RU56152U1 - DEVICE FOR MEASURING INTERNAL EYE PRESSURE THROUGH THE EYE - Google Patents

Abstract

The utility model relates to portable medical equipment for ophthalmology, designed to measure intraocular pressure (IOP) with the simultaneous use of static load and shock for deformation of the eyeball through the eyelid, and can be used for mass examination of the population for glaucoma, monitoring the correctness of its treatment, individual monitoring intraocular pressure without anesthesia (anesthesia) and the risk of infection. A device for measuring intraocular pressure through an eyelid comprises a housing, a movable sleeve with a support installed in the housing with limited reciprocating movement to create a static load on the eyeball through the eyelid, a rod with a flat base mounted in the cavity of the sleeve with the possibility of movement relative to the support and creating a shock for deformation of the eyeball through the eyelid, at least one measuring winding placed in a movable sleeve. A permanent magnet is mounted on the rod, and the measuring winding is located relative to the permanent magnet with the ability to control the direction and speed of movement of the rod and is connected to a control unit, processing and indication, configured to create voltage of opposite polarities on the measuring winding to return the rod to its original position and then create impulse of the rod movement towards the support, with the possibility of converting the signal from the measuring winding and displaying the results bt.

Description

The utility model relates to portable medical equipment for ophthalmology, designed to measure intraocular pressure (IOP) with the simultaneous use of static load and shock for deformation of the eyeball through the eyelid, and can be used for mass examination of the population for glaucoma, monitoring the correctness of its treatment, individual monitoring intraocular pressure without anesthesia (anesthesia) and the risk of infection.

A device is known for measuring intraocular pressure in the open eye, containing a probe, one part of which is made of magnetic material, and the other part is non-magnetic with a rounded (hemispherical) base for deforming the eye, placed inside the electromagnetic coil to give it a given speed, and the electromagnetic coil is built into the wall of the housing held by the operator’s hand when measuring (see patent WO 03/105680 [PCT / F103 / 00489], A 61 B 3/16, publ. 12.24.2003).

In the known device when measuring IOP, shock is used to deform the open eye, and there is no static eye load. When measuring IOP through the eyelid, the required measurement accuracy is not provided. This is due to the fact that when measuring IOP through the eyelid, much more energy is required than in the open eye to compensate for the depreciation properties of eyelids of various anatomical structures. However, an increase

shock impact leads to instability of the position of the eye in space due to the stretching of the muscles on which it is attached. This instability does not allow the measurement of IOP with the necessary accuracy. In addition, the rounding at the base of the probe is unacceptable in the case of measurement through the eyelid with a large shock load, since it leads to excessive pain during measurement.

Known devices for measuring IOP through the eyelid with stabilization of the position of the eye, for example, due to the additional static load on it.

For example, it is known a device for measuring intraocular pressure, including an annular support through which a static load is created on the eye through the eyelid during measurement, and a ball weighing 0.3 ÷ 0.7 g for deformation of the cornea of the eye through the eyelid by impact, installed with the possibility of free fall with heights 120 ÷ 150 mm with the subsequent determination of pressure by the height of the first rebound of the ball (see RF patent 2007951, class A 61 3/16, publ. 1990).

The use of an annular support does not allow a device for measuring IOP to be rigidly fixed to the eye, which sharply reduces its accuracy. In addition, the additional measurement error increases sharply with a slight deviation of the device from the vertical during measurement.

Closest to the proposed one is a device containing a housing with a movable sleeve placed therein with limited age and progressive movement, provided with guides and a supporting part to create a constant predetermined load, an eyeball deformation element through the eyelid in the form of a freely falling body mounted in the sleeve cavity with the possibility of its free fall in the guides under the action of its own weight to create an impact load, the holder of the deformation element in

the initial upper position, located in the upper part of the cavity of the movable sleeve, a measuring winding mounted in the wall of the movable sleeve and included in the generator circuit to measure the function of movement of the deformation element in time, the position sensor of the movable sleeve relative to the housing, made in the form of a mechanical lock of the initial lower position indicated bushings in the housing, including a spring-loaded button, the clamping part of which is installed in the opening of the housing wall with the possibility of interaction with the outside the back surface of the movable sleeve, and the supporting part of the movable sleeve is made with two protrusions with rounded supporting ends equidistant to a distance of 7 ÷ 10 mm from the axis of movement of the freely falling body, the elastic deformation element is made in the form of a rod with a terminal part for contact with the eyelid of at least 3 mm with a flat base with an area of 1 ÷ 7 mm ² , the lower guide is a limiter of the lower position of the deformation element in the cavity of the movable sleeve in the idle position (see RF patent №2123798, cl. A 61 B 3/16, publ. 1998).

