RU2302191C1 - Tonometer for self-measurement of intraeye pressure through lid - Google Patents

Abstract

FIELD: medicine; ophthalmology; surgery; neurological traumatology; neurology.

SUBSTANCE: tonometer can be used for non-invasive measurement of intraeye pressure through lid by express method, for checking rightness of glaucoma treatment, for individual control of intraeye pressure without using analgesics. Tonometer has protection casing with case, movable bushing mounted in tonometer, which bushing has guides and support. Contact area of support is disposed at distance of 7-10 mm from axis of motion of free falling body made for resilient deformation of organ through lid; measuring converter of body's linear movement, which converter is connected with microprocessor. Tonometer has removable holder with mirror and support post for head to keep the latter at proper position, detector for checking angular deflection of axis of motion of freely falling body from vertical line. Detector is connected with aids for forming sonic or light signal-warning on position of axis of motion of freely falling body during measurement; detector is connected with the aids through microprocessor. Removable holder is made for movement along protecting casing and for fixation at working position to perform visual control of mutual position of end of lid, limb of eye and support in mirror.

EFFECT: improved precision of measurement.

4 cl, 9 dwg

Description

The invention relates to medicine and can be used in ophthalmology, surgery, neurosurgery, neurotraumatology, neurology and other medical fields for non-invasive measurement of intraocular pressure through the eyelid by the express method, monitoring the correct treatment of glaucoma, individual monitoring by the patient of intraocular pressure (IOP) without pain relief eyes.

A device for measuring intraocular pressure, comprising a housing with a sleeve housed therein with the possibility of limited reciprocating movement, provided with guides and a supporting part for creating 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 original upper floor However, located in the upper part of the sleeve cavity, a measuring transducer for linear displacement of the deformation element, wherein the supporting part of the sleeve is made with two protrusions with rounded support ends equidistant to a distance of 7-10 mm from the axis of movement of the freely falling body, the deformation element is made in the form of a rod with the end portion for contact with the eyelid of no less than 3 mm with a flat base area of 1-7 mm ^2, the lower guide stopper is lower position in the cavity deformation element vtulit and in an inoperative position (see. RF patent 2123798, cl. A61B 3/16, publ. 1998 - prototype).

The disadvantages of the known devices with a freely falling body are:

- the need to involve medical personnel for measurements, which makes the process of diagnosis and treatment more expensive;

- low measurement accuracy due to the lack of signaling devices of the correct working position of the device;

- duration of measurement.

The absence of analogs of control means for the correct working position of the measuring tonometer body requires constant attention of the operator (medical personnel) to subjective assessment of the verticality of the tonometer (otherwise, to ensure the reliability of the measurement result), which is long and inefficient. In this case, the user's discomfort and the need to perform several measurements are not excluded.

Thus, the main disadvantage of the prototype is the lack of the possibility of self-monitoring and self-diagnosis, which is important for timely assessment of the condition of ocular pathological processes, early diagnosis, monitoring the treatment process.

The present invention solves the problem of creating a tonometer for independent measurement of IOP by a patient without involving medical personnel, increasing the speed and accuracy of measurement by simplifying the orientation of the tonometer in the working position during measurement and using visual and sound (or light) control of the correctness of the tonometer position during measurement.

The technical result of the invention is to increase the efficiency and reliability of the conclusions by the patient with regard to the state of the visual organ, in the universality of its use, in improving measurement accuracy, in simplifying operation, in improving its consumer properties (comfort and ease of use, stability of parameters) by eliminating the influence of inaccuracy in the installation of the housing tonometer when measuring.

The technical result of the invention is achieved by the fact that in a measuring tonometer for independent measurement of intraocular pressure through the eyelid, containing a protective casing with a housing, a movable sleeve with guides and a support installed in the housing, the contact surface of which is located at a distance of 7-10 mm from the axis of movement of the freely falling body made with the possibility of elastic deformation of the body through the eyelid, a linear body displacement transducer connected to the microprocessor, a removable holder is introduced atelier with a mirror and a support stand for emphasis on the forehead in the working position, a sensor for monitoring the angular deviation of the axis of movement of the freely falling body from the vertical, connected via a microprocessor with means for generating an audio or light signal reminding the position of the axis of movement of the freely falling body during measurement, while the removable holder is made with the possibility of moving along the protective casing and fixing in the working position for visual inspection in the mirror of the relative position of the eyelid edge, eye limb and support.

