JP2008154857A - Apparatus for measuring corneal resistance and corneal resistance measurement electrode used in the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an apparatus for measuring corneal resistance which uses a novel corneal examination method that allows quantitative measurement of corneal impairment instead of conventional qualitative corneal examinations; and also to provide a corneal resistance measurement electrode used in the corneal resistance measurement apparatus. <P>SOLUTION: The corneal resistance measurement apparatus comprises an electrode support 16 having a curved concave surface 18 contacting and covering the surface of the cornea, first and second electrodes 20 and 22 arranged concentrically on the curved concave surface 18 of the electrode support 16 to keep a contact with the surface of the cornea, and a measurement means 14 that measures the electric resistance of the cornea. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a corneal resistance measuring device and a corneal resistance measuring electrode device used therefor, which can perform a novel corneal examination method for quantitatively measuring a corneal disorder.

  As is well known, the cornea is a transparent thin tissue at the center of the eyeball surface, the diameter is about 11 to 12 mm, the thickness is about 0.5 mm at the center, and the peripheral part. It is about 0.7 mm, and is formed of three layers of epithelium, parenchyma, and endothelium in order from the eyeball surface side.

  The outermost epithelium of the cornea forms a thin layer with a thickness of about 0.05 mm, and plays an important role as a barrier that protects the cornea by preventing invasion of foreign substances. It takes oxygen directly from the outside air and supplies it to corneal cells through which blood does not pass. The parenchyma is made up of collagen fibers and occupies most of the cornea thickness, while the endothelium plays a role of a water-regulating pump, supplying nutrient-containing water to the parenchyma that does not pass blood. It is fed in and vice versa, and unnecessary moisture in the substance is taken out.

  If the epithelium, parenchyma, and endothelium that make up the cornea are damaged, the cornea may become turbid. If such turbidity occurs even slightly, external light reaches the retina. It can't be done, and it has a big negative effect on vision. In particular, when the corneal opacity cannot be resolved, the visual acuity can be recovered only by corneal transplantation. Therefore, it is desirable that the corneal disorder is examined and discovered as early as possible.

  By the way, as a corneal disorder test, particularly a corneal epithelial disorder test, a corneal staining test (fluorescein staining) in which fluorescein is used to stain a damaged part of the corneal epithelium has been widely performed. (Refer nonpatent literature 1).

  However, such fluorescein staining is a method in which the stained site is visually inspected using a slit lamp microscope or the like, so that the examination becomes qualitative and the stained site is not visually recognized. Even if there is a failure, it is impossible to obtain a test result indicating that there is a failure. Moreover, since the examiner visually inspects the stained part and independently determines the degree of the failure, there is a problem that the examination result varies depending on the examiner. Thus, with fluorescein staining, it is difficult to objectively quantify the degree of corneal epithelial damage, making it difficult to make a universal assessment.

Edited by Toshio Maruo et al., “Ophthalmology Examination Guide”, first edition, second edition, Kosodo Co., Ltd., December 7, 2004, p. 49

  Here, the present invention has been made in the background of such circumstances, and the problem to be solved is that, instead of the conventional qualitative corneal examination, corneal injury can be measured quantitatively. An object of the present invention is to provide a corneal resistance measuring apparatus capable of performing a novel corneal examination method and a corneal resistance measuring electrode apparatus used in the corneal resistance measuring apparatus.

  In order to solve such a problem, the present invention provides an electrode support having a curved concave surface that is in contact with the corneal surface and covers the corneal surface, and is provided concentrically on the curved concave surface of the electrode support. A corneal resistance measuring device comprising: first and second electrodes that are in contact with the surface; and a measuring unit that measures the electrical resistance of the cornea by passing a current between the first and second electrodes. This is the gist.

  In addition, according to one of the preferable aspects of the corneal resistance measuring apparatus according to the present invention, an opening is provided in the center of the curved concave surface of the electrode support.

  Further, according to another preferred embodiment of the corneal resistance measuring device according to the present invention, the configuration in which an opening is provided in a part of the curved concave surface of the electrode support, and a suction means is connected to the opening, Adopted.

