WO2013017337A1 - Imaging device for recording an image of a retina of an eye, imaging method, and computer program product - Google Patents

Abstract

The invention relates to an imaging device (1), in particular a fundus camera (1) for recording an image of a predefinable image area (11) of a retina (111) of an eye (10). To form an illumination beam (50), an illumination source (400) with a first light-emitting body (40) for a first light beam of a first wavelength (λ₁) and a second light-emitting body (41) for a second light beam of a second wavelength (λ₂) is provided, wherein the illumination source (400) is configured and arranged in such a way that the retina (111) of the eye (10) can be exposed to the illumination beam (50) via an objective lens (410) in the image area (11). To detect a return beam (60) reflected from the image area (11) of the retina (111), a sensor device (300) with a first radiation-sensitive sensor (31) and a second radiation-sensitive sensor (32) is also provided. According to the invention, a light polarizer (44), in particular a linear light polarizer (44), is provided between the illumination source (400) and the objective lens (410) in a beam path of the illumination beam (50), and a polarizing beam splitter (30) is provided between the objective lens (410) and the sensor device (300) in a beam path of the reflected return beam (60), such that the first radiation-sensitive sensor (31) and the second radiation-sensitive sensor (32) can be exposed to differently polarized return beams (60). In addition, the invention relates to an imaging method for recording an image of a retina (111) of an eye (10), and to a computer program product for controlling an imaging device (1) and for carrying out an imaging method.

Description

 Receiving device for receiving a retina of an eye,

Recording procedure, as well as computer program product

The invention relates to a recording device, in particular fundus camera for recording a predefinable image area of a retina of an eye, a recording method for receiving a retina of an eye, and a computer program product for controlling a recording device and for performing a recording method by means of a

 Receiving device according to the preamble of the independent claims.

For the imaging of the fundus (fundus oculi), so-called fundus cameras have long been known in the art

various embodiments known. Corresponding devices are described in detail, inter alia, in WO 2007/104165 A1, EP 0 608 516 Blöder of CH 699 479 B1. On the one hand, light must enter the eye through the narrow pupil of the eye and, on the other hand, the light reflected from the fundus of the eye must be registered by means of a recording camera. In this case, in the devices known from the prior art, the illumination path and the receiving path must be guided locally separately, since otherwise the light reflected from the cornea and the eye lens outshines the light reflected from the fundus. Since the pupil diameter of the eye is only a few millimeters, the division of the illumination and recording path is a decisive factor for the quality of the images obtained. Furthermore, this division

crucial for the tolerance against lateral displacement of the

Recording device relative to the optical axis of the eye. In commercial fundus cameras, the illumination and imaging beam path is usually made coaxial, for example, the circular area of the pupil is divided into an outer annular area for illumination and a circular central area for recording. However, this coaxial division of the available pupil opening requires that the eye with respect to the optical axis of the

Imaging device must be positioned very accurately. This is especially important if the image is to be taken without drug dilatation of the pupil, since then the pupil diameter e.g. less than 4mm. With a small pupil diameter, the

Lighting ring should be positioned exactly in the center of the pupil, otherwise only a part of the light will be in the eye and the recording will be faint or even unusable. This lateral offset also allows reflexes from the cornea to enter the camera and outshine the light from the fundus.

For a better understanding of the problems with the fundus cameras known from the prior art, in particular in the analysis of the blood flowing through the blood vessels of the retina, reference is made below to FIGS. 1 and 2. Fig. 1 shows a schematic representation of an eye 10 with inner

Blood vessels. The inner blood vessels 21 in the eye 10 run almost parallel to the surface of the retina 1 1 1. The inner blood vessels 21 are very clearly visible, as shown in FIG. 2, partially covered by the transparent nerve fiber layer 24, which in turn is covered by the inner nerve

Boundary membrane (membrana limitans interna "ILM") 23 is limited to the glass body 100. The inner boundary membrane 23 is a few μm thick basal layer, which is the visible light of microscopically small

Irregularities speculatively backscattered. By "specular reflection" the skilled artisan generally understands a reflection, as it takes place, for example, on a mirror, that is, in a specular reflection, light incident from a single direction is also reflected and traced back to another single direction essentially the well-known reflection law of classical optics, that the angle of incidence of the light is equal to the angle of reflection of the light.

