FR3036607A1 - DEVICE FOR DETECTING A CONDITION OF THE CORNE OF THE EYE AND ASSOCIATED METHOD - Google Patents

Abstract

The invention relates to a device (1) for detecting a state of the cornea (3) of the eye (5) comprising a laser granularity contrast imaging unit (11) having a source (13) of coherent electromagnetic radiation for illuminating the cornea (3) of the eye (5), • a detector (15) of at least one speckle image scattered by the cornea (3) of the eye (5), a speckle image processing unit (17) configured to establish a normalized histogram of the speckle image, and to determine the order of the Gamma law for extrapolating the normalized histogram.

Description

The present invention relates to a device for detecting a state of the cornea of the eye and an associated method.

When examining the eye of an ophthalmologist, the eye usually examines the cornea through the slit lamp's biomicroscopy, to see if it is damaged or not. This technique requires little training, but it does not allow an accurate analysis of the cornea. In particular, this visual examination does not detect weak alterations not visible to the naked eye by the ophthalmologist, which are for example premises of a potentially more serious complication. There are other more sophisticated and comprehensive analytical techniques such as specular non-contact microscopy. However, this technique is complex, expensive and time consuming. Admittedly, specular microscopy makes it possible to collect qualitative (cellular morphology) and quantitative (cell density) information from the endothelial image, but it allows only a small surface area of about 1 mm 2 to be examined and is summarized more often counting corneal cells per unit area. The present invention aims to provide a device for reliably detecting alteration of the cornea at an early stage. For this purpose, the present invention proposes a device for detecting a state of the cornea of the eye comprising a contrast imaging unit with a laser granularity ("speckle imaging unit" in English), presenting - a source of radiation coherent electromagnetic device for illuminating the cornea of the eye, 3036607 2 - a detector of at least one speckle image scattered by the cornea of the eye, - a unit for processing the speckle image ("Speckle image" in English) configured to establish a standardized histogram of the speckle image ("speckle image" in English), and to determine the order of the Gamma law for extrapolating the normalized histogram. Thus, the device for detecting a state of the cornea of the eye according to the invention makes it possible to quickly and efficiently distinguish whether a cornea is healthy or whether a cornea has an impaired state. Indeed, the inventors have found that for a healthy cornea, the light scattered by the cornea comes essentially from the surface of the cornea. In this case, the order of the Gamma law extrapolating the normalized histogram is N = 1. While for a cornea for example poorly hydrated or sick, the cornea reveals a more heterogeneous structure and it is a volume diffusion. In this case, the order of the Gamma law extrapolating the normalized histogram is N> 1, typically N = 2 or N = 4.

The device according to the invention may furthermore have one or more of the following characteristics taken alone or in combination: The coherent radiation source comprises for example a laser. In one aspect, the radiation source is almost monochromatic.

In another aspect, the coherent radiation source is monochromatic, especially in the ultraviolet, the visible or the infrared. The device may further include an optical fiber for delivering radiation from the radiation source to the cornea.

Such detector for at least one speckle image ("speckle image" in English) comprises, for example, a CCD camera. According to yet another aspect, the device comprises a measuring head integrating said detector with at least one speckle image 5 and at least a part of the optical fiber, the output of the optical fiber and said detector being maintained in a position of measure one with respect to the other. The invention also relates to a method for detecting a state of the cornea of the eye using a laser granularity contrast imaging unit ("speckle imaging unit"), in which - the cornea of the eye is subjected to observation with coherent electromagnetic radiation, - at least one speckle image is detected diffused by the cornea of the eye, 15 - the speckle image is exploited in English) by establishing a standardized histogram, - the histogram is extrapolated by a Gamma law, the state of the cornea being associated with a first state if the extrapolated Gamma law is of order N = 1 and the state of the the cornea being associated with a second state if the extrapolated Gamma law is of order N> 1. The coherent electromagnetic radiation comes in particular from a laser. The shimmer image can be taken by a camera with a CCD sensor.

Other advantages and features will become apparent upon reading the description of the invention, as well as the following figures in which: FIG. 1 shows a diagram of a device for detecting a corneal state of the According to one embodiment of the invention, FIG. 2 shows an example of a measured shimmer image, FIG. 3 shows an example of a normalized and extrapolated histogram, and FIG. steps of the method according to the invention.

