DE3421701A1 - Applanation tonometer - Google Patents

Abstract

The invention presents a simply handled applanation tonometer which rules out subjective measurement errors and considerably eliminates the influence of lacrimal fluid. The measurement sensors used can be opto-electrical elements interacting with optical waveguides, acoustic surface wave transducers and semi-conductor pressure sensors whose electrical signals are processed in known electronic circuits to produce a digital direct display of the intra-ocular pressure. It is possible both to determine the applanation area at a constant pressure and to determine the pressure on a predetermined applanation area. The tonometer can be used, depending on the design, on lying and seated patients, the former tonometer being a small hand-held device operating independently of externally supplied energy.

Description

Title of the invention

Applanation Tonometer Field of the Invention The Invention relates to a device for measuring intraocular pressure according to the principle of applanation tonometry.

Characteristics of the known technical solutions There are three basic principles for measuring intraocular pressure generally known, the impression tonometry, the Applanation atonometry and non-cont act tonometry.

An impression tonometer measures; the depth of the indentation of the cornea, caused by a metal stamp loaded with a known weight. With the same weight, the indentability is the opposite of the intraocular pressure ; it is greater when the intraocular pressure is lower and vice versa.

The resistance that the cornea opposes the deformation becomes neglected. The main deficiency of expression tonometry is due to the fact that the putting on of the tonometer and the child's back of the metal stamp the intraocular pressure raise. The pressure found at the moment of reading corresponds to the tonometric pressure and not the tension that occurs in the interior of the eye before the Put on the tonometer prevails. But there is the handling of the Impressiontonometier quite easy. But not the tonometric pressure, but rather the intraocular pressure is to be measured, either an inaccuracy of the measurement must be accepted or additional calculations are required.

Another disadvantage of these devices is that when measuring the intraocular pressure the transmission of the measurement result by means of moving parts, stamps, Axis, lever and pointer, is made so that changes in the friction values of these know that moving mechanical parts can falsify the measurement result.

An impression tonometer that has no mechanical moving transmission element Sufficient for the display is described in DE-OS 31 12 910 A vI. this device is; designed for long-term measurement and has a sensor in the form of a Eye-attachable elastic contact lens that has a small on its underside rounded central elevation carries.

On the underside of the sensor is distributed over the entire surface applied an electrical conductor track in the form of a spiral. The top of the Contact lens is optionally perforated or spiral-shaped provided electrical conductor track. The electrical conductors on the upper and lower surface are connected to each other and form a passive sensor oscillating circuit. Further an active resonant circuit with a high frequency generator is provided. This Oscillating circuit 5 is preferably built into a spectacle frame, as is a dip meter and a telemetry transmitter. The sensor is deformed according to the intraocular pressure, so that this changes the resonance frequency of the sensor oscillating circuit. These Change can either be through the so-called dip frequency, i.e. H. a break in Oscillation spectrum of the active oscillation circuit or as a change in the oscillation amplitude of the active, active resonant circuit operated with a single frequency and assigned to corresponding intraocular pressures.

But this device also has the general disadvantages set out above the impression tonometer on. They become when applying the applanation principle overcome. This is based on Imbert's law, which says that the pressure corresponds to the counter pressure in a spherical container filled with liquid, which flattens a certain surface of this Rugel.

However, this law is only correct if the wall of the sphere is very is thin and does not offer any resistance to deformation. This is at Eyeball the case, which is why an intraocular pressure measurement on the Basis of this law is possible in two different ways.

1. A tonometer with constant weight can be used; used and the flattened surface can be measured.

2. It can be determined the force that is required to applanate a known surface of constant size.

A Perkins tonometer is known, which consists of a plastic cylinder exists, the lower, planar end is provided with a graduation. At the at the top there is a magnifying glass. After instillation of fluorescent into the conjunctival sac the diameter of the applanated corneal surface can be read optically determine on the grand scale. The intraocular pressure is determined here by means of a constant force.

