FR2594679A1 - Mechanical tonometer - Google Patents

Abstract

The invention relates to a mechanical tonometer. According to the invention, it includes a body 1 with a foot 2, a graduation 3, set inside the body on the side opposite the foot 2, and a plunger 4 which can move in the body 1; by means of the foot 2 the plunger 4 interacts with the cornea 27 of the eye to be examined; inside the body 1 there are received a light source 7, 8 and a reflecting mirror 9 which is connected to the plunger 4; the internal cavity of the plunger 4 is made of a light-conducting material. The invention finds its application in ophthalmology.

Description

 The present invention relates to medical engineering, and more particularly, it relates to mechanical tonometers.

 The invention will find its application in ophthalmology, for the measurement of intraocular pressure and the diagnosis of ocular pathologies in extra-hospital and clinical conditions.

 Mechanical tonometers are known, in which the value of the intraocular pressure is evaluated according to the size of the application circle whose diameter is measured, or according to the force which corresponds to a determined diameter of said circle d application (AP Nesterov et al., "Intraocular pressure, physiology and pathology", 1974, Nauka, Moscow, pages 16-17).

 The aforementioned tonometers are either characterized by low measurement accuracy or by the complexity of their structure. Furthermore, it is impossible, using said tonometers, to evaluate the magnitude of the pulsating oscillations of the eye.

 A mechanical tonometer is known (AP Nesterov and others, "Intraocular pressure / physiology and pathology /", Nauka, 1974, Moscow, pages 16-18), comprising a body with a foot which comes into contact with the eye , a graduation arranged in the body on the side opposite the foot, and a plunger, placed inside the body with the possibility of carrying out a movement and whose lower end, by means of the foot, cooperates with the ocular cornea at the moment measurement of intraocular pressure. The other end of the plunger is connected by a curvilinear lever system, to an indicator needle which moves on the scale, arranged in the body on the side opposite the foot.

 However, the conversion of the displacement of the plunger into displacement of the needle is related to a large friction force in the elements of the tonometer. Furthermore, said tonometer has a low resolving power, since the increase in its resolving power depends on the increase in the transmission coefficient of the curvilinear lever system, which leads to the increase in the reduced mass of the circuit. that acts on the plunger. The presence of friction, as well as the low resolution power of the graduation of said tonometer, exclude the possibility of determining the pulsating oscillations of the eye.

 The aim of the present invention is to create a mechanical tonometer, in which, thanks to the introduction of an optical reading of the result of the measurement of the intraocular pressure, it will be possible to modify the conditions of friction in the elements. of the tonometer.

 The problem is solved by the fact that, in a mechanical tonometer, comprising a body with a foot which comes into contact with an eye under examination, a scale arranged in the body on the side opposite the foot, and a plunger, installed in the body with the possibility of carrying out a movement and the lower end of which, by means of the foot, cooperates with the ocular cornea of the eye to be examined, according to the invention, inside the body there is a light source and a reflection mirror, the latter being connected to the plunger, the internal cavity of which is made of a light-conducting material and into which part of the light emitted by the light source arrives, and the part of the light reflected by the reflection mirror is directed on the graduation.

 It is advantageous to produce the reflecting mirror pivoting with respect to the axis, the supports of which are fixed in the body.

 It is advantageous to provide the plunger with a needle which moves with it during the measurement of the intraocular pressure and which, cooperating with the reflection mirror, makes it pivot relative to the axis.

 It is advantageous to install the supports in the body so that they are mobile.

 Such an embodiment of the tonometer according to the invention makes it possible to greatly simplify its construction, to reduce the friction in its mobile elements, to increase the accuracy of the measurement of the intraocular pressure and, moreover, to fix the gaze of the patient.

The invention will be better understood, and other objects, characteristics, details and advantages thereof will appear more clearly during the explanatory description which follows, made with reference to the appended schematic drawings given solely by way of example illustrating a embodiment of the invention and in which
- Figure 1 shows a mechanical tonometer, according to the invention, in longitudinal section;
- Figure 2 shows the same mechanical tonometer, seen from the front;
- Figure 3 shows, on an enlarged scale, the part surrounded by a circle A of Figure 1; and
- Figure 4 graphically represents the dispersion of the intraocular pressure measurements with the known tonometer and with the tonometer according to the invention.

