RU2099000C1 - Apparatus for measuring intraocular pressure - Google Patents

Abstract

FIELD: medical engineering; diagnostics of glaucoma cases; conduct of mass-scale preventive examination of people to detect diseases of vision organs; checks to determine whether treatment of eye diseases is correct. SUBSTANCE: proposed apparatus represents conventional apparatus for measuring intraocular pressure, and comprises casing, sleeve with supporting portion, and element for applying deformation to eye through eyelid. This deformation applying element is made in form of rod having ferrite cell. Deformation applying element also comprises rod holder in its upper initial position, measuring converter made in form of generator, data processing unit connected with electromagnetic coil, core of which is constituted by ferrite cell of rod. Sleeve is housed by casing and is capable of performing therein limited reciprocating movement to provide constant predetermined load. Sleeve also comprises guideways adapted to direct movements of rod. Latter is capable of dropping by sliding along guideways under effect of its own gravity. Thus, rod constitutes element providing percussive load. Lower guideway forms limiter of lower position of rod in interior cavity of sleeve, when apparatus is in its idle position. EFFECT: 1) structural simplicity; 2) high accuracy and rapidity of intraocular pressure measurements; 3) possibility to automatically monitor intraocular pressure variations in course of treatment; 4) convenience in handling for both patient and operator, since it takes less time to make manipulations on patient's eye; 5) no anaesthesia is required. 6 cl, 3 dwg

Description

 The invention relates to medical equipment, namely, equipment used in ophthalmology for the study of intraocular pressure (IOP) and can be widely used in medical polyclinics in the diagnosis of glaucoma, conducting mass preventive examinations of the population in order to detect diseases of the organs of vision, for early diagnosis and control of the correct treatment of eye diseases.

Known tonometer indicator for measuring and indicating intraocular pressure, comprising a housing, a reading device and an element for deforming the cornea of the eye through the eyelid in the form of a ball placed in a housing with a transparent working part with the possibility of free fall inside it and held in the upper inoperative state using the holder fixed in the upper part of the body, while the lower position of the ball is attached to the lower part of the body, while the reading device is made on a transparent working part orpusa a scale along a longitudinal axis of this part and separated longitudinally into three portions corresponding to elevated intraocular pressure in the normal range and reduced [1]
The operation of this device is based on the principle of the correlation between the intraocular pressure and the height of the first bounce of the falling ball of a certain diameter and mass from the surface of the eye in the area of the cornea covered by the eyelid.

 The bounce height of the ball is visually fixed by the person making the measurement on the reading scale. In this regard, the device has low measurement accuracy and is not convenient for the operator during mass examinations (with numerous measurements), since increased attention is required to record the measurement results.

 The disadvantage of this device is the accuracy of measuring IOP. The accuracy of the measurement is largely affected by the operator, since the measurement result is recorded visually and not automatically.

A device for determining intraocular pressure, containing loading devices for creating pressure on the eye tissue in the abutment position, a device for communicating a mechanical shock to the probe and devices for measuring the amount of force transmitted by the loading device as a result of the reaction of the eye tissue to the push [2]
The advantage of the device is the short duration of the application of significant eye strain. However, it reduces performance due to the need to bring the probe to the stop position. The device is structurally complex.

 Known impression methods for measuring IOP, based on measuring the degree of indentation of the eye shell with a plunger. The magnitude of this indentation is judged on the degree of IOP.

