JP6703839B2 - Ophthalmic measuring device - Google Patents

Description

The present invention relates to an ophthalmologic measuring device.

In recent years, utilization of optical coherence tomography (OCT) in the field of ophthalmology is advancing. For example, in addition to the conventional acquisition of B-mode images and three-dimensional images, it is also used for acquisition of frontal images (en-face images) such as C-mode images and shadowgrams, angiographic imaging, and blood flow measurement. The range is expanding.

It is known to apply a Bessel beam to OCT in order to extend the depth of focus (see, for example, Patent Document 1 and Non-Patent Document 1). The Bessel beam is a beam having a conical surface with the propagation axis as a rotational symmetry axis, and the light intensity distribution in the radial direction is expressed by the square of the Bessel function. Since infinite energy is required to generate a true Bessel beam, a beam similar to this is practically used. In this specification, a beam similar to the Bessel beam will be called a Bessel type beam. The Bessel type beam is generated, for example, by acting an axicon lens (conical lens) on a collimated Gaussian beam.

International Publication No. 2012/127880

Kye-Sung Lee and Jannick P. Rolland, “Bessel beam spectral-domain high-resolution optical coherence tomography with micro-opticaxicon providing extended focusing range”, OPTICS LETTERS, Vol. 33, No. 15, August 1, 2008, p. 1696 -p. 1698

In the field of ophthalmology, OCT is used for examination/imaging of various parts represented by the anterior segment (cornea, etc.) and the posterior segment (vitreous, retina, choroid, sclera, etc.). Since the conventional OCT apparatus for ophthalmology has a shallow depth of focus, it is necessary to individually measure each part. For example, it is not possible to perform OCT while focusing on the entire range from the anterior segment to the posterior segment, and OCT that focuses on the anterior segment and OCT that focuses on the posterior segment are sequentially performed. Was there. In addition, the conventional OCT for ophthalmology has a problem that it is not possible to obtain data on the tissue behind a scatterer such as a blood vessel.

One of the objects of the present invention is to provide an ophthalmologic measuring apparatus capable of performing OCT while focusing on a wide range.

The embodiment is an ophthalmologic measuring apparatus that collects data of an eye to be examined using optical coherence tomography (OCT), which includes a first optical system, an optical scanner, a conversion member, a second optical system , a first optical path coupling member , And a switching mechanism . The first optical system splits the light from the light source into measurement light and reference light, irradiates the eye to be inspected with the measurement light through the objective lens, and interferes the return light of the measurement light from the eye to be inspected with the reference light. Detect light. The optical scanner scans the eye to be inspected with measurement light. The conversion member is provided at a position closer to the light source than the optical scanner in the optical path of the measurement light, and converts the measurement light toward the subject's eye from the Gaussian beam to the Bessel beam. The second optical system images the subject's eye through the objective lens. The first optical path coupling member is provided at a position closer to the objective lens than the optical scanner in the optical path of the measurement light, and connects the optical path of the measurement light and the optical path of the second optical system. The switching mechanism switches between a first state in which the conversion member is arranged in the optical path of the measurement light and a second state in which the conversion member is retracted from the optical path.

According to the embodiment, it is possible to focus on a wide range and perform OCT.

The schematic diagram showing an example of the composition of the ophthalmologic measuring device concerning an embodiment. The schematic diagram showing an example of the composition of the ophthalmologic measuring device concerning an embodiment. The schematic diagram showing an example of the composition of the ophthalmologic measuring device concerning an embodiment.

Exemplary embodiments of the present invention will be described in detail with reference to the drawings. The ophthalmologic measuring apparatus of the embodiment is an ophthalmologic apparatus having at least a function of executing OCT. Hereinafter, an ophthalmologic measuring apparatus that combines a swept source OCT and a fundus camera will be described, but the embodiment is not limited to this. For example, the type of OCT is not limited to swept source OCT, and may be spectral domain OCT or the like. Here, the swept source OCT splits light from a wavelength-swept type (wavelength scanning type) light source into measurement light and reference light, and causes return light of measurement light from an object to be inspected to interfere with interference light. Is generated, the interference light is detected by a balanced photodiode or the like, and Fourier transform or the like is performed on the detection data collected according to the wavelength sweep and the scanning of the measurement light to form an image. The spectral domain OCT splits light from a low-coherence light source into measurement light and reference light, interferes the return light of the measurement light from the test object with the reference light to generate interference light, and the spectrum of this interference light. This is a method in which an image is formed by detecting the distribution with a spectroscope and applying Fourier transform or the like to the detected spectral distribution.

The embodiment may or may not have a function of acquiring a photograph (digital photograph) of the eye to be inspected, such as a fundus camera. Further, instead of the fundus camera, a scanning laser ophthalmoscope (SLO), a slit lamp microscope, an anterior segment imaging camera, a surgical microscope, or the like may be provided. The fundus photograph can be used for observing the fundus, setting a scan area, tracking, and the like. Further, the embodiment may have a function of acquiring a digital photograph or the like of the anterior segment.

<Constitution>
As shown in FIG. 1, the ophthalmologic measuring apparatus 1 includes a fundus camera unit 2, an OCT unit 100, and a calculation control unit 200. The fundus camera unit 2 is provided with an optical system substantially similar to that of the conventional fundus camera. The OCT unit 100 is provided with an optical system and a mechanism for performing OCT. The arithmetic and control unit 200 includes a processor. A chin rest and a forehead support for supporting the subject's face are provided at positions facing the fundus camera unit 2.

