 4000, the layer thickness map enlarged display screen 6000, the enlarged fundus front image display screen 7000, and the enlarged tomographic image display screen 8000. First, the display position can be changed.

Further, the display size may be dynamically changed for each display element item.

For example, as shown in FIG. 31, a separator indicated by a dotted line 4050 is displayed on an enlarged tomographic image display screen 4000, and the display size of a tomographic image 4010 and an OCTA image 4020 can be changed by moving this separator with the mouse. It may be changed dynamically.

By dynamically changing the display size, it becomes possible to check the details of the layer boundary correction results without changing the screen.

Similarly, the OCTA image enlarged display screen 2000, the fundus front image enlarged display screen 3000, the layer thickness map enlarged display screen 6000, the fundus front image enlarged display screen 7000, and the tomographic image enlarged display screen 8000 are dynamically displayed. Can be configured to change display size.

Similarly, the OCTA report screen 1000 and the layer thickness map report screen 5000 can be configured so that the display size can be dynamically changed.

(Other examples)
The present invention is also realized by performing the following processing. That is, the software (program) that realizes the functions of the embodiments described above is supplied to a system or device via a network or various storage media, and the computer (or CPU, MPU, etc.) of the system or device reads the program. The processing to be executed also constitutes one form of the present invention.

100 Measurement optical system 101 Stage section 102 Base section 103 Control section 104 Storage section 105 Input section 106 Display section 200 Eye to be examined 209 Photodiode 210 SLO light source 220 OCT light source 231 Line sensor

Claims (11)

a display control means for superimposing a tomographic image of the eye to be examined on the display means and a line indicating the first layer boundary on the tomographic image;
layer boundary line correction means for correcting a line indicating the first layer boundary;
an operation reception means for accepting operations from an operator;
An image processing device having:
The layer boundary line correction means,
an operation of setting a new editing point at a position different from the line indicating the first layer boundary using the operation receiving means in a state where the line indicating the first layer boundary is displayed superimposed on the tomographic image; a first layer boundary line correction mode that receives and generates a line indicating a second layer boundary passing through the new edit point and at least two reference points on the line indicating the first layer boundary;
The operation accepting means receives an operation for moving a first editing point among a plurality of editing points displayed at regular intervals on a line indicating the first layer boundary superimposed on the tomographic image, and moves the first editing point. A second layer boundary passing through the first editing point and a second editing point and a third editing point that are different from the first editing point among the plurality of editing points. a second layer boundary line correction mode that generates a line indicating the
An image processing device comprising: The operation receiving means
The image processing apparatus according to claim 1, wherein the image processing apparatus receives an operation for selecting the first layer boundary line correction mode or the second layer boundary line correction mode. The image processing apparatus according to claim 2, wherein the selecting operation is an operation of switching between the first layer boundary line correction mode and the second layer boundary line correction mode. 4. The image processing apparatus according to claim 2, wherein the selecting operation is performed on a screen displayed on the display means. The image processing apparatus according to claim 4, wherein the display control means displays the screen together with the tomographic image. The display control means indicates a line indicating the first layer boundary in the first layer boundary line correction mode and a line indicating the first layer boundary in the second layer boundary line correction mode, which are to be edited. 6. The image processing apparatus according to claim 1, wherein the image processing apparatus displays the lines in a distinguishable manner. The layer boundary line correction means,
The image processing apparatus according to any one of claims 1 to 6, wherein the operation accepting unit accepts an operation for deleting the editing point. 8. The image processing apparatus according to claim 1, wherein the line indicating the first layer boundary is automatically set. 9. The image processing apparatus according to claim 1, wherein the line indicating the first layer boundary is a line indicating a layer boundary automatically set by segmentation. The display control means,
10. The image processing apparatus according to claim 1, wherein a line indicating the first layer boundary and a line indicating the second layer boundary are displayed in a distinguishable manner. displaying a tomographic image of the eye to be examined and a line indicating the first layer boundary on the display means, superimposed on the tomographic image;
An image processing program comprising: a layer boundary line correction step of correcting a line indicating the first layer boundary,
The layer boundary line correction step
With the line indicating the first layer boundary superimposed on the tomographic image , an operation for setting a new edit point at a position different from the line indicating the first layer boundary is accepted, and the new edit point is a first layer boundary line correction mode that generates a line indicating a second layer boundary passing through the edit point and at least two reference points on the line indicating the first layer boundary;
Accepting an operation to move a first editing point among a plurality of editing points displayed at regular intervals on a line indicating the first layer boundary superimposed on the tomographic image, A line indicating a second layer boundary passing through the edit point and a second edit point and a third edit point that are different from the first edit point among the plurality of edit points is generated. a second layer boundary line correction mode;
An image processing program comprising: a layer boundary line correction step.

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