RU2336014C1 - Method of intraocular pressure measurement through eyelid (versions) and related device (versions) - Google Patents

Abstract

FIELD: medicine; ophthalmology.

SUBSTANCE: method of intraocular pressure measurement through eyelid is based on static eyelid deformation by support loading with two flanges and simultaneous dynamic eyeball deformation through eyelid with free-falling rod at subsequent measurement of rod time-motion function parameters. Measurement is performed twice with different static eye loadings of support. Dynamic eyeball deformation can also be carried out by counter-balanced rod, thus rod gets speed due to acceleration unit. Besides, acceleration of rod can be due to magnetic field. In case of multiple dynamic eye deformation with increasing eye pressure force at the moment of occurrence of sclera or cornea deformation wave, intraocular pressure value is registered, then increasing dynamic eye deformation is stopped. Device used for intraocular pressure measurement contains eye pressure sensor and rod motion velocity sensor.

EFFECT: application of this group of inventions provides detection of intraocular pressure through eyelid regardless of geometrical and physical characteristics.

13 cl, 4 dwg

Description

The invention relates to the measurement of physical quantities and can be used to measure intraocular, intracranial and other pressure.

A known method for determining intraocular pressure Maklakov, based on the installation on the human eye of a certain load with a flat surface. The area of contact of the cargo with the surface of the eye (the size of the punching) determines the value of intraocular pressure.

When using this method, it is necessary to use local anesthesia. The accuracy of the method is influenced by the radius of curvature of the cornea of the eye and the stiffness of the cornea, which is taken into account in the method as the average for all people, but with age it increases and in all people, naturally, is different.

A known method for measuring intraocular pressure through the eyelid, RF patent No. 98101607, authors Piletsky G.K. etc., taken as a prototype, based on the static deformation of the eyelid by the load of the support with two protrusions and the dynamic deformation of the eyeball through the eyelid, the body freely falling relative to the support, with the subsequent determination of the amount of elastic deformation of the surface of the eyeball closed by the eyelid, according to the parameters of the displacement function falling body in time.

When using this method, the rigidity of the sclera of the eye affects the accuracy of the measurement result, which varies with the age of a person, and with an increase in intraocular pressure. The error of the method depends on the perpendicularity of the fall of the rod to the surface of the eyes, the reaction of the eye muscles to the impact of the falling rod, the thickness and rigidity of the eyelid.

A device for measuring intraocular pressure through the eyelid, RF patent No. 98101607, authors Piletsky G.K. etc., taken as a prototype, consisting of a housing with a support with two protrusions placed in it with the possibility of limited reciprocating movement, designed to create a constant predetermined load, an element of the eyeball deformation through the eyelid in the form of a freely falling rod installed in the cavity supports with the possibility of its free fall in the guides under the action of its own weight to create an impact load, the rod holder in its original upper position, the linear converter is moved I rod designed as a generator associated with the electromagnetic coil.

When using this method, the rigidity of the sclera of the eye affects the accuracy of the measurement result, which varies with the age of a person, and with an increase in intraocular pressure. The error of the method depends on the perpendicularity of the fall of the rod to the surface of the eyes, the reaction of the eye muscles to the impact of the falling rod, the thickness and rigidity of the eyelid.

The problem to which the invention is directed is to create a method for measuring intraocular pressure through the eyelid, in which the measurement result does not depend on the conditions of the stem fall, the radius of curvature of the cornea of the eye, the rigidity of the cornea, the accuracy of the device on the surface of the eyelid of the eye and the thickness of the eyelid.

The technical result is aimed at creating a device that allows you to determine through the eyelid intraocular pressure, regardless of the geometric and physical characteristics of the eye covering the eyelid and stiffness of the sclera.

In the proposed method and device, the technical result is achieved by using the following nodes: rod counterweight, rod acceleration unit, additional eye pressure unit, eye support pressure sensor.