In the case of the superficial blood vessels 21, the inner boundary membrane 23 follows the cylindrical shape of the blood vessels 21 and forms a "back" on which irradiated light 60, as shown in FIG. 2, is reflected back speculatively and as the mid-vessel reflex 25 on most fundus images a well-known from the prior art fundus camera is visible.

Since the reflection from the boundary membrane 23 is speculative, like the

One skilled in the art, substantially maintaining any polarization of the illuminating light. The known fundus cameras are designed for maximum light output of the light reflected from the retina and therefore use polarizing filters which are arranged so that the specular reflex of the retina is maximally detected and at the same time the internal reflexes of the fundus camera are suppressed. For many measurements, for example, in the measurement of hemoglobin in the inner blood vessels 21 of the retina 1 1 1, however, the central specular reflex 25 is disturbing because it outshines the actually measured, the desired information-carrying beam 26 from the interior of the blood vessel 21 and an evaluation, for example according to a Lambert-Behr model, makes impossible. The object of the invention is therefore to provide a recording device, in particular a fundus camera and a measuring method available, in which the problems described above with the over-radiating central reflex are largely avoided. It's also one

Object of the invention to provide a computer program product for controlling a recording device and / or for performing a recording method and for the evaluation of measurements according to a recording method of the invention.

The objects of the invention solving these objects are characterized by the independent claims of the respective category.

The dependent claims relate to particularly advantageous

Embodiments of the invention.

The invention thus relates to a receiving device, in particular

Fundus camera for recording a predefinable image area of a retina of an eye. To form an illumination beam is a

Lighting source with a first luminous element for a first

Luminous radiation of a first wavelength and a second luminous body provided for a second luminous radiation of a second wavelength, wherein the illumination source is configured and arranged such that the retina of the eye can be acted upon by the illumination beam via an object optics in the image area. For detecting a reflected radiation from the image area of the retina, a sensor device with a first radiation-sensitive sensor and a second radiation-sensitive sensor is further provided. According to the invention, an illumination polarizer, in particular a linear illumination polarizer, is arranged between the

Illumination source and the object optics in a beam path of the

Illuminating beam, as well as a polarizing beam splitter between the object optics and the sensor device provided in a beam path of the reflected return radiation, so that the first radiation-sensitive sensor and the second radiation-sensitive sensor with differently polarized return radiation can be acted upon.

The inventive combination of the illumination polarizer, in particular a linear illumination polarizer with the

For the first time, the polarizing beam splitter has succeeded convincingly in separating the otherwise overshadowing central reflex from the image of the interior of the blood vessels of the retina, even if both image signals are not guided away from the eye. This means that, for example, the position of a blood vessel on the retina can be precisely measured, and at the same time the necessary information from the interior of the blood vessel can be obtained exactly, for example by evaluating the corresponding light intensities from the blood vessel with the aid of a Lambert-Beer model. The essence of the invention is that the two signals are separated via two different, preferably mutually largely orthogonally polarized signals, i. the beam splitter divides the return radiation into two sub-beams polarized perpendicular to one another and leads them to the first one

radiation-sensitive sensor and the second radiation-sensitive sensor each separately for detection. In another embodiment, while the

 Illumination polarizer also a polarizer for generating circularly polarized luminous radiation, in particular visible light, or else, e.g. a polarizer for generating elliptically polarized

Luminescent radiation, in particular visible light. The same applies of course to the polarizing beam splitter, which may be a linearly polarizing beam splitter and / or a circularly polarizing beam splitter and / or also an elliptically polarizing beam splitter.

Essential for the invention is that the combination of

Illumination polarizers and polarizing beam splitter to the

inventive effect, namely the sufficient separation, ie a sufficient separation of the measurement information carrying radiation from the blood vessels and the otherwise all-overshadowing specular backscattered central reflex leads.

In this case, the first wavelength is particularly different than the second wavelength. Thus, e.g. the first wavelength can be used to illuminate the Au background, preferably a

long-wavelength light, preferably a red light is used, since this is more pleasant for patients after prolonged irradiation. For the

Measuring and analysis of the blood in the blood vessel of the retina, a short-wave light is advantageously used in practice, which is then operated pulsed for the actual measurement.