In the figures, the identical elements are identified by the same references. The following achievements are examples. Although the description refers to one or more embodiments, this does not necessarily mean that each reference relates to the same embodiment, or that the features apply only to one embodiment. Simple features of different embodiments may also be combined to provide other embodiments. In the description, certain elements or parameters can be indexed, such as first element or second element as well as first parameter and second parameter, or first criterion and second criterion, and so on. In this case, it is a simple indexing to differentiate and name elements or parameters or criteria close but not identical. This indexation does not imply a priority of one element, parameter or criterion with respect to another, and it is easy to interchange such denominations without departing from the scope of the present description. FIG. 1 shows an example of a device 1 for detecting a state of the cornea 3 of the eye 5. In this diagram, the eye 5 is shown partially and schematically with, in addition, the iris 7 and the crystalline 9.

3036607 This device comprises a unit 11 for contrast imaging laser granularity ("speckle imaging unit" in English). This laser granularity contrast imaging unit 11 comprises a source 13 of electromagnetic coherent radiation intended to illuminate the cornea 3 of the eye 5. This source 13 of coherent radiation may be a laser or any other source of radiation. spectral purity giving rise to the presence of speckle images ("speckle images"). Typically the source is continuous, but it can also be pulsed provided that the duration of the pulse does not significantly alter the spectral purity, according to the time-frequency relationship. Note that for a standard HeNe laser, the linewidth of the radiation source 13 is of the order of the picometer. Finally, the emission wavelength will generally be between the ultraviolet and infra-red, and we can use an emission around low-cost sources (He-Ne, diodes ...).

Indeed, it is important that the power of the incident radiation is not so great as not to cause damage to the eye during the measurement. For that we will be able to base ourselves on the standards in force in the field of the optical protection of the eye. It should be noted that the incident power can be considerably reduced, since the integration time of the CCD matrix can be increased in parallel. As can be seen in FIG. 1, the source of coherent electromagnetic radiation 13 is not placed directly in front of the lens 5 for the measurement, but an optical fiber 14 is interposed between the coherent radiation source 13 and the eye 5. to guide and route the light emitted by the source 13 to the eye 5. However, alternatively the illumination can also take place directly, without fiber. The laser granularity contrast imaging unit 11 further comprises a detector 15 of at least one speckle image scattered by the cornea of the eye. The detector 15 is for example a capture device 3036607 6 view equipped with a CCD sensor (for "Charge coupled device" in English), as a CCD camera. If necessary, this matrix detector can be linear (recording by rows of pixels), or replaced by any matrix or linear detection system.

The imaging unit 11 further comprises a shimmer image processing unit 17 connected to the detector 15 which transmits the image taken as data. This processing unit 17 is configured to establish a normalized histogram of the speckle image, and to determine the order of the Gamma law, also called Gamma distribution in probability theory, for extrapolating the normalized histogram. According to the embodiment of FIG. 1, the device 1 comprises a measuring head 19 integrating said detector 15 with at least one speckle image and at least a portion of the optical fiber 14. The output of the optical fiber 14 and said detector 15 are held in a measuring position with respect to each other. The value of the detection angle can be chosen almost arbitrarily in the angular range, as well as the illumination angle. In general, for practical reasons, the illumination may be in near-normal incidence, and the detection will be in a direction taken between 15 ° and 45 °. It will be noted that in the case of a radiation source 13 having a width of larger line, it is possible to place a narrow-band interference filter at the output of the radiation source 13 or in front of the detector 15.

Figure 2 shows an example of a recorded shimmer image of approximately 13mm x 13mm size by a CCD sensor. One clearly distinguishes the "granular" character of the image which is a characteristic of the image of 3036607 7 shimmer. It is thus possible to take into account a large part of the cornea 3, to see the entire surface of the cornea 3. From such a speckle image, a histogram is established, that is to say that the for each measured intensity level I, the number of points N (1) for which this level is obtained is evaluated and, by normalizing, the histogram can be converted into a probability density law (pdf - "propability density function In English), which is shown in Figure 3. The measurements can then be extrapolated by a Gamma law: NNi1e (I) - 10 where N is the order of the Gamma law. By extrapolating the measurement points of the normalized histogram, we can therefore determine the order of the Gamma law. In FIG. 3, a first standardized histogram of 15 measurements 50 has been plotted which can be extrapolated by a Gamma law of order N = 1 and a second histogram of measurements 52 which can be extrapolated by a Gamma law of order N = 2. Of course, when the measurements are taken, only one measurement histogram is detected.

In addition, the steps of processing the speckle image, in particular for establishing the normalized histogram and for extrapolating the normalized histogram, are carried out by the processing unit 17 which comprises, for this purpose, calculation means and processing, including a microprocessor and memories loaded with software for this purpose. The inventors have found that when the order of the Gamma law is N = 1 (curve 50), the detected scattering is a surface diffusion from the surface of the cornea 3. In this case, it is a question of a healthy and well hydrated cornea. When the order of the Gamma law is N> 1, for example N = 2, 4, the detected diffusion is a diffusion from the volume of the cornea 3 and more particularly of its heterogeneities.

