RU2642274C2 - Method of intraocular pressure measurement through eyelid (versions) - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: to measure IOP through the eyelid, a static deformation of the eyelid is performed followed by periodic resonant dynamic deformation of the eyeball through the eyelid by a rod connected to the body by elastic elements. At least in one period of resonant oscillations of the rod on the eyeball, in moments of rod movements with maximum speed, rod is forcibly pushed out in the direction of eye or is thrown up in the direction of eye, depending on the oscillations of the rod motion direction, while the frequency of resonant oscillations of the rod is proportional to IOP.

EFFECT: group of inventions allows to determine through the eyelid the intraocular pressure, regardless of the time of damping of free oscillations of the rod on the patient's eye.

3 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 (IOP) according to 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.

The disadvantages of all methods of measuring IOP directly through the surface of the sclera or cornea include the psychological inconvenience of patients, since the eye must be anesthetized, the eyelids must be closed from closing, while plungers, weights and rods are installed on the unprotected eye.

A known method of measuring IOP through the eyelid, RF patent No. 2335234, taken as a prototype, based on static deformation of the eyelid of the eye by a rod connected to the body by elastic elements, followed by a single pulsed dynamic deformation of the eye, while the value of intraocular pressure is determined by the frequency of free oscillation of the rod .

It has been established that after pulsed deformation of the sclera of the eye by the stock through the eyelid, the free oscillations of the stem-spring-sclera system damp in two periods — less than 0.05 seconds. In this connection, the disadvantages of the method are manifested - a short recording time of the period of damped oscillations. As is known, systolic and diastolic blood pressure affects IOP. Therefore, it is necessary to measure for at least 2 seconds, followed by averaging the frequency of the oscillation of the rod. In addition, with deformation of the eyeball by the stock, a slight increase in IOP occurs, since the sclera of the eye is inextensible, and the volume of the eye does not change during deformation.

The technical result is aimed at creating a method of measuring IOP, which allows to determine intraocular pressure through the eyelid, regardless of the decay time of free oscillations of the stem on the patient’s eye.

In the proposed method, the technical result is achieved by the algorithm for deforming the sclera of the eye through the eyelid, when, after a period of free oscillations of the stem on the eyeball, the stem is forcedly pushed or throws up, depending on the direction of movement of the stem.

The method of measuring intraocular pressure through the eyelid is illustrated by figures 1-4.

The figure 1 presents a graph of the oscillation of the rod when it is once ejected into the eye.

The figure 2 presents a graph of the oscillation of the rod when it is alternately briefly pushed into the eye and tossed from the eye through a period of resonant oscillation of the rod.

The figure 3 presents a graph of the oscillation of the rod during its periodic short-term pushing into the eye through a period of resonant oscillation of the rod.

The figure 4 presents a graph of the oscillation of the rod during its periodic short-term tossing from the eye through a period of resonant oscillation of the rod.

The operation of the IOP meter based on the method described in the prototype is shown in figure 1 and consists in the following - before installing the rod on the eyelid of the eye, the sclera surface has a level of Lo, after installing the rod on the eye and static deformation of the eye, the sclera surface has a level of L _ct . During dynamic deformation of the sclera of the patient’s eye due to pulsed ejection of the rod, the sclera’s surface briefly has a level of L _dyne . Further, after removing the ejection pulse (time t ₀ ), free oscillations of the rod begin, the frequency of which is due to the IOP, the weight of the rod and the stiffness of the springs connecting the rod to the device body.

As indicated above, after pulsed deformation of the eyeball by the stock through the eyelid, the free oscillations of the stem-spring-sclera system quickly decay - in 0.05 seconds. As is known, systolic and diastolic blood pressure affects IOP. Therefore, it is necessary to measure for at least 2 seconds, followed by averaging the frequency of the oscillation of the rod. It is known that to increase the amplitude and time of oscillation of rapidly decaying oscillations, a swinging resonant action is necessary.

To generate resonant oscillations of the stem on the eye, the authors propose the following method for measuring intraocular pressure through the eyelid, based on the static deformation of the eyelid and the eyeball with a rod connected to the body by elastic elements, followed by periodic resonant multidirectional pulsed dynamic deformation of the eye, when, at least after one period resonant oscillations of the stem on the eyeball, at the moment of movement of the stem at maximum speed, it is forcedly pushed in the direction of the eye behind or is thrown away from the eye depending on the direction of movement of the rod’s oscillations, while the frequency of the resonant oscillations of the rod is proportional to the IOP.