For guidance and exact adjustment of the line of sight of the eye of the

Patients is particularly preferably a fixation mark provided and configured such that the image area in the region of a predetermined position, in particular in the region of the optic nerve head on the retina is selectable, to compensate for ametropia of the eye, an assembly along an optical axis of an objective lens is advantageously displaced.

In addition, the invention relates to a recording method for receiving a prescribable image area of a retina of an eye by means of a recording device of the present invention, wherein a

Lighting beam is formed by providing an illumination source with a first luminous body for a first luminous radiation of a first wavelength and a second luminous body for a second luminous radiation of a second wavelength. In this case, the illumination source is designed and arranged such that the retina of the eye is exposed to the illumination beam via an object optics in the image area, and a reflected from the image area of the retina back radiation is detected by a sensor device with a first radiation-sensitive Sensor and a second radiation-sensitive sensor is provided. According to the invention, an illumination polarizer, preferably a linear illumination polarizer between the illumination source and the

Object optics in a beam path of the illumination beam, as well as a polarizing beam splitter between the object optics and the

 Sensor device provided in a beam path of the reflected return radiation, so that the first radiation-sensitive sensor and the second radiation-sensitive sensor is subjected to differently polarized return radiation. As already explained, the first wavelength is preferably chosen to be different from the second wavelength, wherein the second luminous body is operated advantageously pulsed and in practice usually a

Fixation mark is provided and configured such that the

Viewing the eye is guided so that the image area in the region of a predetermined position, in particular in the optic nerve head on the retina is selected, in particular a refractive error of the eye can be adjusted by an assembly of the recording device along an optical axis of an objective lens becomes.

The reverberation is particularly preferably divided by the beam splitter into two sub-beams polarized perpendicular to one another, whereby a radiation intensity reflected specularly on the eye can be directed to more than 95%, in particular more than 95%, of the radiation-sensitive sensor.

It can, in particular with the help of a suitable

Data processing system and an inventive

Computer program product from a measurement signal of the first

radiation-sensitive sensor and a measurement signal of the second radiation-sensitive sensor, a sum signal are generated, for example, corresponds to a retinal image and / or a measurement signal of the first radiation-sensitive sensor and a measurement signal of the second radiation-sensitive sensor can also be a difference signal which contains largely specular reflections of a surface of the retina.

In practice, a chemical and / or physical property of the eye, in particular of the retina and / or of the blood in the interior of the blood vessel is often determined with the aid of a Lambert-Beer method.

As is well known, Lambert-Behr's Law provides the

Concentration of an absorbant depending on the transmitted light and therefore finds widespread use in photometry. The absorbance, ie the absorbance of a material for radiation of wavelength λ when a light beam passes through a cuvette, e.g. through a

Blood vessel of thickness d follows the law:

Ε _λ = -lg (Ii / I ₀ ) = e _x -cd

Wherein, depending on the normalization or system of units used, Ig is the decadic or natural logarithm, the intensity of the transmitted light, l ₀ the intensity of the incident (incident) light, c the concentration of the absorbing substance in the liquid, and ε _λ as the decadic extinction coefficient (often also as a spectral

Absorption coefficient) at the wavelength λ and d is the layer thickness of the irradiated body.

 It goes without saying that in a method according to the invention, the evaluation of the signals from the blood vessels can take place according to a Lambert-Behr model, but does not have to follow such a model. Rather, it is quite possible that one

Inventive method also refers to other models for the evaluation of the measurement signals from the eye. Finally, as already mentioned, the invention relates to a

Computer program product for controlling a receiving device and for carrying out a purchase procedure.

The invention will be explained in more detail below with reference to the schematic drawing. Show it

Fig. 1: schematic representation of an eye with internal blood vessels;

Fig. 2: blood vessel of the eye gem. Fig. 1 under transparent

 Nerve fiber layer;

3 shows an embodiment of an inventive arrangement. 4: spatial arrangement of the iris and pupil opening of the iris of the eye;

FIG. 5 shows the prior art technique of pupil separation by T. Weitzel et al .;

FIG. 6: Reduction of the intensity of the corneal reflex according to FIG

 Invention. To remedy the problem of central specular reflex 25 is a new by the invention, as generally explained above

Imaging system proposed that largely eliminates the central reflex, so the specular reflex 25.