Preferably, the holder is in the form of a clamp with a cam clip.

It is advisable to install the sensor horizontally on a board located perpendicular to the axis of movement of the freely falling body.

Preferably, the body is made in the form of a rod with a flat base with an area of 1-7 mm ² .

The essence of the invention is to create a design that allows the patient to carry out self-monitoring (self-diagnosis) by timely assessment of the condition of ocular pathological processes, which is important at the stage of early diagnosis and in the treatment process.

The analysis of the prior art, including a search by patent and scientific and technical sources of information and identification of sources 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 the essential features of the claimed invention. The definition 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 applicable 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 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".

Figure 1 presents a tonometer (without a removable holder), in section; figure 2 shows the tonometer from the side (without the front of the protective casing and a removable holder); figure 3 depicts a tonometer on the front side (without the front of the protective casing and a removable holder); figure 4 depicts a tonometer with a removable holder (front view); 5 depicts a tonometer with a removable holder (side view); Fig.6 depicts an enlarged fragment A of Fig.6; Fig.7 depicts a tonometer with a removable holder (top view); on Fig - visible in the mirror relative position of the limb, ciliary edge of the eyelid of the eye and tonometer when measuring IOP; figure 9 shows the eye in section with a tonometer installed in the working position.

The tonometer for self-measurement of intraocular pressure through the eyelid is an upgrade of the manufactured TDc-01 "PRA" tonometer and includes (Figs. 1, 2, 3) a movable sleeve 2 installed in the housing 1 (made with the possibility of limited vertical reciprocating movement) from the first guide 3, the second guide 4, made integral with the movable sleeve 2, and the support 5, the contact surface 6 of which is located at a distance (L) from the axis 7 of the free fall of the body, which is a rod 8. The distance L d I versatility tonometer is advisable to choose in the range of 7-10 mm, like in the prior art, while providing the opportunity to IOP measurements with the required accuracy. The rod 8 has a means 9 of restricting its movement and a flat base 10 with an area of 1-7 mm ² for elastic deformation of the organ through its skin, the range of which eliminates the painfulness of the measurement procedure. The holder 11 of the rod 8 in the initial position is made in the form of a spring-loaded plate-latch. The measuring tonometer also contains a sensor 12 for the angular deviation of the axis 7 of the free fall of the rod 8 from the vertical, mounted horizontally on a board 13 located perpendicular to the axis of incidence 7 of the body, and connected via a microprocessor to means for generating an audio or light reminder signal (not shown in FIG. ) about the position of the axis 7 of the fall of the body when measuring. The measuring transducer of linear movement of the body (not shown in FIG.) Is connected to the microprocessor and placed on the printed circuit board 14 of the measuring tonometer. The specified measuring transducer has a generator, a data processing unit (not shown in Fig.) And an electromagnetic coil 15 connected to the generator, fixed in the sleeve 2 between the first and second guides 3, 4.

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 when the device is oriented along the vertical axis in one direction (working position, when the bearing 5 of the sleeve 2 below, 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 after measurement to its original position). In this case, the tool 9 for restricting the movement of the rod 8 is made, for example, of ferrite material or brass, is located in the cavity of the sleeve 2 in the initial position above the coil 15 and is its core.

The holder 11 of the rod 8 in the initial position is a 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 spring-loaded latch plate when it is vertically moved down the surface of the bevel 16 when moving down the housing 1. The latch plate is spring-loaded using a wire element 18 integrated in the walls of the sleeve 2 and located in corresponding hole of the latch plate. The upper end of the rod 8 is made with a stop 19 for its reliable fixation in the hole of the latch plate.

In the housing 1, a vertical slot 20 is made, in which a pin 21 is mounted, mounted on the sleeve 2 to limit the vertical reciprocating and exclude the rotational movement of the sleeve 2 relative to the housing 1.

The support 5 is mounted on the lower part of the first guide 3 of the sleeve 2, for example, by means of a spring-clip connection, and is made with two wedge-shaped protrusions 22 with rounded support ends equidistant to a distance L equal to 7-10 mm from the axis of movement of the rod 8.

The housing 1 can be placed (in a removable) protective casing 23, rigidly connected to the housing 1 by means of a decorative sleeve 24. In this case, the protective casing 23 and the housing 1 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 21 in the slot 20.