In the known device, the impact during measurement is created by a freely falling rod with a flat base with an area of 1 ÷ 7 mm ² , and the static load on the eye through the eyelid is created by a movable sleeve, into which the measuring winding is mounted together with means for fixing the initial position of the rod that acts on the eye through support of the original design, which allows you to firmly fix the device to the eye through the eyelid.

However, the device requires strict verticality during measurement, as well as an additional procedure for setting the rod to its original position before measurement, several measurements on the eye to increase accuracy, which lengthens the measurement procedure and does not allow

IOP measurements for the patient himself.

The low accuracy of the IOP measurement by a known device is associated with the influence of the error of manual installation of the device case in a vertical position, the lack of automatic control of the correct position of the device during measurement, the influence of the error from the mechanical lock when creating a given static load at the time of measurement.

The utility model solves the problem of increasing the operational properties of the device for measuring IOP through the eyelid.

The technical result of the utility model is to increase the accuracy of the measurement by ensuring the independence of the measurement readings from the verticality of the device body, reducing the time for the measurement procedure as a whole by several times, simplifying and convenient the measurement procedure, and the patient being able to perform IOP measurements on his own.

The technical result is achieved by the fact that in the device for measuring intraocular pressure through the eyelid, comprising a housing, a movable sleeve with a support installed in the housing with the possibility of limited reciprocating movement to create a static load on the eyeball through the eyelid, a rod with a flat base installed in the cavity of the sleeve with the ability to move relative to the support and create a shock for deformation of the eyeball through the eyelid, at least one measuring winding, installed in the movable sleeve, a permanent magnet mounted on the rod is introduced, and the measuring winding is located relative to the permanent magnet with the ability to control the direction and speed of the rod and connected to the control unit, processing and display, configured to create voltage on the measuring winding

opposite polarities for the removal of the rod to its original position and the subsequent creation of a pulse of movement of the rod towards the support, with the possibility of converting the signal from the measuring winding to determine the intraocular pressure and display the results.

The device can be equipped with a non-contact signaling device of the presence of a given static load on the eyeball through the eyelid during measurement, preferably made in the form of a sensor position of the sleeve relative to the housing.

It is advisable that the position sensor of the movable sleeve relative to the housing be made comprising a generator, an additional sleeve with a cavity and a coil mounted respectively on the movable sleeve and the housing with the possibility of changing the inductance of the coil winding when moving the movable sleeve, and the coil winding is included in the generator circuit.

It is advisable to connect the generator of the position sensor of the movable sleeve relative to the housing with a control unit for processing and displaying measurement data.

It is advisable to perform a stock with a base area from 0.2 to 1.5 mm ² .

Preferably, the support is removable.

It is advisable to carry out the support in the form of two wedge-shaped protrusions concave inward with rounded ends, between which a leveling ring protrusion is located at a height of 3 ÷ 5 mm from their base.

It is advisable to move the sleeve and the support with the corresponding cavities and openings for air outlet when moving the rod.

The essence of the utility model is that forced

controlled movement of the stem with a flat base with an area of 0.2 ÷ 1.5 mm under the influence of an electromagnetic field with a stable value of the static load on the eyeball through the eyelid ensures guaranteed compression of the eyelids of various anatomical structures directly in the place of its deformation during measurement, which increases the accuracy of IOP measurement .

Figure 1 shows a device for measuring IOP in a section; figure 2 communication diagram of the main parts of the device for measuring IOP, explaining its operation.