A device for examining the sclera and cornea of the eye is known, comprising a plunger with a rod and an associated pressure metering mechanism in the form of two interconnected circuits, one of which is made in the form of a pressure metering control circuit and contains a permanent magnet located in the hole of an electromagnetic coil mounted on a frame connected to a power voltage generator and through a first analog-to-digital converter with a pressure value recorder, the second circuit being it is in the form of a contour for measuring the movement of a plunger containing a reflector rigidly connected through the frame of the electromagnetic coil to the rod and optically mounted between an LED connected to a reference voltage generator and a photodiode connected to a series-connected photo-current amplifier, an amplitude detector, a second analog-to-digital converter, and the plunger movement recorder. In the dosing circuit of the pressure value, the permanent magnet is supplemented by a magnetic circuit, in the gap of which there is an electromagnetic coil rigidly connected through the frame to the rod, while the frame is mounted in suspensions with the possibility of linear movement [3]
A device for measuring intraocular pressure, holding the body with the lower, upper and supporting parts, the corneal deformation element through the eyelid, made in the form of a plunger with a ferrite element with interchangeable weights, mounted with the ability to move in the bearings, the rod holder in the initial upper non-working position, measuring Converter made in the form of a generator, a data processing unit associated with an electromagnetic coil, the core of which is a ferrite element of the plunger [4]
In this device, the rod with its lower end surface by the action of its mass deforms the surface of the cornea of the eye. the magnitude of the deformation, i.e., the depth of the indentation of the rod, is determined by the value of the IOP and is its measure, expressed in arbitrary units of Schiotz.

A device for measuring intraocular pressure, comprising a housing, a movable sleeve, an element of the corneal deformity through the eyelid, made in the form of a plunger with a ferrite element with interchangeable weights, mounted for movement in bearings, a rod holder in its original upper non-working position using an electromagnetic coil, measuring a converter made in the form of a generator, a data processing unit associated with an electromagnetic coil, the core of which is a ferrite element plun EPA [5]
The advantage of these devices is the use of electronic automation for measuring IOP.

 The disadvantages of these analogues and the prototype is that they require the use of increased loads for deformation of the eye, to provide the required measurement accuracy, with low speed, as they provide longer manipulations on the eye than the device [1] using the rebound of the deformation element. Due to the large force of pressure on the eye (10-60 g) and the complexity of the tonometry method, as well as the complexity of the design, such devices are not widely used.

 the invention solves the problem of improving the accuracy and speed of measuring IOP while ensuring simplicity of design and convenient measurement procedure (by reducing the time of exposure to eye strain and using automation to control IOP by the dynamics of the movement of the eye deformation element over time).

где m масса штока с ферритовым элементом;
S площадь поперечного сечения нижней части штока;
h высота размещения нижней части штока в полости втулки в исходном положении.This object is achieved by the fact that in the device for measuring intraocular pressure, comprising a housing, a sleeve with a supporting part, a deformation element of the investigated organ through the eyelid, made in the form of a rod with a ferrite element, the rod holder in its initial upper position, a measuring transducer made in the form of a generator , a data processing unit associated with an electromagnetic coil, the core of which is a ferrite rod element, the sleeve is placed in the housing with the possibility of limited reciprocation of moving in it to create a constant predetermined load and is equipped with guides for the rod, the rod holder is located in the upper part of the sleeve cavity, the rod is installed in the sleeve cavity with the possibility of falling in the guides under its own weight and is an element of shock load, the electromagnetic coil of the measuring transducer is fixed in the sleeve between the rails, the lower guide is a limiter of the lower position of the rod in the cavity of the sleeve in the idle position of the device. Preferably, the mass, height of the rod and the geometric dimensions of its lower part should be chosen so that the condition is met:

where m is the mass of the rod with a ferrite element;
S is the cross-sectional area of the lower part of the stem;
h the height of the lower part of the rod in the cavity of the sleeve in its original position.

 It is advisable to make the rod holder in the form of a spring-loaded latch plate with a hole for gripping the upper end of the rod and a pin fixed in its end surface and passing through the corresponding hole in the housing, the pin being the drive for horizontal movement of the latch plate. In this case, the upper end of the rod can be performed, for example, with a stop for its reliable grip.

 It is advisable to make a vertical slot in the housing, and to fix a pin-pointer on the sleeve by installing it in the specified vertical slot to limit the reciprocating movement of the sleeve in the housing.

 It is preferable to make marks on the end of the index pin and on the housing, the mark on the housing being an indicator of the center of the vertical slot.

 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 mechanical 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 solution meets the criterion of "inventive step".

 In FIG. 1 shows the design of the device; in FIG. 2, view A in FIG. one; in FIG. Figure 3 shows the dependence of the change in the frequency of the generator during the fall and rebound of the rod in the cavity of the sleeve over time.