The analysis of the prior art, including a search by patents and scientific and technical sources of information containing information about analogues of the claimed invention, allows us to establish that the applicant has not found technical solutions characterized by features identical to all existing features of the claimed invention. The difference from the list of identified analogues of the prototype made it possible to identify a set of essential (with respect to the technical result perceived by the applicant) distinctive features in the claimed object set forth in the claims.

Therefore, the claimed invention meets the requirement of "novelty" under the current law.

Information about the fame of the distinguishing features in the totality of the characteristics of the known technical solutions with the achievement of the same as that of the claimed device, there is no positive effect. Based on this, it was concluded that the proposed technical solution meets the criterion of "inventive step".

The method of measuring intraocular pressure and a device for its implementation are illustrated by drawings, where

figure 1 presents a typical characteristic of the fall of the rod on the surface of the eye through the eyelid.

Figure 2 presents a typical characteristic of changes in stiffness of the sclera of the eye from intraocular pressure.

Figure 3 presents the device for measuring intraocular pressure (option 1).

Figure 4 presents the device for measuring intraocular pressure (option 2).

When using the method for determining intraocular pressure, presented in the prototype, in which the stem falls on the surface of the eyelid and the eyes below it, a typical characteristic of the change in the rate of fall of the stem when it falls on the eye is determined, which is presented in figure 1. It is easy to identify four zones on the characteristic:

- zone I describes the change in the speed of the rod as it approaches the surface of the eyelid;

- zone II describes the change in the speed of the rod during its penetration into the eyelid of the eye;

- III describes the change in the speed of the rod when it penetrates the eye, protected by the eyelid;

- IV describes the change in stem velocity when it bounces from the eye.

The prototype uses such an area of zone III to determine the intraocular pressure, which is as independent as possible from the influence of the eyelid on the measurement accuracy, but this leads to another measurement error, namely the reaction of the sclera of the eye to a change in the intraocular volume.

It is known that with an increase in intraocular pressure, the scleral stiffness sharply increases, as shown in FIG. It is also known that the sclera and cornea with an increase in intraocular pressure can stretch in a very limited range. In adults, this figure does not exceed 5% and will decrease with age. In children, the sclera and cornea are very elastic and can be very stretched. In figure 2, curve 1 describes the change in stiffness of the sclera of an average adult, curve 2 describes the change in stiffness of the sclera of an average elderly person, and curve 3 describes a change in stiffness of the sclera of a child.

From the above it follows that in adults and older people it is extremely difficult to accurately determine intraocular pressure by dynamic methods at its high values, and in static methods, such as by Maklakov, etc., the measurement error increases.

When the stem hits the eye, two dynamic processes occur in the eye - the propagation of the deformation wave inside the eye and the propagation of the surface (elastic) deformation wave of the sclera and cornea of the eye. The first process propagates with the speed of sound in the liquid and takes a reaction time to a disturbance of about 20-40 μs, and as can be seen in Fig. 1, it does not have a noticeable effect on the rebound of the stem from the eye, since the process of interaction of the stem with the eye takes about 1000 μs . The second process develops as an oscillation of the membrane with a certain rigidity, and it is this process that determines the reaction of the eye to the penetration of the rod into the eye. In this regard, the authors argue that all dynamic methods for measuring intraocular pressure directly depend on the rigidity of the sclera and cornea, the rigidity of which depends on intraocular pressure. At the same time, an error is introduced into these methods caused by an increase in the stiffness of the sclera with the age of a person.

The authors propose the following method for measuring intraocular pressure, in which a correction is made to the measurement result for changes in stiffness of the sclera or cornea and physical parameters of the eyelid. To do this, it is enough to measure intraocular pressure twice by any dynamic method, with a support known for different static pressure on the eye.