In the present specification, the “processor” includes, for example, a CPU (Central Processing Unit), a GPU (Graphics Processing Unit), an ASIC (Application Specific Integrated Circuit), and a programmable logic device (eg, SPLD (Simple Dimension), programmable logic device (SPLD). It means a circuit such as Programmable Logic Device, FPGA (Field Programmable Gate Array), or the like. The processor realizes the function according to the embodiment by reading and executing a program stored in a storage circuit or a storage device, for example.

<Ocular fundus camera unit 2>
The fundus camera unit 2 is provided with an optical system and a mechanism for photographing the fundus Ef of the eye E to be examined. Images obtained by photographing the fundus Ef (called fundus images, fundus photographs, etc.) include observation images and photographed images. The observation image is obtained, for example, by shooting a moving image using near infrared light. The captured image is, for example, a color image or monochrome image obtained using visible flash light, or a monochrome image obtained using near infrared flash light. The fundus camera unit 2 may be capable of acquiring a fluorescein fluorescence image, an indocyanine green fluorescence image, a spontaneous fluorescence image, or the like.

The fundus camera unit 2 includes an illumination optical system 10 and a photographing optical system 30. The illumination optical system 10 illuminates the eye E to be inspected with illumination light. The imaging optical system 30 detects the return light of the illumination light from the eye E to be inspected. The measurement light from the OCT unit 100 is guided to the eye E through the optical path in the fundus camera unit 2, and the return light is guided to the OCT unit 100 through the same optical path.

The observation light source 11 of the illumination optical system 10 is, for example, a halogen lamp or an LED (Light Emitting Diode). The light (observation illumination light) output from the observation light source 11 is reflected by the reflection mirror 12 having a curved reflection surface, passes through the condenser lens 13, passes through the visible cut filter 14, and becomes near-infrared light. Become. Further, the observation illumination light is once focused near the photographing light source 15, is reflected by the mirror 16, and passes through the relay lenses 17 and 18, the diaphragm 19, and the relay lens 20. Then, the observation illumination light is reflected by the peripheral portion of the apertured mirror 21 (a region around the apertured portion), passes through the dichroic mirror 46, and is refracted by the objective lens 22 to pass through the eye E (especially the fundus Ef). Illuminate.

The return light of the observation illumination light from the eye E is refracted by the objective lens 22, passes through the dichroic mirror 46, passes through the hole formed in the central region of the perforated mirror 21, and passes through the dichroic mirror 55. The light is reflected by the mirror 32 via the photographing focusing lens 31. Further, this return light passes through the half mirror 33A, is reflected by the dichroic mirror 33, and is imaged on the light receiving surface of the CCD image sensor 35 by the condenser lens 34. The CCD image sensor 35 detects return light at a predetermined frame rate, for example. An observation image of the fundus oculi Ef is obtained when the photographing optical system 30 is in focus on the fundus Ef, and an observation image of the anterior segment is obtained when the focus is on the anterior segment.

The photographing light source 15 is, for example, a visible light source including a xenon lamp or an LED. The light (imaging illumination light) output from the imaging light source 15 is applied to the fundus oculi Ef through the same path as the observation illumination light. The return light of the photographing illumination light from the eye E is guided to the dichroic mirror 33 through the same path as the return light of the observation illumination light, passes through the dichroic mirror 33, is reflected by the mirror 36, and is condensed by the condenser lens 37. An image is formed on the light receiving surface of the CCD image sensor 38.

The LCD 39 displays a fixation target for fixing the eye E to be examined. A part of the luminous flux (fixed luminous flux) output from the LCD 39 is reflected by the half mirror 33A and is reflected by the mirror 32, passes through the photographing focusing lens 31 and the dichroic mirror 55, and then the hole of the perforated mirror 21. Pass the section. The fixation light flux that has passed through the hole portion of the perforated mirror 21 passes through the dichroic mirror 46, is refracted by the objective lens 22, and is projected onto the fundus Ef. The fixation position of the eye E can be changed by changing the display position of the fixation target on the screen of the LCD 39. Instead of the LCD 39, a matrix LED in which a plurality of LEDs are two-dimensionally arranged, a combination of a light source and a variable diaphragm (a liquid crystal diaphragm, etc.), or the like can be used as the fixation light flux generating means.

The fundus camera unit 2 is provided with an alignment optical system 50 and a focus optical system 60. The alignment optical system 50 generates an alignment index used for alignment of the optical system with respect to the eye E to be inspected. The focus optical system 60 generates a split index used for focus adjustment on the eye E to be inspected.

The alignment light output from the LED 51 of the alignment optical system 50 passes through the diaphragms 52 and 53 and the relay lens 54, is reflected by the dichroic mirror 55, and passes through the hole portion of the perforated mirror 21. The light passing through the hole of the perforated mirror 21 passes through the dichroic mirror 46 and is projected onto the eye E to be inspected by the objective lens 22.