The IOP measurement method through the eyelid (option No. 1) is based on the static deformation of the eyelid and eyeball with a rod connected to the body by elastic elements, followed by periodic multidirectional pulsed resonant dynamic deformation of the eyeball by the rod when, after at least one period of resonant oscillations of the rod on the eye apple, at the time of movement of the stem at maximum speed, the stem is forced out in the direction of the eye or throws away from the eye, depending on the direction of movement I oscillation rod, wherein the resulting resonant frequency of oscillation is proportional to the rod IOP.

The method of measuring IOP through the eyelid (option No. 1), presented in figure 2, works as follows - before installing the stem on the eyelid of the eye, the sclera surface has a level of L ₀ , after installing the stem on the eye and static deformation of the eye, the sclera surface has a level of L _ct . During dynamic deformation of the sclera of the patient’s eye due to pulsed ejection of the rod, the sclera’s surface briefly has a level of L _dyne . Further, after removing the ejection pulse (time t ₀ ), free rapidly decaying oscillations of the rod begin, the frequency of which is due to the IOP, the weight of the rod, and the stiffness of the springs connecting the rod to the device body. After the passage of time of the full period of oscillations, the rod moves away from the eye and at the moment of passing the point L _ct , when the speed of movement of the rod is maximum, a short-term tossing of the rod in the direction from the eye occurs (time t ₁ ). In this case, the static deformation of the eye is compensated, and the free oscillations of the stem are independent of the static deformation of the eye. Further, after the passage of time of the full period of oscillations, the rod moves in the direction of the eye and at the moment of passing the point L _article , when the speed of movement of the rod is maximum, a short-term pushing of the rod in the direction of the eye (time t ₂ ) is performed. Subsequent multidirectional pulsed resonant deformations of the eye by the stock can be carried out arbitrarily long, while it can be seen (figure 2) that the amplitude of the oscillations of the stock increases. The resonant oscillations of the stem are formed on the eye. The frequency of the resonant oscillations of the stem is determined by the IOP, the weight of the stem, and the stiffness of the springs connecting the stem to the device body.

To obtain resonant oscillations of the rod on the eye, it is not necessary to use the multidirectional action of the rod on the eye. You can use unidirectional resonant rod pushing into the eye or resonant rod toss from the eye. The authors propose a method for measuring IOP through the eyelid (option No. 2), based on the static deformation of the eyelid and eyeball with a rod connected to the body by elastic elements, followed by periodic unidirectional pulsed resonant dynamic deformation by the stock of the eyeball, when, after at least one full period of free the oscillations of the rod on the eyeball, at the moment the rod moves in the direction of the eye at maximum speed, the rod is forced into the eye, while the frequency of the resonant oscillations th rod is proportional to IOP.

The method of measuring IOP through the eyelid (option No. 2), shown in figure 3, is as follows - before installing the stem on the eyelid of the eye, the sclera surface has a level of L ₀ , after installing the stem on the eye and static deformation of the eye, the sclera surface has a level of L _ct . During dynamic deformation of the sclera of the patient’s eye due to pulsed ejection of the rod, the sclera’s surface briefly has a level of L _dyne . Further, after removing the ejection pulse (time t ₀ ), rapidly damping rod oscillations begin, the frequency of which is due to the IOP, the weight of the rod, and the stiffness of the springs connecting the rod to the device body. After the time of the full period of free vibrations at the moment when the stem moves in the direction of the eye, when passing through the point L _ct , when the speed of movement of the stem is maximum, repeated pulse deformation of the eye occurs due to short-term pushing of the stem in the direction of the eye at time t ₁ . As can be seen from figure 3, the oscillations of the rod do not damp, which means they are resonant. Subsequent resonant pulsed deformations of the eye by the stock can be made for an arbitrarily long time. The frequency of the resonant oscillations of the stem is determined by the IOP, the weight of the stem, and the stiffness of the springs connecting the stem to the device body.