The tonometer is equipped with a latch (clamping means) of the initial position of the sleeve 2 in the housing 1. The latch can be made, for example, in the form of a button spring-loaded with a plate 25, the braking part 26 of which is installed in the hole in the wall of the housing 1 with the possibility of interaction with the outer surface of the sleeve 2 . By pressing the spring-loaded button 25 of the lock ensure that the sleeve 2 is held in the lower position when the rod 8 is installed in its original position by tilting the protective casing (and case 1) with the support 5 up and when installing the device on and the eyelid of the patient. To indicate the results, a display 27 is used, mounted in a protective casing 23.

On the protective casing 23 is fixed (Fig. 4, 5, 7) a removable holder for the mirror 28 and the support column 29 for emphasis on the forehead in the working position. The removable holder is a collar 30 with a cam-clamp 31. The mirror 28 and the support stand 29 on the forehead are connected to the specified clamp 31 so that in the working position when the support stand 29 is installed on the patient’s forehead in the mirror 28, visual control of the relative position of the ciliary edge is possible 32 century and limb 33 eyes (Fig.8), as well as the front rib 34 of the upper eyelid, tonometer support 5 in the working position (Fig.8, 9).

Since the axis 7 of the fall of the rod 8 should be located vertically and pass through the center of the eyeball, preliminary determination of the deviation of the axis of incidence of the body from the vertical using the sensor 12 of the angular deviation of axis 7. When the deviation of the specified axis 7 from the vertical by 2-6 degrees indicate incorrect position of the measuring tonometer with the inclusion of a reminder signal, since the indicated sensor 12 is connected via a microprocessor to means for generating an audio or light reminder signal.

The tonometer with a reminder light additionally has a corresponding LED (not shown in Fig.) On the outside of the casing 23. The incorrect position is corrected to the working (correct) state by the angular displacement of the tonometer body 1 (respectively, casing 23) when the support 5 is fixedly mounted. Upon reaching operating position, respectively, turn off the specified reminder signal. Thus, the incorrect position of the measuring tonometer is accompanied by the inclusion of a reminder signal, and the correct position is turned off. Another option is possible, when, on the contrary, the correct position of the measuring tonometer is accompanied by the inclusion of a reminder signal, and the wrong one - by turning it off.

An audio signal 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.

A tonometer for independent measurement of intraocular pressure through the eyelid, for example, with a reminder signal in the form of an audio signal, works as follows. When measuring intraocular pressure, the patient is placed face up. Measurement of intraocular pressure is carried out by the patient independently in a lying or sitting position. To use the tonometer, the patient individually adjusts the position of the support column 29 and the mirror 28 by moving the clamp 30 (Fig.6) on the protective casing 23 to take into account the anatomical features of his head. To do this, he moves the clamp 30 along the protective casing 23 until the limb 33 eyes and tonometer support 5 are displayed in the mirror of the 28th century. In this position, the clamp 30 is fixed by a cam-clamp 31 on the protective casing 23.

To measure IOP, the patient spreads the upper eyelid with one hand, without stretching it and without putting pressure on the eyeball, so that the edge of the upper eyelid coincides with the upper edge of the limbus of the 33 eyes. In this case, the viewing direction is set for deformation of the eye in the sclera at approximately an angle of 45 ° to the horizon. Then the patient sets the support stand 29 of the included tonometer on his forehead, while the rod 8 fixed in the holder 11 is located in the initial position.

Holding the measuring tonometer by its casing 23, with the clamp button 25 pressed to exclude the possibility of premature stem 3 exit from its initial position, the support 5 is mounted on the upper eyelid region with protrusions 22 in the area of its cartilage symmetrically to the center of the eyeball. At the same time, the patient, looking in the mirror 28, brings the tonometer support 5 closer to the eyelid, orients the tonometer vertically with the angular displacement of the protective casing 23 until the discontinuous sound signal ceases, and sets the protrusions 22 of the support 5 on the cartilaginous part of the 35th century close to the front rib 34 and parallel to it, as this is shown in Fig.9. In this case, the tonometer should maintain a vertical position (the absence of a sound signal indicates the correct position of the tonometer). The area of influence of the rod 8 of the tonometer should be in the area of the sclera corresponding to corona ciliaris.