 The pressure measuring device comprises a housing 1, a sleeve 2, placed in the housing 1 with the possibility of limited vertical reciprocating movement to create a constant predetermined load, a rod 3 with a ferrite element 4, a spring holder 5, the rod holder 6 in the initial position, located in the upper part cavity of the sleeve 2, the first guide 7 for the rod 3, made, in particular, in the form of a washer mounted on the walls of the sleeve 2, the second guide for the rod 3, made, in particular, in the form of a washer 8, the support there are 9 sleeves 2, a measuring transducer made in the form of a generator 10 and a data processing unit 11 connected to an electromagnetic coil 12 fixed in the sleeve 2 between the guides 7, 8. In this case, the ferrite element 4 of the rod 3 is located in the cavity of the sleeve above the coil 12 and is her core. The rod 3 is installed in the holes of the guides 7, 8 with a gap of 0.1 0.2 mm, while it is possible to drop the rod under the action of its own weight in the cavity of the sleeve when the device is oriented along the vertical axis in one direction (working position, when the supporting part of the sleeve below, and the rod is fixed in the holder 6 in its original position) and in the other direction (when the rod returns after measurement to its original position). The lower guide 8 is a limiter for the lower position of the rod 3 in the cavity of the sleeve 2. The holder of the rod 3 in the initial position is the latch plate 6 with an opening for capturing the upper end of the rod 3. The pin 13 is the horizontal drive of the spring-loaded latch plate 6. The latch plate 6 spring-loaded using a wire element 5, built into the walls of the sleeve 2 and located in the corresponding hole of the latch plate 6.

 In the housing 1, a vertical slot 14 is made in which a pin-pointer 15 is mounted, mounted on the sleeve 2 to limit the vertical reciprocating movement of the sleeve 2 in the housing 1.

 On the end of the pin-pointer 15 and on the housing 1, marks 16, 17 are made, while the mark 17 on the housing 1 is a pointer to the center of the vertical slot 14.

 To reduce the mechanical effect on the eye, the rod 3 in the final part 18 may have, in particular, a smaller cross-sectional area.

Величина нижнего предела в указанном соотношении ограничена требованиями к погрешности измерения ВГД (чувствительностью электронной части устройства к изменению индуктивности электромагнитной катушки, соответствующей деформации исследуемого органа в результате ударной нагрузки при падении штока): при более низком значении погрешность измерения увеличивается.The mass (m) of the rod 3 (together with the ferrite element), the cross-sectional area (S) of the lower part 18 (with the detector d) of the rod 3, the height (h) of the placement of the lower part 18 of the rod 3 in the cavity of the sleeve in the initial position of the device are selected from the following ratio:

The value of the lower limit in the indicated ratio is limited by the requirements for the IOP measurement error (the sensitivity of the electronic part of the device to a change in the inductance of the electromagnetic coil, corresponding to the deformation of the organ under investigation as a result of shock loading when the rod falls): at a lower value, the measurement error increases.

 The upper limit in the ratio is limited by the permissible degree of mechanical effect on the organ under study: with a higher value, the probability of eye injury sharply increases.

 The upper end of the rod is made, in particular, with a stop 19 for its reliable fixation in the hole of the latch plate.

 The device operates as follows.

 Holding the IOP device for the housing 1, the supporting part 9 of the movable sleeve 2 is mounted vertically on the eyelid closed. In this case, it is necessary to ensure that the pin pointer 16 is located in the middle of the vertical slot 14 of the housing 1, which is achieved by combining the colored marks 16, 17 respectively on the housing 1 and on the index pin 15. Under this condition, the pressure of the housing 1 on the eye is excluded. Then, by briefly pressing the pin 13 ("Start" mode), the latch plate 6, moving horizontally in the cavity of the sleeve 2, releases the stem 3. The rod 3, by gravity, falls into the cavity of the sleeve 2 in the guides 7, 8 in the direction of the eye. Hitting the eye, rod 3 bounces in the opposite direction. In this case, the ferrite element 4 located on the rod 3, passing down (when the rod 3 falls) and up (when the rod 3 bounces) creates a change in the inductance of the electromagnetic coil 12, which is recorded as a changing frequency in the data processing unit 11 (in the electronic part of the device ), is processed and issued on the indicator as a result. Figure 2 presents the curve of the frequency variation of the generator over time during the fall and rebound of the rod 3: section "a" corresponds to the dynamics of the fall of the rod 3 in the cavity of the sleeve 2, the point "b" corresponds to the moment of contact of the lower part 18 of the rod 3 with the investigated organ (eye) , section “in” the curve corresponds to the dynamics of the input and output of the rod 3 from the eye, section “g” to the dynamics of the rod 3 when bouncing after leaving the eye. The shape and dimensions of the "in" section of the curve correspond to IOP.