The corneal reflection light of the alignment light passes through the objective lens 22, the dichroic mirror 46 and the hole, and a part of the light passes through the dichroic mirror 55, the photographing focusing lens 31, and is reflected by the mirror 32. The light passes through the mirror 33A, is reflected by the dichroic mirror 33, and is projected by the condenser lens 34 onto the light receiving surface of the CCD image sensor 35. Based on the received light image (alignment index image) by the CCD image sensor 35, it is possible to perform manual alignment and automatic alignment similar to the conventional one.

The focus optical system 60 is moved along the optical path (illumination optical path) of the illumination optical system 10 in conjunction with the movement of the imaging focusing lens 31 along the optical path (imaging optical path) of the imaging optical system 30. The reflection rod 67 can be inserted into and removed from the illumination optical path.

When performing focus adjustment, the reflecting surface of the reflecting rod 67 is obliquely provided in the illumination optical path. The focus light output from the LED 61 passes through the relay lens 62, is split into two light beams by the split optotype plate 63, passes through the double-hole diaphragm 64, is reflected by the mirror 65, and is reflected by the condenser lens 66. An image is once formed on the reflecting surface of 67 and reflected. Further, the focus light passes through the relay lens 20, is reflected by the perforated mirror 21, is transmitted through the dichroic mirror 46, is refracted by the objective lens 22, and is projected onto the fundus oculi Ef.

The fundus reflected light of the focus light is detected by the CCD image sensor 35 through the same path as the cornea reflected light of the alignment light. Based on the received light image (split index image) by the CCD image sensor 35, it is possible to perform manual alignment and automatic alignment similar to the conventional one.

The photographing optical system 30 includes diopter correction lenses 70 and 71. The diopter correction lenses 70 and 71 can be selectively inserted in the photographing optical path between the aperture mirror 21 and the dichroic mirror 55. The diopter correction lens 70 is a plus (+) lens for correcting intensity hyperopia, and is, for example, a +20D (diopter) convex lens. The diopter correction lens 71 is a minus (-) lens for correcting intense myopia, and is, for example, a -20D concave lens. The diopter correction lenses 70 and 71 are attached to, for example, a turret plate. The turret plate is formed with a hole for the case where neither of the diopter correction lenses 70 and 71 is applied.

The dichroic mirror 46 combines the optical path for fundus imaging and the optical path for OCT (measurement optical path, measurement arm). The dichroic mirror 46 reflects light in the wavelength band used for OCT (measurement light LS) and transmits light for fundus imaging. In the measurement arm, the light flux limiting member 80, the collimator lens unit 40, the light flux conversion member 81, the lens 82, the optical path length changing unit 41, the optical scanner 42, the OCT focusing lens 43, the mirror 44, and the OCT unit 100 are arranged in this order from the OCT unit 100 side. A relay lens 45 is provided.

The light flux limiting member 80 is provided on the end surface 127a of the optical fiber 127 extending from the OCT unit 100 on the fundus camera unit 2 side or in the vicinity thereof. The light flux limiting member 80 limits the beam size (beam diameter, beam cross-sectional area) of the return light of the measurement light LS from the eye E to be inspected. In this example, the light flux limiting member 80 is provided to limit the beam size of the return light that is condensed by the collimator lens unit 40 toward the end surface 127a. The light flux limiting member 80 is, for example, a diaphragm.

The beam size passing through the light flux limiting member 80 may be constant or variable. In the former case, for example, a fixed diaphragm is used, and in the latter case, for example, a variable diaphragm or a liquid crystal diaphragm is used. In the latter case, the light flux limiting member 80 (variable diaphragm, liquid crystal diaphragm, etc.) is controlled by the control unit 210 described later. The control unit 210 can change the luminous flux limitation range (aperture aperture size and the like) according to a predetermined factor such as a measurement site (particularly of interest) and a depth of focus of the eye E, for example. Further, the user can arbitrarily adjust the luminous flux limitation range while observing a real-time image obtained by preliminary OCT measurement. Alternatively, it is possible to adjust the luminous flux limitation range by analyzing real-time data (signal, image, etc.) obtained by preliminary OCT measurement.

By forming the end surface 127a of the optical fiber 127 (the entrance of the return light of the measurement light LS) sufficiently small, it is possible to impart a light flux limiting function to the end surface 127a. In this case, it is not necessary to separately provide the light flux limiting member.

The collimator lens unit 40 converges the function of converting the measurement light LS emitted from the end face 127a of the optical fiber 127 and passing through the light flux limiting member 80 into a parallel light flux, and the return light of the measurement light LS from the eye E to be examined. It has the effect of making the light incident on the end face 127a (via the light flux limiting member 80).

The light flux conversion member 81 converts the measurement light LS toward the eye E to be inspected into a Bessel type beam. Here, it is assumed that the measurement light LS emitted from the collimator lens unit 40 and incident on the light flux conversion member 81 is, for example, a substantially Gaussian (Gaussian) beam. The Gaussian beam is a beam whose light intensity distribution in the beam cross section is a Gaussian distribution. In this case, an axicon lens can be used as the light flux conversion member 81.

The configuration of the light flux conversion member 81 is not limited to this. For example, a configuration in which a ring aperture (ring slit) and a lens are combined, or a diffractive element (spatial phase modulator, axicon zone plate, etc.) is used, Can be generated.

