RU67836U1 - DEVICE FOR MEASURING INTERNAL EYE PRESSURE - Google Patents

Abstract

A device for measuring intraocular pressure relates to medical equipment and can be used in forensic practice for post-mortal measurement of intraocular pressure, in order to determine the age of death of the body. The essence of the device: it contains a housing inside which is mounted a movable sleeve with guides, a rod mounted with the possibility of elastic deformation of the measured organ, a support with protrusions in its lower part, a microprocessor, a measuring transducer, linear displacement of the rod, a sensor of angular deviation of the axis of free fall of the rod from vertical mounted on the board and connected through a microprocessor with means for generating an audio or light signal-a reminder of the position of the axis of incidence of the rod during measurement, n a plastic cage mounted between the projections of the support and made in the form of a sphere segment with a hole in the center and a removable 0.15 mm thick latex membrane inserted into the nozzle in such a way that it contacts the inner surface of the nozzle, the length of the nozzle opening being equal to the distance between the inner surfaces of the protrusions of the support. The device allows: to ensure the accuracy of measurement of intraocular pressure of dead organisms; the possibility of the most correct comparison of the measurement results when monitoring changes in intraocular pressure to determine the age of death; reduce the orientation time of the device to enable the most correct comparison of measurement results; the use of the device for any changes in eyelid tissue and to improve consumer properties, in particular, comfort, convenience and simplification of operation. F: 1 p. and 2-a p.zav. 4 drawings.

Description

The utility model relates to a device for measuring intraocular pressure and can be used in forensic practice, as a device for post-mortal measurement of intraocular pressure, in order to determine the age of death of an organism.

A drop in intraocular pressure refers to permanent posthumous changes and allows you to use it to determine the age of death in forensic practice.

A device for measuring intraocular pressure, comprising a body in the form of a tube, a reading device, an element for dynamic deformation of the cornea of the eye through the eyelid, made in the form of a moving ball, weighing 0.3-0.7 g, freely falling from a height of 120-150 mm and placed inside the case with a transparent working part, the holder in the upper part of the case and the stopper in its lower part, while holding the ball in the upper idle state is provided by the holder, and in the bottom - by the stopper (see RF patent No. 2007951, АВВ 3/16, 29.06 .1990).

A device for measuring intraocular pressure, comprising a housing, inside of which is mounted with a possibility of limited reciprocating movement of the sleeve, having guides, a supporting element to create a constant predetermined load, a rod mounted in the cavity of the sleeve with the possibility of free fall under the influence of its own weight, holder, located in the upper part of the sleeve cavity and serving to hold the rod in the initial upper position, the linear displacement transducer rod connected to a microprocessor (see RF patent No. 21373798, class A61B 3/16, 1998).

These devices have a common disadvantage in that they cannot be used to measure the intraocular pressure of deceased organisms, because at the time of death and after death in the body of the deceased, in particular, in the cornea and soft tissues of the eyelids, post-mortem changes occur that affect on measurement accuracy.

From the point of view of mechanics, the cornea is a soft shell (a shell that does not resist bending stresses), which allows measurements to be made directly through the cornea, however, the above-mentioned known devices are not suitable for corneal tonometry; upon contact with the cornea, the stock is quickly contaminated; there is no control over the possibility of multiple measurements at a particular point.

The closest technical solution of the claimed device is the utility model "Measuring tonometer for determining the pressure inside the organs through their skin" (see patent No. 50096 U1, A61B 3/16, 5/00, 06/24/2005).

The specified measuring tonometer contains a housing inside which a movable sleeve with guides is mounted, a rod mounted with the possibility of elastic deformation of the measured organ, a support with protrusions in its lower part, the protrusions being equidistant from the rod axis at a distance of 7-10 mm, a microprocessor, measuring a rod linear displacement transducer connected to a microprocessor, a sensor for angular deviation of the axis of free fall of the rod from the vertical, mounted horizontally on a board located perpendicular but to drop the rod axis and connected by a microprocessor with means forming a sound or light signal, reminders stem axis position of incidence in the measurement.

The disadvantages of the device prototype are:

- relatively low accuracy of post-mortal measurement of intraocular pressure and stable values of the measured parameters;

- the difficulty of measuring pressure and the long orientation time of the device in the process of measuring the intraocular pressure of dead organisms due to contamination of the stem when measured through the cornea of the eye;

- reduced consumer properties, in particular, comfort and usability in post-mortal pressure measurement.

The objectives of the proposed device for measuring intraocular pressure are:

- ensure the accuracy of measurement of intraocular pressure of dead organisms;

- to provide the possibility of the most correct comparison of the measurement results when monitoring changes in intraocular pressure to determine the age of death;

- reduce the orientation time of the device to enable the most correct comparison of measurement results;

- ensure the use of the device for any changes in the tissue of the eyelids;

- improve consumer properties, in particular, comfort, convenience and simplification of operation.