 Preparation of the device for measuring IOP for the next measurement is as follows. Holding the device by the housing 1, rotate it so that the supporting part 9 of the sleeve 2 is located at the top, while the device is placed vertically. Then the rod 3 falls down under the action of gravity, wring out the spring-loaded latch plate 6, while the end of the rod with a stop 19 enters the hole of the latch plate 6 and is fixed in this position. Then carry out the rotation of the device to the operating position (supporting part 9 down).

 The inventive device provides a measurement of intraocular pressure in millimeters of mercury.

 The proposed technical solution improves the accuracy of IOP measurement and provides the ability to track changes in IOP during treatment.

 The device is convenient in the operation of the patient and the operator, as the duration of manipulations directly on the investigated organ (eyes) is reduced and anesthesia is not required, since the impact on the eye with the stock is short-term and weakly perceptible. High measurement performance is ensured by reducing the time required to install the device in its original position on the eye, to center it and to prepare for work for the next measurement.

 The proposed device has wide diagnostic capabilities by providing a study of the dynamics of entry and exit of the shock element from the eyes using automation and storing the results, which is especially important for monitoring the correct treatment of eye diseases.

 The result of measuring true intraocular pressure is less affected by abnormal corneal regidity, the volume of the eyeball and other factors, since the less the force on the eye, the less its deformation. The device provides a measurement accuracy of +1 mm Hg

 The simplicity of design and measurement technology make it possible to manufacture the device at affordable prices for both individual and clinical applications and reduce the complexity of the measurement process for the operator.

 All this improves consumer properties compared with the prototype, which is especially important for durable medical devices.

Claims (6)

 1. A device for measuring intraocular pressure, comprising a housing, a sleeve with a supporting part, a deformation element of the test organ through the eyelid, made in the form of a rod with a ferrite element, a rod holder in its initial upper position, a measuring transducer made in the form of a generator, a data processing unit, associated with an electromagnetic coil, the core of which is a ferrite rod element, characterized in that the sleeve is placed in the housing with the possibility of limited reciprocating movement I in it to create a constant predetermined load and equipped with guides for the rod, the rod holder is located in the upper part of the sleeve cavity, the rod is installed in the sleeve cavity with the possibility of falling in the guides under the action of its own weight and is an element of shock loading, the electromagnetic coil of the measuring transducer is fixed in the sleeve between the rails, the lower guide is a limiter of the lower position of the rod in the cavity of the sleeve in the idle position of the device. 2. The device according to claim 1, characterized in that the mass, height of the rod and the geometric dimensions of its lower part are selected from the condition
h • m / S (40 90) kg / m,
where m is the mass of the rod with a ferrite element;
S is the cross-sectional area of the lower part of the stem;
h the height of the lower part of the rod in the cavity of the sleeve in its original position.  3. The device according to claim 1, characterized in that the rod holder is made in the form of a spring-loaded horizontal latch plate with a hole for gripping the upper end of the rod and a pin fixed to its end surface and passing through the corresponding hole in the housing, wherein the pin It drives horizontal movement of the latch plate.  4. The device according to PP.1 and 3, characterized in that the upper end of the rod is made with emphasis for interaction with the plate-latch.  5. The device according to claim 1, characterized in that the housing has a vertical slot, and a pin-pointer is mounted on the sleeve, mounted in the specified vertical slot to limit the reciprocating movement of the sleeve in the housing.  6. The device according to claims 1 and 5, characterized in that the marks are made on the end part of the index pin and on the housing, while the mark on the housing is an indicator of the center of the vertical slot.

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