Reference to the schematic Fig. 3 to Fig. 6, a particularly preferred embodiment of an inventive arrangement will now be discussed in somewhat greater detail.

The illumination source 400 of the system comprises a first luminous element 40, which emits a first luminous radiation, preferably light of a first wavelength λϊ, and a second luminous element 41 of a second

Luminous radiation, preferably emitted light of a second wavelength λ ₂ . in the 3, the luminous bodies 40, 41 are designed as light-emitting power LEDs LED 40, 41.

The LED 40 (e.g., Philips Lumilex LXML-PD01 -0040 or similar) emits, for example, in the red wavelength region with a middle first one

Wavelength λι of 627 nm and is used to illuminate the

 Eye 10 eye background during patient adjustment.

The LED 41 (Philips Lumiled LXML-PM01 -0100 or similar) emits preferentially but not necessarily in a different wavelength range, for example in the green wavelength range with a mean second wavelength λ ₂ of 530 nm and becomes the measurement recording in the specific embodiment according to FIG. 3 lightning-fast, so pulsed operated. The green light with a wavelength of about 530 nm is particularly preferred because the main absorption line of the hemoglobin is about 530 nm, so that its measurement is of course particularly facilitated. Of course, the luminous bodies 40, 41 may, of course, in principle be any suitable luminous bodies. Particularly advantageously, the luminous bodies 40, 41 can also be designed as a laser, for example.

The light emitted by the LEDs 40 and 41 light is combined by the dichroic beam splitter 42 into a common beam path and focused by means of lens 43 on the Einlenkspiegel 45, wherein on the mirror 45 an intermediate image of the two LED filament 40, 41 is formed. The intermediate image of the LED filament 40, 41 is focused by the objective lens 46 by means of the illumination beam 50 on the cornea 13 of the examined eye 10, passes through the pupil 14 and lens 12 of the eye 10 and illuminates the retina 1 1 1 of the eye 10 in the image area. 1 1 . A pinhole 47 thereby limits the illumination beam 50 and thus determines the size of the image area 11. Typically this will be for this application Image area 1 1 on the retina 1 1 1, for example, about 6 mm

Diameter used.

The location of the image area 11 is selected by the viewing direction of the patient's eye 10. Externally or system internally provided, from the prior art known per se fixation marks, for reasons of

Clarity in Fig. 3 are not shown, the viewing direction of the eye 10 of the patient in the desired position. For the described application, an image area 1 1 in the vicinity of the visual nerve head 20 is selected on the retina 1 1 1, from which the larger inner blood vessels 21 go out, so that a sufficiently high evaluable signal intensity is generated.

A portion of the backscattered by the retina 1 1 1 light is collected by the eye lens 12 and the cornea 13 and imaged by the objective lens 46 as an intermediate image of the retina 1 1 1 in the plane of the aperture 47. The reticle interchangeable is again through the field lens 49 as

 Reflection 60 on the light-sensitive sensors 31 and 32 shown.

To compensate for any defective vision of the eye 10, for example, the internal assembly 35 of the system may be displaced relative to the objective lens 46 along its optical axis OA. A sharp picture of the

Retina 1 1 1 arises on the radiation-sensitive sensors 31 and 32 always exactly when the pinhole 47 in the plane of

Retina sunscreen lies.

The sensors may e.g. Digital camera systems known per se, such as e.g. CMOS cameras, CCD cameras, point or line photodetectors or any other suitable light sensitive detector.

According to the present invention, a linear polarizes

Illumination polarizer 44, the illumination beam 50 containing the of the two luminous bodies 40, 41 emitted light such that the polarization axis of the illumination beam 50 upon appearance on the

Cornea 13 of the eye to be examined 10 e.g. according to the representation, it is horizontal. As is known to the person skilled in the art, the human cornea 13 is a birefringent element, that is to say an optical element which splits a light bundle into two sub-beams polarized perpendicularly to one another, wherein its so-called slow axis averages approximately 5 degrees nasally,

according to the presentation runs down. The representation of the horizontally polarized light of the illumination beam 50 thus passes the cornea 13 almost parallel to the slow axis and remains largely linearly polarized after penetrating the cornea 13.

The linearly polarized light radiates through the eye lens 12 and strikes the retina 1 1 1. There, a first part 25 of the light 60 is speculatively reflected at the boundary membrane 23, and a second part 26 penetrates deeper

 Layers of the retina 1 1 1 and is backscattered from the retina 1 1 1 and / or from the interior of the blood vessel 21.