  In addition, the present invention is used in the corneal resistance measuring apparatus as described above, and is provided concentrically on the curved concave surface of the electrode support having a curved concave surface that is in contact with the corneal surface and covers the corneal surface. The gist resistance measuring electrode device having the first and second electrodes in contact with the corneal surface is also the gist thereof.

  Thus, in the corneal resistance measuring device according to the present invention, the first and second electrodes are concentrically arranged on the curved concave surface of the electrode support, and the first and second electrodes are attached at the time of wearing. It comes in contact with the corneal surface of the subject. The electrical resistance of the cornea can be measured by passing an electric current from the measuring means between the first and second electrodes and measuring the electrical resistance.

  More specifically, by passing a weak current from a measuring means such as an electric resistance meter, a weak current flows from one electrode through the cornea to the other electrode, and the electrical resistance value at that time is measured. It can be measured by means. For this reason, when a disorder occurs in the corneal epithelium and the corneal epithelium becomes thin, the current is easily flown through the cornea by the thinned thickness, and the electrical resistance value becomes small. Depending on the magnitude of the resistance value, the degree of corneal injury can be quantified.

  Therefore, according to the present invention, the degree of corneal damage can be quantitatively measured by applying the measured electric resistance value to a calibration curve, grade table or the like prepared in advance. is there. In this way, since the degree of corneal damage can be determined from the measured electrical resistance value, there is no problem that the test result varies depending on the examiner as in the case of fluorescein staining, and the objective test result You will be able to get

  According to one of the preferred embodiments of the corneal resistance measuring device according to the present invention, since the opening is provided in the central portion of the curved concave surface of the electrode support, the cornea is instilled from the opening. It can be done. This eliminates the need to remove and reattach the electrode support before and after instillation, and it is also possible to measure the drug effect of the eyedrops in real time while performing instillation. It is possible to grasp the effect of the above safely and quickly without imposing an excessive burden on the patient.

  Further, according to another preferred embodiment of the corneal resistance measuring device according to the present invention, the suction means is attached to the opening provided in a part of the curved concave surface. When mounting on a person's cornea, the suction means generates a negative pressure between the curved concave surface and the corneal surface, thereby improving the adhesion between the curved concave surface and the corneal surface. It is difficult to come off from the corneal surface, and if tears, liquids, or bubbles remain between the curved concave surface and the corneal surface, they are effectively eliminated, and therefore the resistance value of the cornea is stable. As a result, the accuracy of resistance measurement can be advantageously increased.

  Furthermore, according to the corneal resistance measuring electrode device according to the present invention used in the corneal resistance measuring apparatus as described above, the electrical resistance of the cornea can be measured very advantageously, and the corneal disorder can be measured more effectively. It becomes possible.

  Hereinafter, in order to clarify the present invention more specifically, embodiments of the present invention will be described in detail with reference to the drawings.

  First, FIG. 1 schematically shows a longitudinal sectional view illustrating a typical embodiment of a corneal resistance measuring device according to the present invention. In FIG. 1, the corneal resistance measurement device 10 includes an electrode device 12 for measuring the electrical resistance of the cornea, and an electrical resistance meter 14 as a measuring unit to which the electrode device 12 is connected. It is configured.

  Specifically, the electrode device 12 is mainly composed of a contact lens type electrode support 16 formed using a resin material such as acrylic resin, and the curved concave surface 18 of the electrode support 16 is It is designed to have a base curve having a diameter that is the same as or slightly smaller than the cornea to be inspected and a curvature radius that is substantially the same as that of the cornea.

  Further, as apparent from FIGS. 1 and 2, the curved concave surface 18 of the electrode support 16 has a first electrode 20 on the outer peripheral side thereof, and a predetermined value radially inward from the first electrode 20. The second electrode 22 is disposed on the inner peripheral side separated by a distance from the curved concave surface 18 of the electrode support 16.

  More specifically, each of the first and second electrodes 20 and 22 is formed of a gold wire that achieves high conductivity, and a part of the gold wire is exposed as shown in FIG. As shown, the ring-shaped electrodes 20 and 22 are embedded in the electrode support 16 so as to have a ring shape in which a part of the ring is cut out, and so as to be concentric. . In the present embodiment, the first electrode 20 has a diameter (outer diameter) of about 5 mm to 12 mm and a width of about 0.5 mm to 1.5 mm, while the second electrode 22 has a diameter (outer diameter). ) About 3 mm to 5 mm and a width of about 0.5 mm to 1.5 mm.