The beam characteristic of the original measuring light LS is not limited to the Gaussian beam, and for example, the measuring light LS having an arbitrary beam characteristic such as a top hat type beam can be used. The light flux conversion member 81 may have a configuration according to the beam characteristics of the measurement light LS.

The light flux conversion member 81 may be configured to perform the opposite conversion to the return light of the measurement light LS from the eye E to be inspected. Further, it is also possible to configure so that only the measurement light LS traveling toward the eye E to be examined passes through the light flux conversion member 81 and the return light bypasses the light flux conversion member 81. The light flux conversion member 81 is provided closer to the OCT unit 100 side (light source unit 101 side) than the optical scanner 42 in the measurement arm, and is, for example, return light from the eye E to be examined (for example, return light from the fundus Ef). Is arranged at a position where the light is collected again.

The lens 82 propagates the Bessel type beam generated by the light flux conversion member 81. The arrangement of elements constituting the measurement arm is such that the position where the Bessel type beam is generated (the position of the focal point of the light flux conversion member 81) and the position of the optical scanner 42 are in the relationship between the focal point of the lens 82 and the pupil. Is designed.

The optical path length changing unit 41 is movable in the direction of the arrow shown in FIG. 1 and changes the optical path length of the OCT optical path. This change of the optical path length is used for correction of the optical path length according to the axial length of the eye E to be inspected, adjustment of the interference state, and the like. The optical path length changing unit 41 includes, for example, a corner cube and a mechanism for moving the corner cube.

The optical scanner 42 is arranged at a position optically conjugate with the pupil of the eye E to be examined. The optical scanner 42 changes the traveling direction of the measurement light LS that passes through the optical path for OCT. Thereby, the eye E to be inspected is scanned with the measurement light LS. The optical scanner 42 is capable of deflecting the measurement light LS in any direction on the xy plane, and includes, for example, a galvano mirror that deflects the measurement light LS in the x direction and a galvano mirror that deflects the measurement light LS in the y direction.

The OCT focusing lens 43 is moved along the optical axis to change the focus position of the measurement light LS. Since the Bessel type beam is used as the measurement light LS in this embodiment, the depth of focus of the measurement light LS is expanded. For example, in a typical embodiment, the depth of focus is expanded to several tens of times that of a Gaussian beam. In the embodiment in which the depth of focus is sufficiently enlarged, it is not necessary to provide the OCT focusing lens 43.

When the OCT using the Bessel type beam and the OCT using the beam having other characteristics (Gaussian beam, Top hat type beam, etc.) can be selectively applied, when the OCT using the Bessel type beam is performed, the OCT combination is performed. The OCT focusing lens 43 can be inserted into the measurement arm when the focusing lens 43 is retracted from the measurement arm and OCT using a beam having another characteristic is performed. At this time, the characteristics of the beam and the presence/absence of the OCT focusing lens 43 are associated in advance, and the presence/absence of the OCT focusing lens 43 (or the presence/absence of the OCT focusing lens 43) is set based on the setting of the characteristics of the beam (or the setting of the presence/absence of the OCT focusing lens 43). It is also possible to control the beam characteristics). For example, the presence/absence of the light flux converting member 81 (and the light flux limiting member 80 and/or the lens 82) and the presence/absence of the OCT focusing lens 43 are associated in advance to determine the light flux converting member 81 (and the light flux limiting member). It is possible to control so that 80 and/or lens 82) and OCT focusing lens 43 are arranged exclusively on the measuring arm.

<OCT unit 100>
As illustrated in FIG. 2, the OCT unit 100 is provided with an optical system for executing the OCT of the eye E to be inspected. The configuration of this optical system is similar to that of the conventional swept source OCT. That is, this optical system splits the light from the wavelength-swept type (wavelength scanning type) light source into the measurement light and the reference light, and returns the return light of the measurement light from the eye E and the reference light passing through the reference optical path. It includes an interference optical system that generates interference light by causing interference and detects the interference light. The detection result (detection signal) obtained by the interference optical system is a signal indicating the spectrum of the interference light, and is sent to the arithmetic and control unit 200.

The light source unit 101 includes a wavelength-swept (wavelength scanning) light source that changes the wavelength of emitted light at high speed, similar to a general swept source OCT. The wavelength swept light source is, for example, a near infrared laser light source.

The light L0 output from the light source unit 101 is guided to the polarization controller 103 by the optical fiber 102, and its polarization state is adjusted. Further, the light L0 is guided to the fiber coupler 105 by the optical fiber 104 and split into the measurement light LS and the reference light LR.

The reference light LR is guided to the collimator 111 by the optical fiber 110, converted into a parallel light flux, and guided to the corner cube 114 via the optical path length correction member 112 and the dispersion compensation member 113. The optical path length correction member 112 acts to match the optical path length of the reference light LR and the optical path length of the measurement light LS. The dispersion compensating member 113 acts to match the dispersion characteristics between the reference light LR and the measurement light LS.

The corner cube 114 turns back the traveling direction of the incident reference light LR in the opposite direction. The incident direction and the emitting direction of the reference light LR with respect to the corner cube 114 are parallel to each other. The corner cube 114 is movable in the incident direction of the reference light LR, whereby the optical path length of the reference light LR is changed.