In other words, the Gamma law provides information on the origin of the scattered light, while quantifying the level of heterogeneity, which is characteristic of the microstructure of the cornea 3. Thus, by subjecting cornea 3 to The eye 5 of a device 1 according to the invention can easily determine any alteration of said cornea 3, even before the known examinations can see corneal damage already greater. This allows a doctor to prescribe preventive treatments to stabilize or improve the state of the cornea 3. It may therefore be reduced by early detection and appropriate treatment the need to resort to heavier interventions for example of the surgical type. An examination with the device 1 according to the invention would also detect the effect of a corrective lens of view on the eye. Indeed, one can quickly detect if the corrective lens does not allow sufficient hydration of the cornea 3, which will allow the ophthalmologist to choose a lens model more suited to the patient's eye, before irreversible damage. are produced.

The invention also relates to a method for detecting a state of the cornea of the eye using a laser granularity contrast imaging unit whose steps are illustrated in FIG. 4. In a first step 100, the cornea 3 of the eye 5 to 5 is subjected to coherent radiation. Then, according to a step 102, at least one speckle image scattered by the cornea 3 of the eye 5 is detected. During a step 104, the speckle image is exploited by establishing a standardized histogram. Finally, in a step 106, the normalized histogram is extrapolated by a Gamma law to determine the order of the Gamma law. The state of the cornea is associated with a first state if the extrapolated Gamma law is of order N = 1 and the state of the cornea is associated with a second state if the extrapolated Gamma law is of order N > 1. It is thus clear that the device according to the invention gives a doctor a valuable preventive detection tool to easily detect even small impairment of the cornea 3. In addition, the detection can be performed non-intrusively and quickly 20 directly on a patient without this being embarrassed. Finally, the application of the detection device and the method associated with biological tissues other than the cornea, such as for example animal or plant tissue, can be extended. Thus, the device or method can be applied to analyze plant material (leaves, plants, roots, stems, etc.) on samples taken or in real time (in fields / crops). The Gamma law governing the shimmer image histogram will be driven by the structure of this biological tissue, a structure that depends on its nature, its state of stress, its environment, and the level of maturation.

Claims (10)

REVENDICATIONS1. A device (1) for detecting a state of the cornea (3) of the eye (5) comprising a laser granularity contrast imaging unit (11) having a source (13) of coherent electromagnetic radiation for illuminating the cornea (3) of the eye (5), - a detector (15) of at least one speckle image scattered by the cornea (3) of the eye (5), - a unit (17) method of processing the speckle image configured to establish a normalized histogram of the speckle image, and to determine the order of the Gamma law for extrapolating the normalized histogram. 2. Device according to claim 1, characterized in that the source (13) of coherent radiation comprises a laser. 3. Device according to claim 1 or 2, characterized in that the source (13) of radiation is almost monochromatic. 4. Device according to any one of claims 1 to 3, characterized in that the source (13) of coherent radiation is monochromatic, especially in the ultraviolet, the visible or in the infrared. 5. Device according to any one of claims 1 to 4, characterized in that it further comprises an optical fiber (14) for conveying radiation from the source (13) of radiation to the cornea (3). 6. Device according to any one of claims 1 to 5, characterized in that said detector (15) of at least one speckle image comprises a CCD camera. 7. Device according to claim 5 taken together with any one of claims 1 to 4, or 6, characterized in that 3036607 12 comprises a measuring head (19) incorporating said detector (15) of at least one shimmering image and at least a portion of the optical fiber (14), the output of the optical fiber (14) and said detector (15) being held in a measuring position with respect to each other. 8. A method of detecting a state of the cornea of the eye with a laser granularity contrast imaging unit, wherein the cornea of the eye is subjected to radiation irradiation. coherent electromagnetic (100), - at least one scattering image scattered by the cornea of the eye (102) is detected, - the speckle image is exploited by establishing a normalized histogram (104), 15 - extrapolating the histogram by a Gamma law (106), the state of the cornea being associated with a first state if the extrapolated Gamma law is of order N = 1 and the state of the cornea being associated with a second state if the Gamma law extrapolated is of order N> 1. 9. The method of claim 8, characterized in that the coherent electromagnetic radiation is from a laser. 10. The method of claim 8 or 9, characterized in that the speckle image is taken by a camera (15) having a CCD sensor. 25