Also known is a tonometer, which is based on an applanated Constant size surface works. The cornea is hereby made with the help of the quadrangular Base of a glass prism flattened. The intraocular pressure is measured by the Pressure of the prism on the eye is increased until the flattened circular Corneal area is level with the four sides of the prism base.

In addition to their disadvantages, these tonometers have, above all, that they Flatten too large a corneal surface and so artificially reduce intraocular pressure increase at the moment of the measurement process.

A device that has a manometer avoids this mistake Has chamber, one side of which consists of a thin elastic membrane. These is brought to the cornea and the pressure in the rammer is increased until the Membrane becomes flat. At that moment the pressure inside the chamber corresponds intraocular pressure.

Another well-known Goldmann tonometer is on a slit lamp assembled. It consists of a torsion balance fitted with a plastic cylinder. The front surface of the cylinder is flat. She is brought to the cornea and exercises here a rising pressure, which with the help of the torsion balance is measured. The tonometer is a biomicroscope with a maximally wide position Mounted gap. The contact zone of the cornea can be seen through the transparent cylinder watch.

The examination is done under violet light after the tear fluid was stained with the help of fluorescein, with the periphery of the contact zone as fine, intensely green colored circle appears.

Both of these devices require a high level of technical complexity expensive and can only be operated by specialists, i.e. field doctors.

In addition, the Goldmann tonometer fulfills the condition that the applanated surface must be very small (Bie is 7.35 mm2), but one is sensitive to the resistance, albeit slight, of the cornea opposed to the deformation. It also distorts the surface tension of the after The periphery displaced tear fluid by applying pressure to the cylinder Measurement result, since it is not possible to determine the contact zone between the Ange and the Keep tonometer dry.

The Goldmann tonometer can only be used with seated patients Find. In certain cases, for example with congenital glankoma, that is, with increased intraocular pressure, it is often necessary to conduct an anesthetic examination and to do the tonometry while lying down. The one that is in itself well suited for this purpose However, the Draeger tonometer is constructed in such a way that the pressure exerted by the prism takes place with the help of a motor.

That means your flammable preparations for anesthesia can be used as sparks can occur on the motor of the tonometer. aside from that the general arterial pressure and thus also the intraocular pressure can be reduced by anesthetics be reduced. In addition, the measurement must take place in an instant, in your eye looks straight ahead. Using tweezers to correct the The line of sight would, however, result in a measurement error, since the intraocular pressure increases will. This is important for all devices with a longer duration of the measurement process.

Another well-known tonometer made by Mac kay-Marg contains on top of the measuring head there is a small quartz cylinder fixed in an elastic sleeve, whose position shift by only a few microns causes an electrical impulse, which is recorded. The measuring head is with a low frequency, low voltage Electricity supplied, and caused by the pressure exerted on the arzkristall Current fluctuations are amplified. The interpretation of the tonograms is still controversial and solved the problem of calibration.

The Non-Contact Tonometer (NCT) from American OPtical Comp. produced Air blasts lasting 12 ms, within which the current velocity increases linearly increases to a maximum. When such air pokes the eye in the direction of the optical If the axis hits the axis, the cornea becomes more and more flattened and finally indented. An obliquely incident bundle of parallel light rays is called a parallel bundle When the air hits it, it reflects a central area 3.6 mm in diameter exactly applanated. This reflected bundle is picked up by a selenium cell and thus marks the current speed and thus the intensity of the applanation required air puff. However, tests with this device resulted in one Width of measurement error four times greater than that of the Goldmann applanation tonometer.

The US-PS 39 13 390 describes an optical applanation tonon he, in which a movable piston on glass fibers is used, which is driven by metal Weight rings can be changed in its contact pressure. At the top of the fiberglass bulb a measuring scale is arranged, which is in the Schärw fbereich when the device is attached a viewing optics is located. The image of the applanation surface is created through the glass fibers from the lower support surface exactly; to the upper surface marked with the scale transmitted and can be measured there. The disadvantage of this device is that because! 3 it has to be read manually optically, which is subjective on a measuring scale Failure does not rule out.