1 and 2, the optical path length changing unit 41 for changing the length of the optical path (measurement arm) of the measurement light LS and the length of the optical path of the reference light LR (reference optical path, reference arm) are set. Although both of the corner cubes 114 for changing are provided, only one of the optical path length changing unit 41 and the corner cube 114 may be provided. Further, it is possible to change the difference between the measurement optical path length and the reference optical path length by using an optical member other than these.

The reference light LR passing through the corner cube 114 passes through the dispersion compensating member 113 and the optical path length correcting member 112, is converted by the collimator 116 from a parallel light beam into a focused light beam, and is incident on the optical fiber 117. The reference light LR incident on the optical fiber 117 is guided to the polarization controller 118 to adjust its polarization state, guided to the attenuator 120 by the optical fiber 119 to adjust the light quantity, and guided to the fiber coupler 122 by the optical fiber 121. Get burned.

On the other hand, the measurement light LS generated by the fiber coupler 105 is guided to the optical fiber 127 and emitted from the end face 127a. The measurement light LS emitted from the end surface 127a reaches the collimator lens unit 40 via the light flux limiting member 80 and is converted into a parallel light flux. Further, the measurement light LS that has become a parallel light flux enters the light flux conversion member 81, is converted into a Bessel type beam, and reaches the optical path length conversion unit 41 via the lens 82. Then, the measurement light LS passes through the optical scanner 42, the OCT focusing lens 43, the mirror 44, and the relay lens 45, is reflected by the dichroic mirror 46, is refracted by the objective lens 22, and enters the eye E to be inspected. The measurement light LS is scattered/reflected at various depth positions of the eye E to be inspected. Return light of the measurement light LS from the eye E to be examined travels in the same path as the forward path in the opposite direction, reaches the collimator lens unit 40, and is converted into focused light. The return light that has become the focused light has its beam size limited by the light flux limiting member 80 and enters the optical fiber 127 from the end face 127a. Further, the return light of the measurement light LS is guided to the fiber coupler 105 through the optical fiber 127 and reaches the fiber coupler 122 through the optical fiber 128.

The fiber coupler 122 synthesizes (interferes) the measurement light LS incident via the optical fiber 128 and the reference light LR incident via the optical fiber 121 to generate interference light. The fiber coupler 122 splits the interference light at a predetermined splitting ratio (for example, 1:1) to generate a pair of interference light LC. The pair of interference lights LC are guided to the detector 125 through the optical fibers 123 and 124, respectively.

The detector 125 is, for example, a balanced photodiode (Balanced Photo Diode). The balanced photodiode has a pair of photodetectors that detect the pair of interference lights LC, and outputs the difference between the detection results of these. The detector 125 sends the detection result (detection signal) to a DAQ (Data Acquisition System) 130.

The clock KC is supplied from the light source unit 101 to the DAQ 130. The clock KC is generated in the light source unit 101 in synchronization with the output timing of each wavelength swept within a predetermined wavelength range by the wavelength swept light source. The light source unit 101 optically delays one of the two branched lights obtained by branching the light L0 of each output wavelength, and then determines the clock KC based on the result of detecting the combined light. To generate. The DAQ 130 samples the detection signal input from the detector 125 based on the clock KC. The DAQ 130 sends the sampling result of the detection signal from the detector 125 to the arithmetic and control unit 200.

<Arithmetic control unit 200>
The arithmetic and control unit 200 controls each part of the fundus camera unit 2, the display device 3, and the OCT unit 100. The arithmetic control unit 200 also executes various arithmetic processes. For example, the arithmetic and control unit 200 performs signal processing such as Fourier transform on the spectral distribution based on the detection result obtained by the detector 125 for each series of wavelength scanning (for each A line), and thereby, in each A line. Form a reflection intensity profile. Further, the arithmetic and control unit 200 forms image data by imaging the reflection intensity profile of each A line. The calculation processing therefor is similar to that of the conventional swept source OCT.

The arithmetic and control unit 200 includes, for example, a processor, a RAM (Random Access Memory), a ROM (Read Only Memory), a hard disk drive, a communication interface, and the like. Various computer programs are stored in a storage device such as a hard disk drive. The arithmetic and control unit 200 may include an operation device, an input device, a display device, and the like.

<Control system>
FIG. 3 shows a configuration example of the control system of the ophthalmologic measuring apparatus 1.

<Control unit 210>
The control unit 210 controls each unit of the ophthalmologic measuring apparatus 1. The control unit 210 includes a processor. The control unit 210 is provided with a main control unit 211 and a storage unit 212.

<Main control unit 211>
The main control unit 211 performs various controls. For example, the main control unit 211 includes the photographing focusing lens 31, CCDs (image sensors) 35 and 38, LCD 39, optical path length changing unit 41, optical scanner 42, OCT focusing lens 43, focus optical system 60, reflecting rod 67, It controls the light source unit 101, the reference driving unit 114A, the detector 125, the DAQ 130, and the like. The reference drive unit 114A moves the corner cube 114 provided in the reference optical path. Thereby, the length of the reference optical path is changed.

Further, the main controller 211 can control at least one of the light flux limiting member 80, the light flux conversion member 81, and the lens 82. Examples of control of the light flux limiting member 80 include insertion/retraction of the light flux limiting member 80 with respect to the measurement arm, and change of the light flux limiting range. Examples of control of the light flux conversion member 81 include insertion/retraction of the light flux conversion member 81 with respect to the measurement arm, and selective placement of two or more light flux conversion members. Examples of control of the lens 82 include insertion/retraction of the lens 82 with respect to the measurement arm, selective placement of two or more lenses (lens group), and the like.