The specularly reflected light 25 essentially retains its linear polarization with a representation of the horizontal polarization direction, while the scattered light 26 is depolarized more or less.

If part of the light 26 penetrates a blood vessel 21, it will

wavelength dependent, e.g. absorbed by the various blood components according to Lambert-Beer's law.

The polarization-maintaining light 25 and the scattered light 26 are reflected back out of the eye 10 and, as previously described, imaged by the lenses 46 and 49 on the photosensitive sensors 31, 32 which are sensitive to light here. A polarizing beam splitter 30 shares the received Reflection 60 in two Pola sationskomponenten, so that the specular reflected light 25 is imaged for example more than 95% on the sensor 32, and the depolarized light 26, for example, about 50% to 50%, ie approximately each half the sensors 31 and 32 are displayed. Thus, an image of the retina 1 1 1 is generated on the sensor 31, which is largely free of disturbing central reflexes of the surfaces of the blood vessels 21 and thus can be used in a conventional manner for the analysis of blood levels, for example, but not necessary using a method according to Lambert-Beer. By means of suitable electronics and / or digital image processing, as known per se from the prior art, then a summation image of the two sensors 31, 32 can be created, which is a conventional one

Retinal image corresponds and is a measure of the total re-radiated light intensity. Also by means of known electronics and / or digital

 Image processing can also be a difference image of the two sensors 31, 32 are created, the main, i. for the most part only speculative

Reflections of the surface of the retina 1 1 1 includes. These

Image information can then be used to analyze materials, agents, contaminants, trace elements, etc. that are located between the retinal surface and the corneal surface, ie, in the vitreous body 100, eye lens 12, anterior and posterior chamber, or cornea 13.

To reduce the light intensity of the originating from the cornea 13 light reflection is in previous fundus cameras usually a

concentric pupil separation according to FIG. 4 or FIG. 5, which in principle can likewise be used in combination with an arrangement according to the invention, wherein in an arrangement according to the invention However, particularly preferably an arrangement or a method according to FIG. 6 is used, as will be explained below.

FIG. 4 shows a possible relative spatial arrangement of the iris 15 of the eye 10, which has a pupil opening 14. The illuminating beam is arranged annularly on the outer edge of the pupil, while the light 61 to be detected leaves the eye 10 in the center of the pupil.

FIG. 5 shows that of T. Weitzel et al. proposed method of

Pupil separation. Here, an illumination beam 52 is imaged as a point on the pupil plane of the eye 10. The eye pupil is optically divided into two crescent-shaped areas, one of which is for the

 Illumination beam 52, the other for the imaging beam 62 is responsible. The spatially separated entrance and exit pupils are in the

Imaged imaging beam, where then blocked with a suitable aperture of the corneal reflex. In an inventive structure is particularly preferred the

 Arrangement of FIG. 6 used. The Einlenkspiegel 45 is mounted in a conjugate image plane to the corneal plane and thus simultaneously acts as a projected aperture 53 for the separation of the illumination beam 52 from

Imaging beam 63. In this arrangement, the ratio of pupil area for the imaging beam to pupil area for the illumination beam is substantially greater than in the methods shown in FIGS. 4 and 5. This results in a correspondingly greater light output with the same pupil size.

Claims

claims

1 . Aufnahmeevornchtung, in particular fundus camera for receiving a predetermined image area (1 1) of a retina (1 1 1) of an eye (10), wherein for forming an illumination beam (50) a

 An illumination source (400) having a first luminous body (40) for a first luminous radiation of a first wavelength (λ 1) and a second luminous body (41) for a second luminous radiation of a second luminous radiation

Wavelength (λ ₂ ) is provided, and the illumination source (400) is configured and arranged such that the retina (1 1 1) of the eye (10) with the illumination beam (50) via an object optics (410) in the image area (1 1 ) is acted upon, and for detecting a of the image area (1 1) of the retina (1 1 1) reflected back radiation (60) further comprises a sensor device (300) having a first

 radiation-sensitive sensor (31) and a second

 radiation-sensitive sensor (32) is provided thereby

 in that an illumination polarizer (44), in particular a linear illumination polarizer (44), is arranged between the

 Illumination source (400) and the object optics (410) in one

 Beam path of the illumination beam (50), and a polarizing beam splitter (30) between the object optics (410) and the

 Sensor device (300) in a beam path of the reflected

 Reverse radiation (60) is provided, so that the first

 radiation-sensitive sensor (31) and the second

 radiation-sensitive sensor (32) with differently polarized return radiation (60) can be acted upon.