A device for measuring IOP contains (Fig. 1) a plastic housing 1, a movable sleeve 2 with a support 3, mounted in the housing 1 with the possibility of limited reciprocating movement to create a static load on the eyeball through the eyelid. The rod 4 of non-magnetic material is installed in the cavity of the movable sleeve 2 with the possibility of movement relative to the support 3 for deformation of the eyeball through the eyelid by impact. A permanent magnet 5 is installed on the rod 4. The coil 6 is placed in the wall of the movable sleeve 2 and is made with at least one measuring winding 7, mounted relative to the permanent magnet 5 with the ability to control the direction and speed of the rod 4. The measuring winding 7 is connected through a terminal 8 s block 9 control, processing and display (figure 2). A protective screen 10 mounted on the outside of the housing 1, provides shielding of the measuring winding 7 of the coil 6.

The rod 4 is made of plastic and has a flat base 11 with an area of 0.20 ÷ 1.5 mm ² . With an area of less than 0.20 mm ² , a painful sensation of the measurement procedure is possible, with an area of more than 1.5 mm ² , guaranteed compression of the thickened eyelids is not provided. Lower and upper plain bearings 12 and 13, formed in

movable sleeve 2, provide free longitudinal movement of the rod 4 inside the coil 6 and bearings 3. The movement of the rod 4 down is limited by the surface 14 of the lower sliding bearing 12. The installation of the rod 4 in the upper initial position inside the movable sleeve 2 is limited by the surface 15 of the protrusion of the rod 4 and the upper sliding bearing 13.

A longitudinal slot 16 is made in the housing 1, in which a limiter 17 is installed integrally with the movable sleeve 2 to limit its vertical reciprocating movement and to exclude rotational motion relative to the housing 1. To connect the measuring winding 7 to the control, processing, and 9 unit Indication applied pin 8, part of which is built into the cavity of the limiter 17.

The IOP measuring device is equipped with a non-contact indicator of the presence of a given static load on the eye through the eyelid during measurement, made, for example, in the form of a sensor 18 of the position of the movable sleeve 2 relative to the housing 1. The specified sensor 18 contains an additional sleeve 19 and a fixed coil 20 mounted respectively on the movable sleeve 2 and the housing 1, and the winding 21 of the stationary coil 20 is connected through the terminal 22 to the circuit of the generator 23, which is connected to the block 9 of the control, processing and display (figure 2).

The value of the static load when measuring (formed by the mass of the movable sleeve 2 with the support 3, the measuring winding and the additional sleeve 19, as well as the mass of the rod 4 with a permanent magnet 5) should be from 20 to 30 grams. With a mass of less than 20 grams, a stable and stable position of the eyeball is not provided, with a mass of more than 30 grams, a significant increase

tonometric intraocular pressure due to excessive deformation of the eyeball.

The support 3 has two wedge-shaped protrusions 24 with rounded supporting ends, between which there is an annular protrusion with a leveling platform 25, made at a height of (H) 3 ÷ 5 mm from their base. The wedge-shaped protrusions 24 of the support 3 are equidistant to a distance (S) equal to 7 ÷ 10 mm from the axis of movement of the rod 4. For convenience of disinfection, the support 3 is removable and removable. The support 3 is fixed in the lower part of the movable sleeve 2 by means of an elastic retainer 27, providing, if necessary, rotation of the support 3 around its axis, as well as its removal in order to remove the rod 4 for preventive cleaning of contaminants.

The housing 1 can be placed in a removable plastic protective casing 28, rigidly connected to the casing 1 by means of a decorative sleeve 29. Moreover, the specified protective casing 28 and the housing 1 are mounted with the possibility of their vertical reciprocal movement relative to the movable sleeve 2 with the support 3 within distance (L) equal to 4 ÷ 6 mm.

The movable sleeve 2, the stationary coil 20 and the support 3 have respective cavities 30, 31, 32 and openings 33 for air outlet when moving the rod 4.

The control, processing and display unit 9 comprises a switch 34, an amplifier 35, an analog-to-digital converter 36, a processor 37, a display 38, a power supply 39. The first and second outputs of the switch 34 are connected respectively to the first and second inputs of the amplifier 35, the output of which is connected to the first input of the analog-to-digital converter 36. The processor 37 by the first, second and third inputs is connected respectively to the outputs of the analog-to-digital converter 36, the generator 23 and the first input of the display 38, and the first and second

the outputs are connected respectively to the third input of the switch 34 and to the second input of the display 38. The power source 39 is connected to the input of the generator 23, the fourth input of the switch 34, the third inputs of the amplifier 35, processor 37, and the second input of the analog-to-digital converter 36.