In the configuration illustrated in FIG. 3, a moving mechanism 84 is provided for performing the operation of inserting the light flux conversion member 81 and the lens 82 into the measurement arm and the operation of retracting them from the measurement arm. In another embodiment, a mechanism for controlling the light flux limiting member 80, the light flux converting member 81, and the lens 82 can be provided separately, and more generally, the light flux limiting member 80, the light flux converting member 81, and The lenses 82 can be configured to be controlled individually or in any combination by one or more mechanisms.

<Memory unit 212>
The storage unit 212 stores various data. The data stored in the storage unit 212 includes, for example, OCT image data, fundus image data, and eye information. The eye information includes subject information such as a patient ID and name, left/right eye identification information, electronic medical record information, and the like.

<Image forming unit 220>
The image forming unit 220 forms image data of a cross-sectional image of the fundus Ef based on the sampling result of the detection signal input from the DAQ 130. Like the conventional swept source OCT, this processing includes signal processing such as noise removal (noise reduction), filter processing, and FFT (Fast Fourier Transform). The image data formed by the image forming unit 220 is a group of image data (a group of image data formed by imaging a reflection intensity profile on a plurality of A lines (lines in the z direction) arranged along the scan line. A data set including A scan image data).

The image forming unit 220 includes, for example, at least one of a processor and a dedicated circuit board. In the present specification, "image data" may be equated with "image" based on it. In addition, the part of the eye E to be inspected may be identified with the image representing the part.

<Data processing unit 230>
The data processing unit 230 performs image processing and analysis processing on the image formed by the image forming unit 220. For example, the data processing unit 230 executes correction processing such as image brightness correction and dispersion correction. Further, the data processing unit 230 performs image processing and analysis processing on the image (fundus image, anterior segment image, etc.) obtained by the fundus camera unit 2. The data processing unit 230 includes, for example, at least one of a processor and a dedicated circuit board.

The data processing unit 230 can form a three-dimensional image of the fundus oculi Ef by performing an interpolation process of interpolating pixels between the plurality of tomographic images formed by the image forming unit 220. A three-dimensional image is an image in which pixel positions are defined by a three-dimensional coordinate system. As the three-dimensional image, stack data obtained by arranging a plurality of tomographic images along a plurality of scan lines three-dimensionally based on the positional relationship of the scan lines, or voxels obtained by performing interpolation of the stack data and the like. There is data (volume data). A display image is formed by performing rendering (volume rendering, MIP (Maximum Intensity Projection), etc.) on a three-dimensional image. Further, it is possible to set a cross section in a three-dimensional image and display it (multi-section reconstruction: MPR). Further, projection data and shadowgram can be obtained by projecting at least a part of the three-dimensional image in the z direction (A line direction, depth direction). In addition, the data processing unit 230 can execute processing related to OCT angiography and blood flow measurement.

When the OCT using the Bessel type beam and the OCT using the beam having other characteristics (Gaussian beam, top hat type beam, etc.) can be selectively applied, the data processing unit 230 causes the data processing unit 230 to determine the type of the OCT (beam type). Different processing can be performed depending on the characteristics.

For example, in OCT using a Gaussian beam, scanning is performed by focusing on a narrow range in the depth direction. Since this range (anterior eye part, fundus, etc.) is set in advance, the data processing unit 230 executes a predetermined process according to the set range (measurement site). For example, when OCT of the anterior segment is performed, the data processing unit 230 can perform a process of obtaining a corneal curvature distribution, a process of obtaining an anterior chamber depth, a process of obtaining an angle of a corner, and the like.

On the other hand, in OCT using a Bessel type beam, it is possible to perform scanning by focusing on a wide range in the depth direction. The data processing unit 230 can divide the data (signal, image, analysis result, etc.) acquired by OCT into two or more partial data having different depth positions, and can perform different processing on each partial data. ..

The data division includes, for example, a process (segmentation) of dividing the data for each part of the eye E to be inspected. When the data of the range from the cornea to the fundus of the eye E to be inspected is collectively acquired, the data processing unit 230, for example, corresponds to partial data corresponding to the cornea, partial data corresponding to the anterior chamber, and the crystalline lens. Can be divided into partial data corresponding to the vitreous, partial data corresponding to the retina, partial data corresponding to the choroid, and partial data corresponding to the sclera. Further, segmentation into these sub-tissues is also possible (for example, segmentation according to each layer of the retina).

As a typical example, the data processing unit 230 can apply the following processing to each of these partial data: Analyzing partial data corresponding to the cornea to obtain a corneal curvature distribution and a corner angle. ; Analyzing the partial data corresponding to the anterior chamber to determine the anterior chamber depth and angle of angle; Analyzing the partial data corresponding to the crystalline lens to determine the lens thickness (distribution) and opacity distribution; Corresponding to the vitreous Analyzing the partial data to determine the state of vitreous detachment and the state of the vitreous pocket; Analyzing the partial data corresponding to the retina, the retinal thickness (distribution), retinal ganglion cell layer (RNFL) thickness, Obtain retinal ganglion cell layer (GCL) thickness, drusen distribution, size/tilt of optic disc, blood vessel condition (distribution, thickness, etc.), and blood flow information (blood flow velocity, blood flow volume, etc.); The partial data corresponding to the choroid is analyzed to obtain choroidal thickness, the state of blood vessels, and blood flow information; the partial data corresponding to the sclera is analyzed to obtain the state of the sclera.