Based on the foregoing, the method for measuring intraocular pressure is as follows: a static deformation of the eyeball with a support with two protrusions is created by an external specific effect (for example, the operator’s hands), then the eyeball is dynamically deformed through the eyelid by a body freely falling relative to the support, with subsequent determination of the elastic deformations of the surface of the eyeball closed by the eyelid. Then, with a support with two protrusions, a static deformation of the eyeball is performed with a large pressure relative to the initial value, and the dynamic deformation of the eyeball through the eyelid by the body freely falling relative to the support is carried out again, with the subsequent determination of the elastic deformation of the surface of the eyeball closed by the eyelid. The two obtained parameters of the function of moving a freely falling body in time determines the value of intraocular pressure. In this case, the static pressure of the support should be greater than the intraocular pressure.

A device for measuring intraocular pressure using the above method is shown in FIG. 3 and consists of a housing 7, in which a support with two projections 4 is located, while support 4 is connected to the housing by an eye support pressure sensor 6, a rod fixing unit 8, a rod 3, rod speed sensor 5.

A device for measuring intraocular pressure works as follows (see figure 3). A support with two protrusions 4 is installed on the eyeball 1, protected by the eyelid 2, which, due to the weight of the device and the pressure of the operator’s hand, creates a certain static pressure on the eye, and the pressure on the eye is determined by the pressure sensor on the eye 6. When a certain value is reached of pressure on the eye, the rod fixing unit 8 releases the rod, and it falls under the influence of gravity onto the eyeball 1, which is protected by the eyelid 2. In this case, the temporal characteristics of the rod’s movement when it penetrates the eye are determined. Next, the stem 3 is fixed in the node for fixing the rod 8. A different pressure is applied to the eyeball with the support with two projections 4, the pressure of the support is fixed by the pressure sensor of the support on the eye 6, and upon reaching the specified (different than the first time) pressure on the eye, the node fixation of the rod 8 releases the rod, and it falls under the influence of gravity on the eyeball 1, protected by the eyelid 2. In this case, the temporal characteristics of the movement of the rod when it penetrates the eye are determined. The two temporal characteristics of the movement of the rod when it penetrates the eye determines the value of intraocular pressure.

The authors believe that when measuring high intraocular pressure, the energy of a freely falling rod may not be enough, and therefore it is proposed to introduce an additional element for accelerating the rod into the method and device with a magnetic field.

In the above method, the measurement result is determined by the reaction of the sclera to an external disturbance, the impact of the stem on the eye, which deforms the surface of the sclera of the eye. In this case, two components of the force participate in the deformation of the eye, namely, the mass of the rod moving at a speed of V and the weight of the rod, which depends on the acceleration of gravity of the Earth. One of the forces, gravitational, in this method accelerates the rod to a certain speed and acts constantly when the rod interacts with the eye, and at the same time introduces a systematic error into the measurement process, since it dampens the sclera's reaction to deformation. It is advisable to use such a method for deforming the eyeball, in which the gravitational component of the stem weight is compensated. The authors propose to use a rod counterweight for this.

The method for measuring intraocular pressure through the eyelid works as follows - created by external influence (for example, by the operator’s hand), the static deformation of the eyeball with a support with two protrusions, then the eyeball is dynamically deformed through the eyelid by a rod with a counterweight, and the rod acceleration unit gives kinetic energy to it, with the subsequent determination of the magnitude of the elastic deformation of the surface of the eyeball, closed eyelid. Then, with a support with two protrusions, static deformation of the eyeball is performed with a high pressure relative to the initial value and dynamic deformation of the eyeball through the eyelid by a rod with a counterweight is repeated, while the rod acceleration unit gives kinetic energy to it, with the subsequent determination of the elastic deformation of the surface of the eyeball closed by the eyelid . The two parameters obtained function of the movement of the rod with a counterweight in time determines the value of intraocular pressure. Measurement can be carried out both on the sclera protected by an eyelid, and on a cornea protected by an eyelid. In this case, the static pressure of the support should be greater than the intraocular pressure.