The first and second inputs of the switch 34 are the first and second inputs of the control, processing and indicating unit 9 and are connected through the output 8 to the measuring winding 7. The fourth input of the switch 34 is the third input of the control, processing and indicating unit 9 and connected to a generator 23, the output of which connected to the input of the processor 37 and is the input of the indicated unit 9. The analog-to-digital Converter 36 and the processor 37 are a microprocessor 40. The switch 34 is designed to change the direction of the current in the measuring winding 7 with integer The change in the direction of movement of the rod 4 and the creation of a metered impact on the eyeball is controlled by microprocessor 40.

The present invention is based on the use of shock to deform the eyeball through the eyelid while creating a stable static load that keeps the eyeball unchanged during measurement. The principle of operation of the device for measuring IOP consists in creating a dosed impulse of movement of the rod 4 for deformation of the eyeball through the eyelid and converting its translational-reciprocal movement (as a result of interaction with the elastic surface of the eye) into electric current signals.

A device for measuring intraocular pressure through the eyelid works as follows. The patient's head is positioned face up. The direction of his gaze is established for the deformation of the eye in the sclera at approximately an angle of 45 ° to the horizon (or 90 ° during deformation

stock 4 areas of the center of the cornea through the eyelid) using, for example, the patient’s hands as a guide. Holding the device turned on by the protective casing 28 in an upright position, install the support 3 on the upper eyelid region in the region of its cartilage symmetrically to the center of the eyeball, touching the eyelid of the eyeball with its wedge-shaped protrusions 24. The wedge-shaped protrusions 24 and the leveling platform 25 of the support 3 fix the eyelid and the eyeball in a position constant in all measurements. Then the protective casing 28 together with the housing 1 in a small range (4 ÷ 6 mm) smoothly lowers down relative to the support 3. In this case, the movable part of the device (consisting of a movable sleeve 2 with a measuring winding 7, an additional sleeve 19 and a support 3) moves relative to the housing 1 up. As a result of this, an additional sleeve 19, made, for example, of brass, moving over the stationary coil 20, changes the inductance of the winding 21, thereby changing the frequency of the generator 23, into the circuit of which it is connected through terminal 22.

At a certain frequency of the specified generator 23 by the control, processing and indication unit 9, a direct current voltage of a certain polarity is automatically supplied to the measuring winding 7 through terminal 8, as a result of which the rod 4 is moved upward by the electromagnetic field of the measuring winding 7 and is set to its original position. At the same time, a short sound signal is turned on, which indicates that the rod 4 is in the initial position for measuring IOP, the mass of the moving part of the device creates the necessary static load on the eyeball through the eyelid. At this moment, it is necessary to stop lowering the housing 1 relative to the support 3, holding the protective casing 28 with the housing 1 in this position motionless (no more than 3 seconds).

At the same time, from the measuring winding 7 of the coil 6

the previously supplied DC voltage is automatically removed and a short voltage pulse of the opposite polarity is applied. As a result of this, the rod 4 receives a dosed impulse of movement towards the eyeball and with its flat base 11 deforms the eyelid and eyeball, and then bounces in the opposite direction.

The permanent magnet 5 located on the stem 4, passing down (when moving towards the eyeball) and up (when bouncing from it), creates a voltage in the measuring winding 7 of the coil 6, which is further amplified in the amplifier 35 and used for conversion to digital values, processing and analysis of the function of the velocity of the rod 4 and in the form of the measurement result, the IOP is displayed on the display 38.

In the process of operation of the device, the upper and lower bearings 12, 13 provide free longitudinal movement of the rod 4 inside the coil 6 and support 3. The movement of the rod 4 down is limited by the surface 14 of the lower sliding bearing 12. The installation of the rod 4 in the upper position is limited by the surface 15 of the protrusion of the rod 4 and the upper bearing 13 sliding. The hole 33 in the support 3, the cavity 30, 31 inside the movable sleeve 2 and the cavity 32 in the stationary coil 20 allow air to escape when the rod 4 is moving. The restrictor 17 installed in the longitudinal slot 16 of the housing 1 prevents rotation of the movable sleeve 2 about its axis.