<User interface 240>
The user interface 240 includes a display unit 241 and an operation unit 242. The display unit 241 includes the display device 3. The operation unit 242 includes various operation devices and input devices. The user interface 240 may include a device, such as a touch panel, in which a display function and an operation function are integrated. Embodiments may be constructed that do not include at least a portion of user interface 240. For example, the display device may be an external device connected to the ophthalmologic measuring device.

<Action/effect>
The operation and effect of the ophthalmologic measuring apparatus according to the embodiment will be described.

The ophthalmologic measuring apparatus of the embodiment collects the data of the eye to be examined using OCT. The ophthalmologic measuring device includes a first optical system, an optical scanner, a conversion member, a second optical system, and a first optical path coupling member. The first optical system splits the light from the light source into measurement light and reference light, irradiates the eye to be inspected with the measurement light through the objective lens, and interferes the return light of the measurement light from the eye to be inspected with the reference light. Detect light. The optical scanner scans the eye to be inspected with measurement light. The conversion member is provided at a position closer to the light source than the optical scanner in the optical path of the measurement light, and converts the measurement light toward the eye to be inspected into a Bessel type beam. The second optical system images the subject's eye through the objective lens. The first optical path coupling member is provided at a position closer to the objective lens than the optical scanner in the optical path of the measurement light, and connects the optical path of the measurement light and the optical path of the second optical system.

In the above example, the first optical system includes an optical system stored in the OCT unit 100 and an optical system forming a measurement arm, and splits the light from the OCT light source 101 into the measurement light LS and the reference light LR. The measurement light LS is emitted to the eye E through the objective lens 22, and the interference light LC between the return light of the measurement light LS from the eye E and the reference light LR is detected by the detector 125. The optical scanner includes an optical scanner 42. The conversion member includes a light flux conversion member 81. The light flux conversion member 81 is provided at a position closer to the light source unit 101 than the optical scanner 42 in the optical path (measurement arm) of the measurement light LS, and converts the measurement light LS toward the eye E to be inspected into a Bessel type beam. The second optical system includes the illumination optical system 10 and the photographing optical system 30, and photographs the subject's eye E through the objective lens 22. The first optical path coupling member includes a dichroic mirror 46. The dichroic mirror 46 is provided at a position closer to the objective lens 22 than the optical scanner 42 in the optical path (measurement arm) of the measurement light LS, and connects the optical path of the measurement light LS and the optical path of the photographing optical system 30 and the like.

According to such an ophthalmologic measuring apparatus, it is possible to perform the OCT scan of the eye to be inspected by using the Bessel type beam. Further, the fundus image and anterior segment image can be acquired by the second optical system coupled to the optical path of the measurement light. Therefore, it is possible to perform OCT scan while focusing on a wide range of the eye to be inspected. Since the depth resolution of OCT is determined by the coherence length of the light source, by applying a Bessel type beam to OCT, both sufficient depth resolution and deep focal depth can be realized.

In addition, the required precision of the focus position adjustment is lower than that of the conventional technique having a shallow depth of focus. Furthermore, for example, if the depth of focus is expanded so that a wide range from the cornea to the fundus of the eye is brought into focus, even the adjustment of the focus position becomes unnecessary. This eliminates the need for an optical element or mechanism for focusing. In addition, an optical element or an attachment (a front lens for measuring an anterior segment) for switching the measurement site is unnecessary. Therefore, the device configuration can be simplified.

Further, the Bessel-type beam has a characteristic (called self-healing property, self-healing property, etc.) that wraps around behind a scatterer located in the traveling direction. Therefore, according to the embodiment, it is possible to acquire the data of the tissue behind the scatterer such as the blood vessel.

In the embodiment, the conversion member may be configured to convert the measurement light directed to the subject's eye from the Gaussian beam to the Bessel beam. In this case, the ophthalmologic measuring apparatus may further include a switching mechanism that switches between a first state in which the conversion member is arranged in the optical path of the measurement light and a second state in which the conversion member is retracted from the optical path of the measurement light.

In the above example, the light flux conversion member 81 configured to convert the measurement light LS traveling toward the eye E to be inspected from the Gaussian beam to the Bessel beam can be applied. Further, the ophthalmologic measuring apparatus 1 is a moving mechanism that switches between a first state in which the light flux conversion member 81 is arranged in the optical path (measurement arm) of the measurement light LS and a second state in which the light flux conversion member 81 is retracted from the measurement arm. 84 is provided.

With such a configuration, it is possible to selectively use OCT using a Gaussian beam and OCT using a Bessel beam. For example, a Bessel-type beam can be applied for wide-range screening, and a Gaussian-type beam can be applied for follow-up of a specific disease.

The ophthalmologic measuring apparatus of the embodiment may include a processing system that processes data acquired by the first optical system (OCT). The processing system is the first range in the depth direction of the eye to be examined, out of the data acquired by the first optical system (OCT) or the processed data thereof in the first state in which the conversion member is arranged in the optical path of the measurement light. Different processing can be performed on the first partial data corresponding to the above and the second partial data corresponding to the second range.