2. Recording device according to claim 1, wherein the first wavelength (λ ^ is different from the second wavelength (λ ₂ ).

3. Recording device according to claim 1 or 2, wherein the second

Luminous body (41) is pulsed operable.

4. Aufnahmevornchtung according to one of claims 1 or 2, wherein for guiding the line of sight of the eye (10) a fixation mark is provided and configured such that the image area (1 1) in the region of a predetermined position, in particular in the region of the optic nerve head (20). on the retina (1 1 1) is selectable, and / or wherein the

 Compensation of ametropia of the eye (10), an assembly along an optical axis (OA) of an objective lens (46) is displaceable.

5. Recording device according to one of the preceding claims, wherein the beam splitter (30) divides the return radiation (60) into two mutually perpendicular polarized partial beams.

6. recording method for receiving a predetermined image area (1 1) of a retina (1 1 1) of an eye (10) by means of a

A pickup device according to any one of claims 1 to 5, wherein an illumination beam (50) is formed by a illumination source (400) having a first luminous body (40) for a first luminous radiation of a first wavelength (λ ^ and a second luminous body (41) for a second illumination of a second wavelength (λ ₂ ) is provided, and the illumination source (400) is configured and arranged so that the retina (1 1 1) of the eye (10) with the illumination beam (50) via an object optics (410) in Image area (1 1) is applied, and a of the image area (1 1) of the retina (1 1 1) reflected reflected radiation (60) is detected by a

 Sensor device (300) with a first radiation-sensitive sensor (31) and a second radiation-sensitive sensor (32) is provided, characterized in that a

 Illumination polarizer, preferably a linear illumination polarizer (44) between the illumination source (400) and the object optics (410) in a beam path of the illumination beam (50), and a

polarizing beam splitter (30) between the object optics (410) and the sensor device (300) in a beam path of the reflected Reflection (60) is provided, so that the first radiation-sensitive sensor (31) and the second

 radiation-sensitive sensor (32) with differently polarized return radiation (60) is acted upon.

A pickup method according to claim 6, wherein said first wavelength (λ 1) is selected different from said second wavelength (λ ₂ ).

8. Recording method according to claim 6 or 7, wherein the second

 Illuminant (41) is operated pulsed.

9. Recording method according to one of claims 6 to 8, wherein a

 Fixation mark is provided and configured such that the

Viewing direction of the eye (10) is guided so that the image area (1 1) in the region of a predetermined position, in particular in the region of the optic nerve head (20) on the retina (1 1 1) is selected and / or wherein a defective vision of the eye ( 10) by moving an assembly of the pickup device (1) along an optical axis (OA) of an objective lens (46).

10. Recording method according to one of claims 6 to 9, wherein the

 Reflection (60) is divided by the beam splitter (30) in two mutually perpendicular polarized partial beams.

1 1. Recording method according to one of claims 6 to 10, wherein a specular reflected at the eye (10) radiation intensity is directed to more than 90%, in particular more than 95% on the radiation-sensitive sensor (32).

12. Recording method according to one of claims 6 to 1 1, wherein from a measurement signal of the first radiation-sensitive sensor (31) and a measurement signal of the second radiation-sensitive sensor (32) a sum signal is created, which corresponds to a retinal image.

13. Recording method according to one of claims 6 to 12, wherein from a measurement signal of the first radiation-sensitive sensor (31) and a measurement signal of the second radiation-sensitive sensor (32) is a difference signal is created, the largely specular reflections of a surface of the retina (1 1 1) includes.

A recording method according to any one of claims 6 to 13, wherein a chemical and / or physical property of the eye,

in particular the retina (1 1 1) and / or a blood in the interior of the blood vessel (21) by means of a Lambert-Beer method is determined.

Computer program product for controlling a recording device according to one of claims 1 to 5 and / or for carrying out a recording method by means of a recording device according to one of claims 6 to 14.