The conversion of the analog signal from the measuring winding 7 to digital form, software control of the operating modes, digital processing and analysis of the motion function of the rod 4 are carried out by the microprocessor 40, which is part of the block 9 of the control, processing and display.

The claimed device provides guaranteed compression of various eyelid thicknesses and increases the stability of

static load on the eye during measurement (due to the introduction of a non-contact signaling device of its predetermined value and the formation of a command for automatic measurement), which increases the accuracy of measuring IOP. The installation of a permanent magnet 5 on the rod 4 allows you to replace the impact of a freely falling rod (as in the prototype) for forced controlled movement of the rod 4 under the influence of an electromagnetic field. This significantly reduces the requirement of vertical installation of the device during measurement, and also creates the ability to automatically set the rod to its original position and perform several IOP measurements in one installation of the device by eye.

A device for measuring IOP, made with the correctness of setting the static load during measurement, is convenient due to the combination of all elements in one housing with overall dimensions of not more than 174 × 26 × 20 mm, weighing not more than 150 grams. The proposed type of alarm about the presence of a given static load during measurement is quite informative and is active.

The proposed device for measuring IOP is characterized by the informative accuracy of setting the static load in the process of measuring IOP, which increases the accuracy and speed of measurement. The measurement procedure is painless. Provides a measurement of intraocular pressure in mm RT.article. with an accuracy of +/- 0.4 mm Hg Measurement time no more than 3 seconds.

Conducting multiple measurements of IOP on one patient during the day with minimal time is very important for monitoring the correctness of the chosen treatment method and can significantly increase its effectiveness. This eliminates the risk of infection when measured due to the lack of direct contact with the mucous membrane of the eye.

The simplicity of the design of the claimed device allows it to be manufactured at affordable prices, and the ease of use allows it to be used not only in clinical conditions, but also at home. The proposed technical solution allows to increase the accuracy of measuring IOP and provides the ability to monitor changes in pressure during treatment by the patient. The advantages of the device are:

- high accuracy of measurement;

- reduction of the total time of the IOP measurement procedure;

- allows the patient to measure IOP on his own;

- reducing the time of orientation of the device to the working position;

- application in any conditions without special staff training;

- in improving the consumer properties of the device (comfort, usability, stability parameters);

- to simplify the operation of the device.

Claims (10)

1. A device for measuring intraocular pressure through an eyelid, comprising a housing, a movable sleeve with a support mounted in the housing with the possibility of limited reciprocating movement to create a static load on the eyeball through the eyelid, a rod with a flat base mounted in the cavity of the sleeve with the possibility of movement relative to the support and the creation of a shock for the deformation of the eyeball through the eyelid, at least one measuring winding placed in a movable sleeve, characterized in it is provided with a permanent magnet mounted on a rod, and a measuring coil positioned relative to the permanent magnet with the ability to control the direction and speed of movement of the rod. 2. The device according to claim 1, characterized in that the measuring winding is connected to a control, processing and display unit, configured to create voltage of opposite polarities on the measuring winding to divert the rod to its original position and then generate a pulse of movement of the rod towards the support, with the ability to convert the signal from the measuring winding to determine intraocular pressure and display the results. 3. The device according to claim 1, characterized in that it is equipped with a contactless signaling device of the presence of a given static load on the eyeball through the eyelid during measurement. 4. The device according to claim 3, characterized in that said detector is a sleeve position sensor relative to the housing. 5. The device according to claim 4, characterized in that the position sensor of the movable sleeve relative to the housing contains a generator, an additional sleeve with a cavity and a coil mounted respectively on the movable sleeve and the housing with the ability to change the inductance of the coil of the coil when moving the movable sleeve, and the coil of the coil is turned on into the generator circuit. 6. The device according to claim 5, characterized in that the generator of the position sensor of the movable sleeve relative to the housing is connected to a control unit for processing and displaying measurement data. 7. The device according to claim 1, characterized in that the flat stem base has an area of from 0.2 to 1.5 mm ² . 8. The device according to claim 1, characterized in that the support is removable. 9. The device according to claim 1, characterized in that the support is made in the form of two concave wedge-shaped protrusions with rounded ends, between which there is a leveling ring protrusion at a height of 3 ÷ 5 mm from their base. 10. The device according to claim 1, characterized in that the movable sleeve and support have corresponding cavities and openings for air outlet when moving the rod.