Another optically oriented application monitor is in the DE-OS 26 43 879. In this device, the flat surface of a prism is used constant pressure is pressed against the corneal surface, and rays of light are generated guided onto this surface at an angle alpha. Because the refractive index of prism and eye are much closer together than the coefficients of Prism and air, the rays of light that hit the contact surface set theirs Way into the inside of the eye and are absorbed there while the rays of light be reflected outside the outer edge of the contact surface. The difference between the penetrated and reflected light gives a measure of the contact surface. This device has two major drawbacks. Corneal opacities or white scars reflect the light too, so that incorrect measurements cannot be ruled out or the device cannot be used at all for certain patients.

It also adulterates tear fluid, which is changing The extent around the support surface and is never entirely avoidable, the measurement result, because it also absorbs the light rays and prevents reflection in its area.

The US-PS 35 64 907 (identical to the DS-OS 20 40 238) and 37 03 095 describe tonometers that work entirely electrically. It is used for Generating a strong signal with the help of a pen-like probe that is connected to the cornea of the patient is brought into contact, a pressure measurement is used. The tear-wet area in the application surface generates another signal, which is proportional to the size of this area. Both signals are combined and displayed as intraocular eye pressure on a simple analog measuring instrument. In the device of US-PS 37 03 095 there is a second probe that the Must have patient in hand. The disadvantage of these devices is that here too The tear fluid area cannot be eliminated and that the probes are attached Cables are attached and the display device separated, connected via the cable, set up is. In addition, material-related tolerances and signs of aging, z. B. the semiconductor pressure meter, to measurement errors to lead. Darübr In addition, a calibration of the device is necessary before each measurement, which is practical Handling made difficult.

The US-PS 43 05 399 describes a miniaturized device in norm of a contact line. Here the position is arranged to be movable relative to one another Coils used to change the frequency, which is a measure of the intraocular pressure. Changes in the frictional resistance and material tolerances can also occur here wrong measurement results.

In DE-OS 22 21 317 a tonometer is described which has an inner and a tubular outer pressure-sensitive element arranged concentrically around it Contains measuring element. These elements e act on strain gauges that are deformable 13 hangers are arranged. The presence of four measuring strips signals when the device rests correctly on the eye, but only rough inclined positions of the Tonometer recorded while lower. Inclinations to the vertical when used of the toning pressure are no longer displayed.

Another optically measuring tonometer is disclosed in US Pat. No. 4,192,317 described. The optical measuring method consists in an arrangement of photodiodes and photodetectors with two clear lines between them Scales are located, which are moved against each other by the toning stamp who the. Moir§ stripes are generated, which are used in a known manner as a measure of the movement of the stamp can be used. This very handy device shows above all the lack of a movable measuring device with, among other things, variable friction is.

DE-AS 26 22 990 and US-PS 37 14 819 describe air - jet tonometer. Here a strong jet of air is directed against the eye and the deformation measured on the surface of the eye.

Although it can be seen as an advantage that these devices do not have any mechanical Touch work is often called the strong airflow required by the patient felt even more unpleasant * The measuring sensitivity is much lower than with the applanation tonometers.

Overall, the known devices are either in the measuring accuracy unsatisfactory or technically and costly very expensive. Another disadvantage is the optical adjustment process, which is time-consuming and only by experienced examiners can be carried out in sufficient quality, based on the subjective observation and measuring the size of the applanation area in the optical devices errors anyway cannot be ruled out. In addition, most of the devices are due to their Structure difficult to clean and disinfect and must be dismantled for this purpose will.

AIM OF THE INVENTION The aim of the invention is to reduce the effort involved Avoid costs and technically complex devices, as well as the difficulties to be overcome during the measuring process and during cleaning.

Explain the essence of the invention The invention is the task based on creating a device for measuring intraocular pressure without high Expenses can be made that are easy to use and easy to use and avoids subjective errors in the measurement.

The measured value should be electronically without moving mechanical ones Transfer members after placing the device on the cornea without additional Adjustment or setting processes can be determined and read directly digitally be. The device should largely reduce the influence of the tear fluid on the measurement result switch off. It should be applicable to both the seated and the lying patient be, and it should be possible to both the area at constant given pressure as well as to determine the pressure for a given area. In addition, should the device be easy to clean and disinfect.