A device for measuring intraocular pressure according to the above method consists (see Fig. 4) of a housing 7 in which a support with two projections 4 is located, while the support 4 is connected to the housing by an eye support pressure sensor 6, a rod 3, a rod speed sensor 5, rod counterweight 9, rod center of mass support and counterweight 10, rod acceleration unit 11.

A device for measuring intraocular pressure works as follows (see figure 4). A support with two protrusions 4 is installed on the eyeball 1, protected by the eyelid 2, which, due to the weight of the device and the pressure of the operator’s hand, creates a certain static pressure on the eye, and the pressure on the eye is determined by the pressure sensor on the eye 6. When a certain value is reached pressure on the eye, the rod acceleration unit 11 accelerates the rod 3, and it falls under the action of the acceleration force on the eyeball 1, protected by the eyelid 2. Before the rod hits the eye, the rod acceleration unit is turned off. In this case, the temporal characteristics of the movement of the rod when it penetrates the eye are determined. Next, the rod 3 under the action of the acceleration unit of the rod 11 is returned to the starting point. An additional pressure is applied to the eyeball with a support with two projections 4, the pressure of the support is fixed by the eye support pressure sensor 6, and when the set pressure value for the eye is reached, the rod acceleration unit 11 accelerates the rod 3, and it falls onto the eyeball 1 under the action of the acceleration force, protected by the eyelid 2. Before hitting the stem against the eye, the stem acceleration unit is turned off. In this case, the temporal characteristics of the movement of the rod when it penetrates the eye are determined. The two temporal characteristics of the movement of the rod when it penetrates the eye determines the value of intraocular pressure.

Since when a rod hits the eye through the eyelid with a pressure greater than intraocular pressure, elastic waves of deformation of the sclera and cornea of the eye appear in the eye, it is advisable to measure intraocular pressure in the following way. A static support is installed on the eye protected by the eyelid, which presses on the surface of the eye with a pressure lower than intraocular pressure, and a sensor for displacement (speed, acceleration) of the eye surface is installed. Then, dynamic deformation of the eye is carried out by any known method (a freely falling body, rod, accelerated magnetic field, ultrasonic wave, etc.), while deformation is carried out repeatedly, with increasing pressure on the eye, for example, from 20 to 100 mm Hg ., and at the moment of the appearance of a surface elastic wave on the sclera of the eye, the value of intraocular pressure is fixed, while the growing dynamic deformation of the eye stops. When using this method of measurement, it is necessary to take into account the inhibition of the stem due to deformation of the eyelid. This value is random. To overcome the ambiguity, the authors propose the following method - in the above method, the eyelid is deformed by the stock, which carries out pressure less than the intraocular pressure, for example 10 ÷ 15 mm Hg, and it is necessary to fix the spatio-temporal parameters of the stock immersion in the eyelid. In the future, upon reaching a surface elastic wave in the sclera or cornea, take into account the measurement of the influence of the eyelid on the final measurement result.

The sensor for the appearance of an elastic wave of deformation of the sclera or cornea can be placed on a static support, and it is advisable to introduce an additional unit for measuring the speed of movement of the support 4 relative to the housing 7 or a measurement unit for accelerating the movement of the support 4 relative to the body 7. In this case, the sensor of the elastic wave of deformation of the sclera or corneas can be installed on the eyelid of the eye, regardless of support, in the form of a measuring probe with sensors for speed or acceleration of the probe relative to the body.

As the acceleration unit of the rod 11, a solenoid can be used, the magnetic field of which accelerates the counterweight of the rod to a certain speed, and the speed of immersion of the rod in the eye determines the block for measuring the velocity of the rod, which can be the same solenoid.