  In addition, the ring-shaped ends 20a and 22a in which a part of the ring in the first and second electrodes 20 and 22 is cut off pass through the inside of the electrode support 16 respectively. 16 has a substantially bottomed cylindrical shape integrally provided on the convex surface 24 of the electrode support 16 and rises outward (upward in FIG. 1) so that its tip is exposed from the convex surface 24. The lead wires 28 and 30 in the casing 26 are respectively connected to one end of the lead wires 28 and 30.

  Further, as shown in FIG. 1, connectors 32 and 32 are integrally connected to the other ends of the lead wires 28 and 30 opposite to the electrode connection side, respectively. The electrode device 12 is connected to the electric resistance meter 14 via

  Then, the corneal resistance measuring apparatus 10 having the above-described configuration is used to inspect a disorder in the cornea, for example, as shown in FIG. 3, first, the electrode support 16 first touches the surface of the subject's cornea 34. It will be mounted so as to cover. By this mounting, the first and second electrodes 20 and 22 provided on the curved concave surface of the electrode support 16 are separated from each other by a predetermined distance from the peripheral portion (outer peripheral portion) side and the central portion of the cornea 34 surface. It is brought into contact with the (inner periphery) side. Then, a weak current (eg, 1 to 10 μA) is passed through the cornea from the first electrode 20 side with the electric resistance meter 14, and the electrical resistance value (impedance) is measured, whereby the electrical resistance of the cornea is reduced. The measured numerical value is used to quantitatively detect the presence or absence of the cornea and the degree of the damage.

  As described above, by using the corneal resistance measuring device 10 having the above-described structure, it is possible to easily and simply measure the electrical resistance of the subject's cornea. Then, for example, when a cornea having a corneal epithelium damaged and having a thin corneal epithelium is measured, an electric current easily flows, and an electric resistance value smaller than that of a normal cornea is measured. As described above, according to the present invention, it is possible to quantitatively measure the degree of corneal injury based on the magnitude of the measured electrical resistance value.

  Therefore, according to the corneal resistance measuring apparatus 10 of the present embodiment, the degree of corneal injury can be quantitatively measured by applying the measured electrical resistance value to a calibration curve, a grade table, or the like prepared in advance. It can be done. In addition, since the degree of corneal damage can be determined from the measured electrical resistance value, there is no problem that the test results vary depending on the examiner as in the case of fluorescein staining, and objective test results can be obtained. Be able to get. Furthermore, by simply comparing the obtained electrical resistance value with the normal value or the previous measurement value, it is possible to perform therapeutic effects and follow-up observations by medication, and to evaluate the safety of drugs, etc. Therefore, it is possible to evaluate them more simply and with higher accuracy.

  In addition, the corneal resistance measuring device 10 of the present embodiment is configured so that the outer shape of the electrode support 16 is a contact lens type and can be mounted by mounting a contact lens. It is extremely small.

  In addition, since the curved concave surface 18 of the electrode support 16 is not provided with any openings or through-holes, it is advantageously prevented that the corneal surface is dried during the measurement of electrical resistance. It is a structure to obtain.

  4 and 5 schematically show another embodiment of the corneal resistance measuring device (specifically, an electrode device for measuring corneal resistance advantageously used in the corneal resistance measuring device) according to the present invention. Is shown in In addition, regarding each embodiment shown in FIG.4 and FIG.5, in order to make the understanding easy, in the site | part made into the structure similar to the said embodiment shown in FIGS. In order to avoid duplication of explanation, explanation of the parts having the same number will be omitted.

  First, the corneal resistance measurement device 36 shown in FIG. 4 is composed of an electrode device 38 and an electric resistance meter 14 as in the measurement device 10 of the previous example, in which the electrode support of the electrode device 38 is supported. The body 40 includes an annular mounting portion 40a that is mounted on the corneal surface and covers a predetermined portion of the corneal surface, and a cylindrical holding portion 40b.