In the above example, the data processing unit 230 detects the detection data (detection signal) acquired by the OCT when the light flux conversion member 81 is arranged in the measurement arm in the first state or the data obtained by processing it ( Signal, image, analysis result, etc.), first partial data corresponding to a first range (eg, cornea) in the depth direction of the eye E, and second partial data corresponding to a second range (eg, retina). Different processing can be performed on.

With such a configuration, it is possible to perform appropriate processing or desired processing for each part of the data acquired over a wide range in the depth direction (for example, for each part of the eye to be inspected).

The ophthalmologic measuring apparatus of the embodiment may include a fixation optical system and a second optical path coupling member. The fixation optical system irradiates the eye to be inspected with a fixation light beam. The second optical path coupling member is provided at a position closer to the objective lens than the optical scanner in the optical path of the measurement light, and connects the optical path of the measurement light and the optical path of the fixation optical system.

In the above example, the fixation optical system includes the LCD 39 and an optical element group that forms an optical path for irradiating the eye E with the fixation light flux output from the LCD 39. The second optical path coupling member includes a dichroic mirror 46. The dichroic mirror 46 is provided at a position closer to the objective lens 22 than the optical scanner 42 in the measurement arm, and connects the measurement arm and the optical path of the fixation optical system. In the above example, the dichroic mirror 46 also serves as the first optical path coupling member and the second optical path coupling member, but the first optical path coupling member and the second optical path coupling member may be separate optical members. Good.

With such a configuration, it is possible to perform OCT using the Bessel type beam while fixing the eye to be inspected.

The ophthalmologic measuring apparatus of the embodiment may include a limiting member that limits the beam size of the return light of the measurement light from the subject's eye. In the above example, the limiting member includes the light flux limiting member 80. With such a configuration, OCT can be performed using a Bessel type beam whose beam size is preferably controlled.

<Modification>
The embodiment described above is merely an example of the present invention. A person who intends to implement the present invention can arbitrarily make modifications (omission, replacement, addition, etc.) within the scope of the gist of the present invention.

It is possible to provide a lens for anterior segment measurement (lens group for anterior segment measurement) or a lens for posterior segment measurement (lens group for posterior segment measurement). Such a lens may be configured as an attachment or may be stored in the device housing (for example, the fundus camera unit 2). The anterior ocular segment measuring lens is arranged on the measurement arm when performing OCT of the anterior segment, and retracted from the measuring arm when performing OCT of the posterior segment. The posterior segment measuring lens is arranged on the measurement arm when performing the OCT of the posterior segment and retracted from the measuring arm when performing the OCT of the anterior segment.

In the above embodiment, it has been described that such an additional lens (additional lens group) is not necessary. However, such an additional lens is considered to be effective when, for example, the depth of focus of OCT using a Bessel type beam is relatively shallow, or when it is desired to adjust the focus position with high accuracy.

1 Ophthalmologic Measuring Device 10 Illumination Optical System 22 Objective Lens 30 Photographing Optical System 42 Optical Scanner 46 Dichroic Mirror 81 Luminous Flux Conversion Member 100 OCT Unit 101 Light Source Unit

Claims (5)

An ophthalmic measurement device that collects data of an eye to be examined using optical coherence tomography (OCT),
The light from the light source is divided into measurement light and reference light, the measurement light is applied to the eye to be inspected through an objective lens, and the return light of the measurement light from the eye to be inspected and the interference light between the reference light A first optical system for detecting
An optical scanner for scanning the eye to be examined with the measurement light,
A conversion member that is provided at a position closer to the light source than the optical scanner in the optical path of the measurement light, and that converts the measurement light toward the subject's eye from a Gaussian beam to a Bessel beam.
A second optical system for photographing the eye to be inspected through the objective lens;
A first optical path coupling member which is provided at a position closer to the objective lens than the optical scanner in the optical path of the measurement light, and which connects the optical path of the measurement light and the optical path of the second optical system ,
An ophthalmologic measuring apparatus comprising: a switching mechanism that switches between a first state in which the conversion member is arranged in the optical path of the measurement light and a second state in which the conversion member is retracted from the optical path . Further comprising a processing system for processing the data acquired by the first optical system,
The processing system includes a first partial data and a second range corresponding to a first range in the depth direction of the eye to be examined, of the data acquired by the first optical system or the processed data thereof in the first state. The ophthalmologic measuring apparatus according to claim 1 , wherein different processing is performed on the second partial data corresponding to. A fixation optical system for irradiating the eye with a fixation light beam,
A second optical path coupling member which is provided at a position closer to the objective lens than the optical scanner in the optical path of the measurement light and which connects the optical path of the measurement light and the optical path of the fixation optical system. The ophthalmic measurement device according to claim 1 or 2 . Ophthalmic measuring apparatus according to any one of claims 1 to 3, further comprising a limiting member for limiting the beam size of the measuring beam of the return beam from the subject's eye. Further comprising one or more lenses arranged in the optical path of the measurement light when performing OCT of one of the anterior segment and the posterior segment of the eye to be examined, and retracted from the optical path when performing OCT of the other. ophthalmic measuring apparatus according to any one of claims 1 to 4, wherein.