Claims (13)

1. A method of measuring intraocular pressure through the eyelid, based on the static deformation of the eyelid by the load of the support with two protrusions and with the simultaneous dynamic deformation of the eyeball through the eyelid by a freely falling stem, followed by measurement of the parameters of the stem movement function in time, characterized in that the measurement is performed twice at different values of static load bearing on the eye. 2. A method for measuring intraocular pressure through the eyelid, based on the static deformation of the eyelid by the load of the support with two protrusions and with the simultaneous dynamic deformation of the eyeball through the eyelid with a stock, followed by measurement of the parameters of the stem displacement function in time, characterized in that the measurement is performed twice at different values static load bearing on the eye and the dynamic deformation of the eyeball through the eyelid is carried out by a rod with a counterweight, while the accelerator unit gives the necessary speed to the rod eniya rod. 3. A method for measuring intraocular pressure through the eyelid, based on the static deformation of the eyelid by the load of the support with two protrusions and with the simultaneous dynamic deformation of the eyeball through the eyelid by a freely falling stem, with subsequent measurement of the parameters of the stem movement function in time, characterized in that the measurement is performed twice at different values of the static load bearing on the eye, and the rod is additionally given acceleration by a magnetic field. 4. A method for measuring intraocular pressure through the eyelid, based on the static deformation of the eyelid by the load of the support with two protrusions and with the simultaneous dynamic deformation of the eyeball through the eyelid with a stock, followed by measurement of the parameters of the stock displacement function over time, characterized in that the dynamic deformation of the eye is performed repeatedly, with increasing pressure on the eye and at the time of the appearance of a wave of deformation of the sclera or cornea of the eye, the value of intraocular pressure is fixed, after which it stops increasing dynamic deformation of the eye. 5. The method for measuring intraocular pressure through the eyelid according to claim 1, characterized in that to determine the value of intraocular pressure, information is additionally used on the speed or acceleration of the support moving upward while the stem is immersed in the eyeball. 6. The method for measuring intraocular pressure through the eyelid according to claim 2, characterized in that to determine the value of intraocular pressure, information is additionally used on the speed or acceleration of the support moving upward while the stem is immersed in the eyeball. 7. The method for measuring intraocular pressure through the eyelid according to claim 3, characterized in that to determine the value of intraocular pressure, information is additionally used on the speed or acceleration of the support moving upward while the stem is immersed in the eyeball. 8. The method of measuring intraocular pressure through the eyelid according to claim 4, characterized in that to determine the value of intraocular pressure, information is additionally used on the speed or acceleration of the support moving upward while the stem is immersed in the eyeball. 9. A device for measuring intraocular pressure, comprising a housing with a supporting part with two protrusions located therein, designed to create a constant predetermined load, an eyeball deformation element through the eyelid in the form of a rod mounted in the sleeve cavity with the possibility of moving it in guides under the action of its own weight to create an impact load, characterized in that it uses an eye support pressure sensor, a rod acceleration unit with a magnetic field and a rod speed displacement sensor. 10. Device for measuring intraocular pressure, comprising a housing with a supporting part with two protrusions located therein, designed to create a constant predetermined load, an eyeball deformation element through the eyelid in the form of a rod mounted in the sleeve cavity with the ability to move it in guides under the action of its own weight to create an impact load, characterized in that a rod counterweight, a rod acceleration unit, a rod center of mass support with a counterweight, a space-time measurement sensor are used of the characteristics of the rod counterweight, the sensor of the elastic wave of deformation of the sclera, the rod velocity sensor. 11. A device for measuring intraocular pressure, comprising a housing with a supporting part with two protrusions, designed to create a constant predetermined load, an eyeball deformation element through the eyelid in the form of a rod mounted in the sleeve cavity with the ability to move it in guides under the action of its own weight to create an impact load, and an eye support pressure sensor, characterized in that an additional speed or acceleration sensor of the support relative to the housing is used. 12. A device for measuring intraocular pressure according to claim 9, characterized in that it additionally uses a speed sensor or acceleration of the support relative to the housing. 13. The device for measuring intraocular pressure of claim 10, characterized in that it additionally uses a speed sensor or acceleration of the support relative to the housing.

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