  More specifically, the electrode support 40 of the electrode device 38 is made of a resin material such as an acrylic resin to secure the strength of the mounting portion 40a for mounting on the corneal surface and the electrode support 40 itself and to handle the fingers during handling. The mounting portion 40a has a curved concave surface 42 with a radius of curvature corresponding to the corneal shape to be inspected, and the curved concave surface. A central portion of 42 is a circular opening 44 having an inner diameter (about 1 to 4 mm) smaller than that of the second electrode 22. On the other hand, the holding portion 40b is a hollow cylindrical body that integrally extends from the inner peripheral portion of the mounting portion 40a toward the outside (upward in FIG. 4). The straight surface 46a extends continuously from the opening 44 of the portion 40a, and the tapered surface 46b expands outward from the straight surface 46a. In other words, the electrode support 40 of the electrode device 38 is provided with a funnel-shaped opening (through hole) that penetrates the central portion thereof in the axial direction.

  Accordingly, when the electrode device 38 according to the present embodiment is mounted on the cornea surface, the central portion of the cornea is exposed to the atmosphere by the opening (through hole) provided in the electrode support 40 of the electrode device 38. Thus, even in a state in which it is worn, medication can be performed through eye drops or the like from such an opening (through hole).

  For this reason, it is possible to continuously measure the electrical resistance of the cornea while performing instillation (medication), and thus the effect of instillation can be obtained in real time. In addition, in order to confirm the effect by instillation, it is not necessary to once remove the electrode device 38 attached to the cornea before instillation and to attach it again after instillation. As described above, according to the electrode device 38 of the present embodiment, the effect of the eye drop treatment can be grasped safely and quickly without imposing an excessive burden on the patient.

  On the other hand, the corneal resistance measurement device 48 shown in FIG. 5 is also composed of the electrode device 50 and the electric resistance meter 14 as in the measurement device 10 of the previous example. The contact lens type electrode support 52 mounted on the surface of the cornea, and a suction tool 54 as a suction means extending outward from the center of the electrode support 52 are configured.

  More specifically, the electrode support 52 of the electrode device 50 has a curved concave surface 18 in which the first and second electrodes 20 and 22 are embedded, as in the embodiment shown in FIG. A small circular opening 56 penetrating in the thickness direction (vertical direction in FIG. 5) is formed in the portion. And this opening part 56 is made into the attachment hole for attaching the suction tool 54 so that it may mention later.

  On the other hand, the suction tool 54 attached to such an opening 56 includes a suction tool body 58, a suction tube 60, and a joint 62, and is a suction formed of a flexible resin material. The tube 60 is integrated by connecting one end in the length direction to the suction tool main body 58 and the other end to the joint portion 62. The suction tool main body 58 has a structure like a syringe composed of a cylinder 58a and a piston 58b. By pulling the piston 58b outward with respect to the cylinder 58a, negative pressure is applied to the suction tube 60. It can be generated.

  And in this embodiment, the suction tool 54 of the above-mentioned structure inserts the cylindrical one end of the joint part 62 in the opening part (attachment hole) 56 of the electrode support body 52 of the electrode apparatus 50, It is integrally connected to the electrode support 52.

  Therefore, after the electrode device 50 according to the present embodiment is brought into contact with the corneal surface, the piston 58b of the suction tool main body 58 is pulled outward, whereby a negative pressure is generated between the curved concave surface 18 and the corneal surface. Adhesion between the concave surface 18 and the corneal surface is improved, and when tears, liquids, or bubbles remain between the curved concave surface 18 and the corneal surface, they are effectively excluded.

  For this reason, the electrode support 52 is not easily displaced with respect to the movement of the eye during the examination. Therefore, the electrode support 52 can be easily stabilized at the correct position, thereby stabilizing the resistance value of the cornea. Thus, the accuracy of resistance measurement can be advantageously increased.

  The exemplary embodiments of the present invention have been described in detail above. However, the embodiments are merely examples, and the present invention is limited in any way by specific descriptions according to such embodiments. It should be understood that it is not interpreted.

  In the electrode devices 12, 38, and 50 of the above example, each of the curved concave surfaces 18, 42, and 18 of the electrode support bodies 16, 40, and 52 has one ring type as the first electrode 20 and the second electrode 22. The electrodes are arranged, but the first electrode 20 and the second electrode 22 are arranged such that the first and second electrodes 20 and 22 are arranged concentrically, and the first and second electrodes are arranged concentrically. 20 and 22 may be constant, for example, the outer first electrode 20 may be a plurality of point electrodes, and the inner second electrode 22 may be a single or a plurality of point electrodes. It is also possible to configure.