 The mechanical tonometer according to the invention comprises a body 1 (FIGS. 1 and 2) with a foot 2. The body 1 comprises an upper part 1 'and a lower part 1 ". The foot 2 makes contact with the ocular cornea to be examined and ensures the stable position of the tonometer during the measurement of the intraocular pressure In the body 1, on the side opposite that of the foot 2, a graduation 3 is maintained, from which the value is read of the eye pressure in conventional units (called "Schiotz units", each unit being equal to 50 u). Inside the lower part 1 "of the body 1 is housed mobile a plunger 4 by bearings 5, 6. By its lower end, the plunger 4 cooperates with the ocular cornea during the measurement of the intraocular pressure. Inside the upper part 1 ′ of the body 1 is received a light source, comprising an electric lamp 7 rigidly fixed and a lens 8, installed mobile on the body 1 and away from the lamp 7 of the focal length. The body 1 carries a reflection mirror 9, which is connected to the plunger 4 for converting the displacement of the plunger 4 into a displacement of a light mark on the graduation 3. The interior cavity 10 of the plunger 4 is made of a conductive material light, for example, glass.

The light-conducting material of the interior cavity 10 of the plunger 4 is in direct contact with the ocular cornea to be examined. The plunger 4 cooperates with a reflection mirror 9 by means of a needle 11 (FIG. 3), rigidly fixed in the upper part of the plunger 4. With respect to the plunger 4, the mirror 9 is arranged so that part light coming from the lamp 7 (FIG. 1) arrives, through the objective 8, on the light-conducting material of the interior cavity 10 of the plunger 4 through a window 12 (FIG. 3), produced , near the needle 11, by removing, from the zone 13, the material reflecting the light from the mirror 9. The reflection mirror 9 is fixed on an axis 14, the supports 15 (of which are shown in FIG. 1) are movable in the body 1. The supports 15 are at the outlet site, from the body 1, of the upper part of the plunger 4 with the needle 11. The stroke of the plunger 4 downwards is limited by a pin 16. The tonometer according to the the invention is held in the working position on the patient's eye by means of a handle 17, inside which is ve the power source (not shown in the drawing) of the electric lamp 7.

 The lamp 7 is powered by conductive wires 18, 19, which pass through a socket 20 in the handle 17. The conductors 18 and 19 are connected to the outputs 21, 22 of the terminals 23, 24, which are fixed on a support 25 inside the handle 17.

 The introduction, into the structure of the tonometer according to the invention, of the light source 7, 8 and of the reflection mirror 9, directing the light of the source 7, 8 on the graduation 3, simplifies the construction of said tonometer by the replacement of all the mobile elements of the tonometer (in particular, the curvilinear lever system in the known tonometer) by the reflection mirror 9, which pivots relative to its axis 14 under the action of the plunger 4. During the conversion of the displacement of the plunger 4 moving the light mark 26 (Figure 2) on the scale 3, the friction is clearly reduced in the elements of the tonometer. This is accompanied by an increase in the resolving power of the tonometer, thanks to the increase in the length of the graduation dial 3.

 The reduction of the friction in the elements of the tonometer and its strong power of resolution allow, in addition to the measurement of the intraocular pressure, to evaluate the amplitude of the oscillations of the ocular pulsation.

Thanks to the fact that part of the light coming from the source 7, 8 is directed towards the internal cavity 10 of the plunger 4, the gaze of the patient is fixed.

 The mechanical tonometer according to the invention operates as follows.

où - H est la distance qui sépare la surface du miroir de
réflexion 9 de la surface de la graduation 3; - h est la distance entre le centre de l'aiguille Il
(figure 3), qui coopère avec le miroir 9, et le centre de l'axe 14.
Nous négligeons l'expression

dans le rapport susmentionné, compte tenu de sa grandeur insignifiante.The body 1 (FIG. 1) is placed on the cornea 27 of the eye of the patient who is the subject of the examination by the foot 2 and is held in this position by means of the handle 17 throughout the time of the examination. Under the action of its own weight, the plunger 4 deforms the cornea 27 of the eye by moving relative to the body 1. The needle 11 of the plunger 4 moves with it during the measurement of the intraocular pressure and, by cooperating with the reflection mirror 9, makes it pivot relative to the axis 14 (FIG. 3) by an angle tS. The light, coming from the lamp 7 (figure 1) through the lens 8, and being reflected by the mirror 9,% creates the light mark 26 '(figure 2) on the graduation 3.The position of the light mark 26 'is proportional to the angle i (figure 3) of rotation of the reflection mirror 9. The modification of the coordinate (tx) of the light marker 26' (figure 2) on the graduation 3 (figure 2) is a function of the displacement (A y) of the plunger 4 (figure 1) according to the ratio

