RU2043070C1 - Tonometer-indicator for measuring intraocular pressure - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: device has ball retention unit being cylindric cap under which a ring rigidly attached to the cylindric casing is mounted, permanent magnets mounted in the ring are engageable with the ball and pusher is attached to the cylindric cap with its one end and the other end being provided with a nozzle having the ball inside. The cover and pusher are movable along the longitudinal axis. The cylindric cap is provided with a ring being movable relative to the longitudinal axis in oscillatory mode. EFFECT: enhanced accuracy in measuring intraocular pressure. 3 dwg

Description

 The invention relates to medicine, namely to ophthalmology, and can be used for measuring and indicating intraocular pressure for prophylactic purposes for the detection of glaucoma diseases at an early stage, as well as for individual use in everyday life when monitoring intraocular pressure.

 Known eye tonometer indicator, containing a transparent body, an element for applying force to the cornea of the eye through the eyelid, namely a freely falling ball, a device for holding the ball in its original position and a scale applied to the body (German patent N 4121713, class A 61 B 3 / 16, 1992).

 However, this tonometer design has significant drawbacks. This applies primarily to the device for holding the ball in the upper idle state and lowering it to produce an impact on the anterior chamber of the eye through the eyelid. Naturally, the force of pressing the spring shutter, rigidly connected with the body of the device, is transmitted to the patient's eye, causing an increase in its intraocular effect. This leads to the fact that the component by the hand of the operator making the measurement, in the process of holding the device and acting on the structural element that releases the ball, acts on the measurement object. All this is the reason for the distortion of the results and their instability. In addition, the moment of establishing the verticality of the device in the patient’s eye, covered by the eyelid, is essential. Installing the device in an inclined position significantly affects the measurement results.

 The basis of the invention is the task of improving the accuracy of measuring intraocular pressure.

 The problem is solved using an eye tonometer indicator containing a cylindrical transparent body, a freely falling ball, a device for holding the ball in its original position and a scale in which (according to the invention) the ball holding device consists of a holder rigidly connected to the cylindrical body, permanent magnets installed in a cage with the possibility of interaction with the ball, and a pusher, one end of which is rigidly connected to the cylindrical cover, and the other is equipped with a tip, inside which is located the ball is false, while the cylindrical cover and the pusher are made to move along the longitudinal axis of the cylindrical body, and the cylindrical cover is equipped with a ring made with the possibility of oscillatory motion relative to the longitudinal axis of the cylindrical body.

 The advantage of the proposed eye tonometer is the objectivity and accuracy of the measurement results, since the requirement is met with respect to the absence of additional impact on the measurement object (patient’s eye), due to the hand-held component of the operator taking the measurement and holding the device on the patient’s eye during the measurement, and acting on the lowering mechanism falling ball.

 The vertical position of the device on the patient’s eye is also provided. The operator keeps the device inoperative over the examined eye by the ring. Under the influence of its own weight, the device takes a vertical position.

 A significant structural advantage of the proposed device is that in it the fact of the lower position of the ball is determined by measuring the inductance of the coil, covering the cylindrical body of the device in its lower part. This design solution allows you to implement a number of modifications of the device, as well as to carry out wireless information retrieval.

 The advantages of the invention include the extreme simplicity of the technical solution, since it does not require the use of any measuring sensors.

 As a falling body, it is advisable to use a ball weighing from 0.4 to 1.0 g, falling from a height of 160-80 mm, respectively. It is advisable to use a metal ball, which allows the use of a simple electric sensor of its position during rebound, and an electric measuring circuit to evaluate pressure.

 In FIG. 1 shows an embodiment of a tonometer in longitudinal section; in FIG. 2 general Ivd of a vertical projection of a tonometer; in FIG. 3 tonometer, bottom view.

 The principle of operation of the proposed tonometer indicator (Fig. 1, 2). This tonometer 1 provides the ability to indicate the magnitude of the intraocular pressure, contains a transparent, for example, glass casing 2, in the upper part of which there is a retention device 3 of the ball 4 in its highest position. The retaining device 3 of the ball 4 consists of a cage 5, rigidly connected with the cylindrical body 2, permanent magnets 6 mounted in the cage 5 with the possibility of interaction with the ball 4, and the pusher 7, one end of which is rigidly connected to the cylindrical cover 8, and the other is equipped with a tip 9, inside which the ball 4 is located. The cylindrical cover 8 and the pusher 7 are arranged to move along the longitudinal axis of the cylindrical body 2. The cylindrical cover 8 is provided with a ring 10 made with the possibility of oscillatory movement eniya respect to the longitudinal axis of the cylindrical body 2. On the outer side of the cylindrical body 2 is applied scale 11 graduated in mm Hg. Art. Risks 12 and 13 divide the scale into three parts, corresponding to pressures below the norm, within the norm and above the norm. The ball 4, made of ferromagnetic material (for example, steel), is held in the upper position by means of permanent magnets 6 installed in the holder 5. The holder 5 is rigidly connected to a transparent cylindrical body 2 having a slot on the opposite sides along which the scale 11 is applied. The ball 4 is placed inside the tip 9 of the pusher 7, rigidly connected to the cylindrical cover 8 using a threaded connection. The pusher 7 is secured to the cover 8 by means of a latch 14 having a hole in which the ring 10 is inserted.

The use of a tonometer indicator is as follows
The operator keeps the device inoperative over the patient’s examined eye by the ring 10. Under the influence of its own weight, the device takes a vertical position. In this form, the device is installed on the front of the studied eye, covered by the eyelid. With a slight lowering of the cover 8 and the pusher 7 rigidly connected to it, the ball 4 is removed from the field of interaction with the permanent magnets 6. As a result, the ball 7 falls along the longitudinal axis of the cylinder 2. The force component from the reaction of the operator’s hand holding the device on the patient’s eye is only the presence of friction between the yoke 5 and the pusher 7. This component, with appropriate processing and selection of materials of the pusher 7 and the yoke 5, can be negligible. The ball with free fall on the eyelid of the patient acts on the front of the studied eye. The height of the first bounce of the ball determines the amount of intraocular pressure. The readout of the measurement result is made visually on a scale 11 applied to the cylindrical body 2, or made as shown in FIG. 1, i.e. plotted along a vertical slot on the body.

 Thus, intraocular pressure can be measured.

 An eye tonometer indicator is a fairly simple design, suitable for mass production, necessary to provide eye patients with individual means of measuring intraocular pressure in everyday life.

Claims (1)

 EYE TONOMETER-INDICATOR, comprising a cylindrical transparent case, a freely falling ball, a device for holding the ball in its original position and a scale, characterized in that the device for holding the ball is made in the form of a cylindrical cover, under which there is a holder rigidly connected to the cylindrical body, permanent magnets, mounted in a cage with the ability to interact with the ball, and a pusher, one end of which is rigidly connected to the cylindrical cover, and the other is equipped with a tip, inside which is located a ball, wherein the cylindrical cap and the pusher are movable along the longitudinal axis of the cylindrical body, and the cylindrical cap is provided with a ring configured to oscillate relative to the longitudinal axis of the cylindrical body.

Images