  In the above example, the outer first electrode 20 is a ring electrode having a diameter (outer diameter) of 5 mm to 12 mm, while the inner second electrode 22 is a diameter (outer diameter) of 3 mm to 5 mm. 6 and 7, the outer first electrode 64 is a ring electrode having a diameter of about 5 mm, while the inner second electrode 66 is In addition, a circular electrode having a diameter of about 3 mm can be used, and by adopting such a configuration, it is possible to efficiently measure the central portion, which is an important part of the cornea.

  Furthermore, in the present invention, as illustrated, the electrical resistance of the cornea can be advantageously measured by arranging the pair of electrodes 20 and 22 concentrically on the curved concave surface (corneal mounting surface). However, the size of the first and second electrodes 20, 22 and the distance between the electrodes are not limited to the illustrated sizes, and are appropriately set according to the shape of the cornea of the subject. To get.

  Further, in the above example, a constant weak current is allowed to flow from the first electrode 20 side on the outer peripheral side, but it is also possible to cause a current to flow from the second electrode 22 side on the inner peripheral side. Of course it is possible. That is, the first electrode 20 may be connected to the + terminal side of the electric resistance meter 14 or connected to the − terminal side.

  In the above example, the electric resistance meter 14 is employed as the measuring means. However, as long as an electric current is passed between the first and second electrodes and the electric resistance between these electrodes can be measured. There is no particular limitation. The electrical resistance can be measured by flowing a constant current, or by applying a constant voltage and flowing a current between the first and second electrodes. Alternatively, an alternating current may be passed.

  Furthermore, the outer shape of the electrode support body only needs to have a curved concave surface corresponding to the cornea, and is not limited to the illustrated one. Further, the size of the electrode support is not particularly limited. In addition to the electrode having the same or slightly smaller diameter as that of the cornea as in the embodiment shown in FIG. As shown, the upper and lower eyelids 70 and 70 have a diameter that covers a part or most of the sclera so that the electrode support 68 can be fixed on the eyeball by pressing the outer edge of the electrode support 68. You may do it.

  Furthermore, in the above example, as the first and second electrodes 20 and 22, gold electrodes that realize high conductivity were employed, but other than gold electrodes, electrodes such as platinum electrodes and silver electrodes are used. It is also possible to do.

  In addition, although not enumerated one by one, the present invention can be carried out in a mode with various changes, modifications, improvements, etc. based on the knowledge of those skilled in the art. It goes without saying that any one of them falls within the scope of the present invention without departing from the spirit of the present invention.

  Some examples of the present invention will be shown below to clarify the present invention more specifically. However, the present invention is not limited by the description of such examples. Needless to say.

  First, as a corneal resistance measuring device, an electrode device (12) having a shape as shown in FIGS. 1 and 2 and an electric resistance meter (14) (digital tester CUSTOM CDM-28D manufactured by Custom Corp.) were prepared. The contact lens-type electrode support (16) was made of acrylic resin and had a diameter and a base curve corresponding to the later-described rabbit cornea shape. The first and second electrodes (20, 22) provided on the curved concave surface (18) of the electrode support (16) are both gold electrodes, and their outer diameters (diameters) are each 12 mm. The width was 4.8 mm and the width was 0.8 mm and 0.6 mm.

  On the other hand, a rabbit eye was used as the subject to be examined. As a control, normal eyes were employed, while eyes having corneal disorders were prepared as follows. That is, the filter paper soaked with 1N NaOH solution was brought into contact with the cornea surface of the rabbit eye for 5 seconds to damage the corneal epithelial layer (barrier layer).

  Then, after the electrode device (12) prepared as described above is mounted on the surface of a normal rabbit cornea or a damaged cornea, the electrode device (12) is connected to an electric resistance meter (14), A weak direct current is passed from the ohmmeter (14) between the first and second electrodes (20, 22), and the electrical resistance of the rabbit cornea is changed every 5 minutes for 40 minutes (normal eye) or 50 minutes ( Impaired eye), measured. And while showing the obtained result in following Table 1, the graph which plotted the electrical resistance value of the measured cornea with respect to measurement time was shown in FIG.