where - H is the distance from the mirror surface to
reflection 9 of the surface of the graduation 3; - h is the distance between the center of the needle Il
(Figure 3), which cooperates with the mirror 9, and the center of the axis 14.
We ignore the expression

in the aforementioned report, given its insignificant size.

Lix = Hh Ly = kL y
h
So therefore, the conversion coefficient k is determined H by the relation H, which means that the increase
by sensitivity is not linked nor does it depend on the modification of the mass of the plunger 4.

 At the site of contact between the needle 11 and the reflection mirror 9, the friction is practically insignificant.

This fact, together with the high resolving capacity, makes it possible to evaluate the amplitude of the oscillations of the ocular pulse. Graduation 3 (Figure 2) is in conventional units. Its reading, using special tables, is converted into intraocular pressure values in millibars according to any known method. In this way, the position of the plunger 4 (FIG. 1) corresponds to a determined value of the intraocular pressure.

Part of the light, which arrives on the mirror 9, through the window 12 (Figure 3) arrives in the interior cavity 10 (Figure 1) of the plunger 4 and, then, in the eye of the patient, creating an optical image at the required position of the tonometer relative to the cornea 27. The patient is offered to constantly follow this optical image, which makes it possible to fix the gaze.

The tonometer is held on the patient's eye in the working position by means of the handle 17.

 The mechanical tonometer according to the invention measures the actual intraocular pressure. Tonometry was carried out, using the mechanical tonometer according to the invention, on 25 patients (35 eyes) suffering from glaucoma, on persons suspected of suffering from glaucoma, in the postoperative period and on children. The age of the patients varied from 7 to 78 years. The intraocular pressure was measured within the limits of 6.6 to 66 mbar. All patients tolerated the examination well.

 The results of the examinations are shown in Figure 4, where line 28 shows the actual value of the measured intraocular pressure, while vertical lines 29 show the value of the error between measurements 30 and 31, measurements 30 being carried out by means of the mechanical tonometer according to the invention, and the measurements 31 by means of any other known tonometer. Thus it can be seen that the measurements 30, carried out by the tonometer according to the invention, most often correspond to the real value of the pressure.

 Compared to known tonometers, the mechanical tonometer according to the invention considerably reduces the duration of the examination, does not require manipulation with dyes, is technically simple and economically advantageous, does not present any contraindications to its application. All this allows it to be used for the determination of intraocular pressure in patients of all age groups, including children.

 On the other hand, working with this device does not require special training on the part of the personnel.

 The mechanical tonometer according to the invention increases the power of resolution and, ultimately, the precision of the measurement, thanks to the increase in the length of the graduation, makes it possible to fix the gaze, and to determine the magnitude pulsating oscillations of the eye. All this improves the efficiency of the diagnosis of ophthalmological pathologies.

Claims (4)

 1.- Mechanical tonometer, of the type comprising a body with a foot, which comes into contact with the eye to be examined, a scale, arranged in the body on the side opposite to the foot, and a plunger, installed mobile inside the body and cooperating by its lower end, through the foot, with the cornea of the eye to be examined, characterized in that inside the body (1) is received a source (7, 8) of light and a reflection mirror (9), which is connected to the plunger (4), the interior cavity (10) of which is made of a light-conducting material, and into which part of the light from the source (7, 8) arrives ), while the part of the light reflected by the reflection mirror (9) goes to the graduation (3).  2. Mechanical tonometer according to claim 1, characterized in that the reflection mirror (9) is pivotable relative to an axis (14), the supports (15) of which are fixed in the body (1).  3.- Mechanical tonometer according to any one of claims 1 or 2, characterized in that the plunger (4) carries a needle (11), which moves with the plunger (4) during the examination of the eye and which, cooperating with the reflection mirror (9), pivots the reflection mirror (9) relative to the axis (14).  4.- Mechanical tonometer according to any one of claims 2 or 3, characterized in that the supports (15) are installed movable in the body (1).