Similarly, one can obtain free oscillations of the stem on the patient’s eyeball if, after creating static pressure on the eye, the rod is periodically unidirectionally thrown from the eye. The authors propose a method for measuring IOP (option No. 3), based on the static deformation of the eyelid and eyeball with a rod connected to the body by elastic elements, followed by periodic resonant pulsed removal of the static deformation of the eye, when, after at least one full period of free oscillations of the stem on the eye apple, at the time of movement of the rod away from the eye at maximum speed, the rod is forcibly thrown away from the eye, while the frequency of resonant oscillations of the rod is proportional to the IOP.

The method of measuring IOP through the eyelid (option No. 3), shown in figure 3, is as follows - before installing the rod on the eyelid of the eye, the sclera surface has a level of L ₀ , after installing the rod on the eye and static deformation of the eye, the sclera surface has a level of L _st . When the stem is thrown away from the eye, the static deformation of the eye is removed, and the stem due to the pulse pushing of the stem by the sclera surface briefly exceeds the value L ₀ , i.e. jumps over the eye. Further, after the release of the throwing pulse (time t ₀ ), the rod deforms the eyeball and free fast-damping oscillations of the rod begin, the frequency of which is due to the IOP, the weight of the rod and the stiffness of the springs connecting the rod to the device body. After the passage of time of the full period of free oscillations, the rod moves away from the eye, and at the moment of passing the point L _article , the rod is thrown up in the direction from the eye (time t ₁ ). In this case, the static deformation of the eye is again compensated, and the free oscillations of the stem are independent of the static deformation of the eye. Subsequent pulsed removal of the static deformation of the eye by the stock can be carried out arbitrarily long. The oscillation frequency of the stem is determined by the IOP, the weight of the stem, and the stiffness of the springs connecting the stem to the instrument body.

All three methods of measuring IOP can be implemented using the device described in the patent of the Russian Federation No. 2335234 and taken as a prototype.

From practice, option No. 1 for measuring IOP is preferable, since dynamic multidirectional resonant action on the eyeball occurs after shorter periods of time than when using options No. 2 and No. 3. Option number 1 allows with less energy costs and faster to achieve a stable amplitude of resonant oscillations.

These methods of measuring IOP through the eyelid can be used to measure IOP directly on the sclera or cornea of the eye, since only the stock is installed on the eyelid of the eye, which can also be installed on the surface of the eyeball.

Claims (3)

1. A method for measuring intraocular pressure through the eyelid, based on the static deformation of the eyelid and eyeball, pulsed dynamic deformation of the eyeball through the eyelid with a rod connected to the body by elastic elements, characterized in that the intraocular pressure of the eye is determined by the frequency of resonant oscillations of the rod on the eye, which are carried out due to periodic multidirectional pulsed resonant dynamic deformations by the stock of the eyeball, when, after at least one period of resonant oscillations w on the eyeball of an eye, at the time of moving the rod with the maximum speed, the rod is pushed forcibly in the direction of the eye or is thrown in the direction from the eye depending on the direction of rod movement oscillations, the frequency of oscillation is proportional to the resonance rod IOP. 2. A method for measuring intraocular pressure through the eyelid, based on the static deformation of the eyelid and the eyeball, pulse dynamic deformation of the eyeball through the eyelid with a rod connected to the body by elastic elements, characterized in that the intraocular pressure of the eye is determined by the frequency of resonant oscillations of the rod on the eye, which are carried out due to periodic unidirectional pulsed resonant dynamic deformations by the stock of the eyeball, when, after at least one period of resonant oscillations of the piece ka on the eyeball, when moving rod with the maximum speed in the direction of the eye, the rod is pushed forcibly toward the eye, wherein the resonant frequency of oscillation is proportional to the rod IOP. 3. A method for measuring intraocular pressure through the eyelid, based on the static deformation of the eyelid and eyeball, pulsed dynamic deformation of the eyeball through the eyelid with a rod connected to the body by elastic elements, characterized in that the intraocular pressure of the eye is determined by the frequency of resonant oscillations of the rod on the eye, which are carried out due to periodic unidirectional pulsed resonant dynamic deformations by the stock of the eyeball, when, after at least one period of resonant oscillations of the piece ka on the eyeball, when moving rod at maximum speed in a direction away from the eye, the rod force is thrown in the direction away from the eye, the resonant frequency of oscillation is proportional to the rod IOP.

Images