  As is apparent from the results of Table 1, the normal cornea of the rabbit (O in FIG. 9) has a stable electrical resistance value of around 10 MΩ, while the rabbit cornea has impaired corneal epithelium. The cornea (● in FIG. 9) is about half that of 5 MΩ, and it can be seen that the electrical resistance value is small. This is due to the fact that the thickness of the corneal epithelial layer (barrier layer) is reduced by NaOH as compared with the normal case, and current flows easily.

  Thus, by measuring the electrical resistance of the cornea using the corneal resistance measuring device according to the present invention, the degree of corneal function failure can be obtained as a numerical value, and that numerical value is applied to a calibration curve or the like prepared in advance. Thus, it can be easily quantified. In this example, the eye of a rabbit was adopted as the subject to be examined, but it is presumed that the corneal disorder or corneal dysfunction can be quantified in the human eye as well. Moreover, even when there is a disorder other than the epithelium, that is, when there is a disorder in the parenchyma or endothelium, it is assumed that the degree of the disorder can be detected. Therefore, according to the corneal resistance measuring device according to the present invention, it is possible to accurately and objectively grasp the degree of corneal damage, and further, the degree of recovery of corneal damage due to medication and treatment and changes over time. It is.

It is longitudinal cross-sectional explanatory drawing which shows the outline of what concerns on a typical example of the corneal resistance measuring apparatus according to this invention, and is a figure equivalent to the II cross section in FIG. It is explanatory drawing which shows the curved concave surface of the electrode support body in the corneal resistance measuring apparatus shown by FIG. It is a partial cross-section explanatory drawing which shows the state which mounted | wore the cornea with the electrode support body of the corneal resistance measuring apparatus shown by FIG. FIG. 6 is a cross-sectional explanatory view corresponding to FIG. 1, showing another example of a corneal resistance measuring device (specifically, a corneal resistance measuring electrode device) according to the present invention. FIG. 7 is a partially cutaway cross-sectional explanatory view corresponding to FIG. 1 and showing still another example of a corneal resistance measuring device (specifically, a corneal resistance measuring electrode device) according to the present invention. It is sectional explanatory drawing which shows the other example of the electrode in the corneal resistance measuring apparatus according to this invention. It is explanatory drawing which shows the curved concave surface of the electrode support body in the corneal resistance measuring apparatus shown by FIG. It is explanatory drawing which shows the other example of the electrode support body in the corneal resistance measuring apparatus according to this invention, Comprising: It is a partial cross-section explanatory drawing which shows the state with which the cornea was mounted | worn. It is the graph which plotted the electrical resistance value of the cornea measured in the Example with respect to measurement time.

Explanation of symbols

10, 36, 48 Corneal resistance measuring device 12, 38, 50 Electrode device 14 Electrical resistance meter 16, 40, 52, 68 Electrode support 18, 42 Curved concave surface 20, 64 First electrode 22, 66 Second electrode 28 , 30 Lead wire 34 Cornea 44 Opening portion 46 Inner peripheral surface 54 Suction tool 56 Opening portion 58 Suction tool body 60 Suction tube 62 Joint portion 70 Eyelid

Claims (4)

An electrode support having a curved concave surface in contact with the corneal surface and covering the corneal surface;
First and second electrodes concentrically provided on the curved concave surface of the electrode support, and in contact with the corneal surface;
A measuring means for passing an electric current between the first and second electrodes and measuring an electrical resistance of the cornea;
A corneal resistance measuring device comprising:   The corneal resistance measuring device according to claim 1, wherein an opening is provided in a central portion of the curved concave surface of the electrode support.   The corneal resistance measuring device according to claim 1 or 2, wherein an opening is provided in a part of the curved concave surface of the electrode support, and a suction means is connected to the opening. An electrode device used in the corneal resistance measuring device according to any one of claims 1 to 3, wherein the electrode support has a curved concave surface that is in contact with the corneal surface and covers the corneal surface, and the electrode. An electrode device for measuring corneal resistance, comprising: first and second electrodes concentrically provided on a curved concave surface of a support and in contact with the corneal surface.

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