These problems are solved by the fact that in a device containing a housing inside which a movable sleeve with guides is mounted, a rod mounted with the possibility of elastic deformation of the measured organ, a support with protrusions in its lower part, and the protrusions are equidistant from the rod axis at a distance of 7- 10 mm, microprocessor, linear linear displacement transducer, connected to the microprocessor, angular deviation sensor of the axis of free fall of the rod from the vertical, mounted horizontally on the board, located th perpendicular to the axis of fall of the rod and connected through a microprocessor

with the means of generating an audible or light signal-reminder of the position of the axis of incidence of the rod during measurement, the device is additionally equipped with a nozzle made of organic material installed between the projections of the support and made in the form of a segment of a sphere with a hole in the center and a removable membrane of elastic material embedded in the nozzle so that it contacts the inner surface of the nozzle, the length of the nozzle opening being equal to the distance between the inner surfaces of the projections of the support. In addition, plastic is used as an organic material for the nozzle, and 0.15 mm thick latex as an elastic elastic material for a removable membrane.

The device is illustrated by drawings, where figure 1 shows the device, in axial section, with the allocation of its lower part, the circle "A"; figure 2 - image of the circle "A" of figure 1; figure 3 - nozzle and a removable membrane, top view; figure 4 is the same side view.

A device for measuring intraocular pressure comprises a housing 1, a movable sleeve 2 made with limited vertical reciprocating movement, the first 3 and second 4 guides, the second made in the form of a single part with a sleeve 2, a support 5, which is fixed in the lower part of the first guide 3 of the sleeve 2, for example, using a spring-clip connection and has in its lower part two protrusions 22 of a wedge-shaped cross-section, with rounded supporting ends, and the contact surface 6 of the protrusions 22 of the support 5 is equidistant from the axis 7 at a distance of "L" equal to 7-10 mm

The device also contains a rod 8 having a flat end 10, the area of which is 1-7 mm square., Which provides elastic deformation of the cornea, means 9 for limiting the movement of the rod 8, the holder 11 of the rod 8, made in the form of a plate-latch with a conical

hole to capture the upper end of the rod 8 and having a bevel 16 on the side surface, the sensor 12 of the angular deviation of the axis 7 of the free fall of the rod 8 from the vertical, mounted horizontally on the board 13, and connected through a microprocessor (not shown in figure 1) with sound generating means or a light reminder (not shown in Fig.) about the position of the axis of incidence 7 of the rod 8 when measuring, while the microprocessor is connected to a measuring transducer (not shown in Fig. 1), which is located on the 'printed circuit board 14 of the device and has a gene an herator, a data processing unit (not shown in FIG.) and an electromagnetic coil 15 connected to the generator, fixed in the sleeve 2 between the rails 3 and 4.

In the wall of the housing 1 of the device there is a pin 17, which is the drive for horizontal movement of the latch plate, spring-loaded with a wire element 18, built into the walls of the sleeve 2 and located in the corresponding hole of the latch plate. The upper end of the rod 8 has a stop 19, (in cross section - a truncated pyramid), which provides reliable fixation in the hole of the latch plate. Also, in the housing 1 of the device, a vertical slot 20 is made, in which a second pin 21 is mounted, mounted on the sleeve 2 to limit the vertical reciprocating movement of the rod 8 and to exclude the rotational movement of the sleeve 2 relative to the housing 1. The device contains a removable protective casing 23, which is attached to the housing 1 using a decorative sleeve 24, and the housing 1 and the decorative sleeve 24 are mounted with the possibility of their vertical reciprocal movement relative to the installed th analyzed on the sleeve 2 within the body movement of the pin 21 in the slot 20. The apparatus 25 has a detent (pressing means) of the initial position of the bushing 2 in the casing 1, made for example in the form of a spring-loaded button plate having

a braking element 26 installed in the hole in the wall of the housing 1 with the possibility of interaction with the outer surface of the sleeve 2.

The device also contains a nozzle 27 of organic material, for example, plastic, made in the form of a segment of a sphere with a hole 28 in the center and installed between the protrusions 22 of the support 5 and contains a removable membrane 29 made of elastic material and embedded in this nozzle in such a way that it is in contact with the inner surface of the nozzle. The length of the nozzle opening is equal to the distance between the inner surfaces of the protrusions 22 of the support 5.