Then, releasing the latch button 25, a smooth translational downward movement of the protective casing 23 is performed. In this case, the latch plate of the holder 11 of the rod 8 is displaced horizontally in the cavity of the movable sleeve 2, releases the stop 19 and the rod 8 freely falls in the guides 4 and 3 onto the eyelid of the examined eye the patient. When the casing 23 moves down, the rod is released when the pin 21 is placed in the middle of the slot 20, which 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 moving down the protective casing 23. When falling, the rod 8 deforms the eyelid and eye with its base, and then bounces in the opposite direction. In this case, the displacement limiting means 9 located on the rod 8, passing down (when the rod 8 falls) and up (when the rod 8 bounces) creates a change in the inductance of the electromagnetic coil 15, leading to a change in the frequency of the generator. These frequency changes are recorded in time by the processing unit and are 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 A of the first rebound or by another known method processing functions.

The preparation of the measuring tonometer for the next measurement is as follows. Holding 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 latch plate and is fixed. Then, the tonometer is returned to its original position (bearing 5 down).

When measuring, it is necessary to maintain the vertical position of the tonometer (there is no intermittent sound signal) until the rod 8 falls onto the eyelid, accompanied by a short sound signal, and also not to allow the eyelid to move to the cornea at the time of measurement and pressing the tonometer on the eyeball.

The tonometer display 27 shows the serial number of a single measurement. After the measurement, the tonometer is removed from the eye and the rod 8 is set to its initial position (figure 1).

During the measurement, an intermittent sound signal informs about the deviation of the tonometer from the vertical at the time of measurement, in which case the serial number of a single measurement on the display is accompanied by a symbol, for example, "L". Subsequent measurements are carried out in the vertical position of the tonometer. Several measurements of IOP of the same eye are carried out with an interval of not more than 30 seconds. If the measurement is correct, the display will show, for example, the symbol "A" and the average IOP in non-flashing mode. The result is considered reliable, the IOP of the examined eye is completed.

A significant difference of the proposed tonometer is the simplicity of its application. The IOP tonometer with the control of the correct orientation during measurement is convenient due to the combination of all elements in one case with overall dimensions of not more than 174 × 26 × 20 mm and weighing not more than 90 g. The proposed type of signaling about the incorrect orientation of the device during measurement has sufficient information content and is active character.

The proposed tonometer is characterized by the informative accuracy of the position of the axis of incidence of the rod during the measurement of IOP, which increases the accuracy and speed of measurement. The IOP measurement procedure is painless and does not require pain relief. Provides a measurement of intraocular pressure in mm RT.article. with an accuracy of +/- 0.4 mm Hg Measurement time no more than 3 s.

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 absence of direct contact with an organ, for example, the mucous membrane of the eye.

The versatility and simplicity of the claimed tonometer design 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 provides the ability to independently monitor changes in pressure during treatment. The advantages of the device are:

- there is the possibility of measuring IOP by the patient himself and eliminates the need to involve medical personnel for measurement;

- application in any conditions;

- improving the consumer properties of the device (comfort, usability, stability of parameters) due to the active form of the alarm in the form of sound or light signals that persist during improper installation of the device before measuring IOP;

- simplification of the operation of the device.

Claims (4)

1. A tonometer for self-measurement of intraocular pressure through the eyelid, comprising a protective casing with a housing, a movable sleeve with guides and a support mounted in the housing, the contact surface of which is located at a distance of 7-10 mm from the axis of movement of a freely falling body, made with the possibility of elastic deformation of the body through the eyelid, a linear body displacement transducer connected to a microprocessor, characterized in that a removable holder with a mirror and a support stand are inserted for emphasizing l b in the working position, a sensor for monitoring the angular deviation of the axis of movement of the freely falling body from the vertical, connected via a microprocessor with means for generating an audio or light signal-reminder of the position of the axis of movement of the freely falling body during measurement, while the removable holder is made to move along the protective casing and fixation in the working position for visual control in the mirror of the mutual position of the edge of the eyelid, limb of the eye and support. 2. The tonometer according to claim 1, characterized in that the holder is a clamp with a cam clip. 3. The tonometer according to claim 1, characterized in that the sensor is mounted horizontally on a board located perpendicular to the axis of movement of the freely falling body. 4. The tonometer according to claim 1, characterized in that the body is a rod with a flat base with an area of 1-7 mm ² .

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