Common features of the proposed device for measuring intraocular pressure and the device of the prototype are: a housing inside which a movable sleeve with guides is mounted, a rod mounted with the possibility of elastic deformation of the measured organ, a support with protrusions in its lower part, and the protrusions are equidistant from the axis of the rod at a distance equal to 7-10 mm, a microprocessor, a linear rod displacement transducer connected to the microprocessor, a sensor for the angular deviation of the axis of free fall of the rod from ticked mounted horizontally on the circuit board, perpendicular to the axis of the stem falls and coupled through a microprocessor with means forming a sound or light signal, reminders stem axis position of incidence in the measurement.

Distinctive features are that the device is additionally equipped with a nozzle made of organic material installed between the projections of the support and made in the form of a segment of a sphere with a hole in the center and a removable membrane of elastic elastic material embedded in the nozzle in such a way that it contacts the inner surface of the nozzle, moreover, the length of the nozzle opening is equal to the distance between the inner surfaces of the projections of the support. As organic material for the nozzle, plastic is used, and as

elastic elastic material for a removable membrane - latex 0.15 mm thick.

The execution of the nozzle 27 in the form of a segment of the sphere determines the anatomy of the structure of the eyeball. The diameter of the circumference of the segment of the sphere (nozzle) is approximately 24 mm (plus or minus 1 mm is allowed), which brings it closer to the size of the eyeball. The length of the hole 28 of the nozzle 27 is equal to the distance between the inner surfaces of the protrusions 22 of the support 5. The manufacture of the nozzle, for example, of plastic, provides a convenient and quick disinfection of it, after measuring the pressure.

A removable membrane 29 protects the stem 8 from contamination when in contact with the cornea. The implementation of the membrane from an elastic material, for example, latex allows you to simulate to some extent the soft tissues of the upper eyelid, to ensure the fixation of the sphere and tight fit to the cornea of the eye when measuring pressure. In addition, the latex material is convenient for quick disinfection.

The claimed combination of features of a device for measuring intraocular pressure (common with the prototype and distinctive) allows to ensure the accuracy of measurement of intraocular pressure of dead organisms; the possibility of the most correct comparison of the measurement results when monitoring changes in intraocular pressure to determine the age of death; reduce the orientation time of the device to enable the most correct comparison of measurement results; also ensure the use of the device for any changes in eyelid tissue and improve consumer properties, in particular, comfort, convenience and simplification of operation.

A device for measuring intraocular pressure works as follows.

Preliminarily, a removable membrane 29 is laid in the nozzle 27 with the hole 28 so that it contacts the inner

the surface of the nozzle, and then install the nozzle in the device between the protrusions 22 of the support 5. If necessary, you can fix the segment of the sphere (nozzle 27) with the contact surfaces 6 of the support 5 using glue "Super-moment".

Before measuring the eyelid with an expander, open the eyeball.

The protective removable casing, which is attached to the housing 1 by means of a decorative sleeve 24, together with the housing are mounted with the possibility of their vertical reciprocal movement relative to the sleeve 2 mounted on the investigated organ within the movement of the pin 17 in the slot 20.

The latch 25 (clamping means) of the initial position of the sleeve 2 in the housing 1 is made, for example, in the form of a spring-loaded button and has a braking element 26 installed in the hole in the wall of the housing 1 with the possibility of interaction with the outer surface of the sleeve 2. Hold the button 25 the lower position of the sleeve 2 when installing the rod 8 in its original position by tipping the protective casing (and the housing 1) with the lower part of the support 5 up and when installing the device on the eyelid of the patient.

Holding the device by the casing 23, while holding the button of the latch 25 to exclude the possibility of premature exit of the rod 8 from its original position, the support 5, namely its protrusions 22 with the nozzle 27 and a removable membrane 29 are installed on the soft membrane of the cornea.

The contact surface of the 6 protrusions is equidistant from the axis 7 of the rod 8 at a distance of "L" equal to 7-10 mm

Since the axis 7 of the rod 8 should be located vertically and pass through the center of the eye block, the deviation of the axis of incidence of the rod from the vertical is determined using the sensor 12 of the angular deviation of axis 7. If the axis 7 deviates from the vertical by 2-6 degrees

indicate the incorrect position of the device by turning on the reminder signal, since the sensor 12 is connected via a microprocessor to means for generating an audio or light reminder signal. The measuring device with a light reminder signal is additionally equipped with a corresponding LED (not shown in FIG. 1) located on the outside of the casing 23. The incorrect position of the axis 7 is corrected to the correct (working) state by the angular displacement of the casing 1 (respectively, casing 23) of the measuring device when fixed support 5.

When the operating position is reached, the indicated reminder signal is accordingly turned off. Thus, the incorrect position of the device is accompanied by the inclusion of a reminder signal, and the correct position is turned off. A variant is possible when, on the contrary, the correct position of the device is accompanied by the inclusion of a reminder signal, and the wrong one is when it is turned off. An audio signal reminder is generated, for example, using a miniature indicator-sensor of an audio signal that occurs when the specified value of the signal from the sensor 12 of the angular deviation of the axis 7, mounted on the board 13 in a horizontal position.

The microprocessor is connected to a measuring transducer located on the printed circuit board 14 of the device and includes a generator, a data processing unit and an electromagnetic coil 15 connected to the generator, fixed in the sleeve 2 between the rails 3 and 4.

The holder 11 of the rod 8, on the side surface, in the initial position is a spring-loaded latch plate with a conical hole for gripping the upper end of the rod 8 and with a bevel 16 on the side surface. The pin 17, mounted in the wall of the housing 1 is the drive for horizontal movement of the latch plate, spring-loaded with a wire element 18, built into the walls of the sleeve 2 and

located in the corresponding hole of the latch plate. For reliable fixation in the hole of the latch plate, the upper end of the rod 8 is made with a stop 19.

The rod 8 is installed in the holes of the guides 3, 4 with a gap of 0.05-0.1 mm to allow the rod to fall under the action of its own weight in the cavity of the sleeve 2. Having released the latch button 25, they translate downwardly into the protective casing 23. In this case, the plate the latch of the holder 11 of the rod 8 is displaced horizontally in the cavity of the movable sleeve 2, the stop 19 is released and the rod freely falls into the guides 3 and 4 on the patient’s expanded eyeball.

When the device is oriented along the vertical axis in one direction (the working position, when the lower part of the support 5 (protrusions 22) of the sleeve 2 is at the bottom, and the rod 8 is fixed in the holder 11 in its original position) and in the other direction (when the rod 8 is returned to its original position, after measurement). In the vertical slot 20 made in the housing 1, a second pin 21 is mounted, mounted on the sleeve 2 to limit the vertical reciprocating and rotational movement of the sleeve 2 relative to the housing 1.

When the device moves down, the release of the rod 8 occurs when the second pin 21 is placed in the middle of the slot 20, which in turn ensures a constant statistical load on the eye through the eyelid from the side of the device. The displacement of the latch plate occurs due to a change in the position of the pin 17 when the protective casing 23 moves downward. When the stem 8 falls, its base 10 through the opening 28 of the nozzle 27 and the latex membrane 29 deforms the eyelid and eye, and then bounces in the opposite direction. The length of the hole 28 of the nozzle 27 is equal to the distance between the inner surfaces 6 of the protrusions 22 of the support 5. The means 9 of the movement restriction located on the rod 8, passing down (when the rod 8 falls) and up (when the rod 8 bounces), creates a change

the inductance of the electromagnetic coil 15, leading to a change in the frequency of the generator. Means 9 of restricting movement is made, for example, of ferrite material or brass and is located in the cavity of the sleeve 2 (in the initial position) above the electromagnetic coil 15 and is its core.

Frequency changes are recorded in time by the processing unit and converted into the displacement of the rod 8 relative to the movable sleeve 2. According to the parameters of the time displacement function of the freely falling rod 8, the intraocular pressure (IOP) is judged, for example, by the amplitude of the first rebound or other known method of processing functions .

Preparing the device for the next measurement is as follows. Holding the device by the casing 23 with the support 5 down, press the latch button 25 and then tilt the casing 23 with the support 5 up. The rod 8, moving under its own weight, engages its focus 19 with the plate - latch and is fixed. Then return the device to its original position (support 5 down). Measurement time no more than 2.5-3 sec.

After measuring the intraocular pressure, the nozzle is sanitized by treatment with alcohol, and the membrane with 1% anaminol if it is reusable.

Claims (3)

1. Device for measuring intraocular pressure, comprising a housing inside which a movable sleeve with guides is mounted, a rod mounted with the possibility of elastic deformation of the measured organ, a support with protrusions in its lower part, the protrusions being equidistant from the stem axis at a distance of 7-10 mm, microprocessor, linear rod displacement transducer connected to the microprocessor, angular deviation sensor of the axis of free fall of the rod from the vertical, mounted horizontally on the board, located perpendicular to the axis of incidence of the rod and connected through a microprocessor with means for generating an audible or light signal-reminder of the position of the axis of incidence of the rod during measurement, characterized in that the device is additionally equipped with a nozzle made of organic material installed between the projections of the support and made in the form of a sphere segment with a hole in the center and a removable membrane of elastic elastic material embedded in the nozzle in such a way that it is in contact with the inner surface of the nozzle, and and nozzle holes equal to the distance between the inner surfaces of the support protrusions. 2. The device according to claim 1, characterized in that plastic is used as the organic material for the nozzle. 3. The device according to claim 1, characterized in that as a flexible elastic material for a removable membrane using latex with a thickness of 0.15 mm