According to the invention, this object is achieved by a tonometer for measuring of the intraocular pressure is solved according to the applanation principle, which is an axially movable Measuring element has with which a force is exerted on the eye and in which this Measuring element consists essentially of light guides with one or more Light sources and optical sensors in interactions stone. These light guides are on the one used to flatten the eye Side to one flat applanation surface merged. Are on the opposite side the light guides arranged so that they allf take light from the light source or sources. This light is directed to the applanation surface and there when the device is in place reflected from the surface of the eye.

The reflected light is converted from the light guides to optical sensors, z. B. photodiodes, and converted by these into electrical signals that processed into a digital display by known electronic means.

According to the principle according to the invention, a simple to operating device for use on the lying patient are created.

The axially movable measuring element is moved vertically and is maintained a constant weight with which it presses on the eyeball. The al movable measuring element consists essentially of light guides that connect to one or more light sources and optical sensors cooperate in the manner described above. The electric Signals are further processed in a known manner to form a digital display. In this arrangement the light sources, the optical sensors, the electronic ones Means, the digital display and the batteries in the one for handling the device serving housing arranged. The movable measuring element consists essentially only from the light guides. In order to avoid frictional losses, the coupling between the housing and the axially movable measuring element carried out purely optically. The axial movable measuring element can be drum-shaped. Then the light guides are arranged in the drum-shaped body so that their first ends at the lower Surface of the drum-shaped body are ground and polished parallel and flat. They thus form an applanation surface suitable for flattening the eye. the second. opposite ends of the light guides terminate at right angles to the Applanation surface on the outer peripheral surface of the drum-shaped body.

In this embodiment, the axially movable measuring element is expedient Light is radiated into a light guide, and that from the surface of the eye reflected light is sent from a neighboring light guide to the optical sensors directed.

To this end, the second ends of the light guides can be used to carry light should take up on half a side of the circumference of the drum-shaped body be arranged and the second ends of the reflected light leading light guide the other half of the circumference0 The second ends of the light guide can also arranged in horizontal rows on the outer periphery of the drum-shaped body be. Then the rows of light-receiving light guides can be on the upper half be arranged and the reflected light leading on the lower half or vice versa.

The rows of the light-receiving light guides and the reflected light Leading light guides can also alternate on one another or in groups on one another follow.

It is also possible to make the second ends of the light guides perpendicular Arrange rows on the outer circumference of the drum-shaped body. Then can the rows of light-receiving light guides and the rows of reflected light leading Light guides follow one another alternately or in groups. The light source or the light sources and the optical sensors are then, analogous to the order of the second Light guide ends, correspondingly on the opposite of the drum-shaped body Part of the inner surface of the housing arranged.

Since it is advisable to keep the applanation area as small as possible, the opposite second ends of the light guide but at right angles to the outer The circumference of the drum is guided, the circumference of the applanation surface is smaller than that outer drum circumference.

The axially movable measuring element can, however, also be prism-shaped throughout be executed, in which case both ends are ground flat. Then the lower one serves Flattened side as applanation surface and the upper one for the entry of light and for the incident light. The light source or the light sources are then arranged together with the optical sensors above the movable element. The light can also be beamed into the light guide from the side at an angle be when a corresponding one on the upper flat-ground surface half-mirrored prism is attached. The optical sensors are in this case also arranged above the movable element. That from the prism into the light guide Directed light is reflected from the surface of the eye and passes upwards the prism acts as the light guide and hits the optical sensors.

In the execution of the axially movable measuring element as a prism can it can be an advantage if the light guides are arranged in parallel. That's in that In the case of two, if here, too, part of the light guides convey the light to the applanation surface and another part guides the reflected light to the optical sensors. if the integral mean value of the luminous intensity is used, e.g. B. in execution With the prism attached, the light guides can also be disordered in the moving element be led. The axially movable measuring element can also be located above the applanation surface have an elongated shape, the opposite second ends of the Light guides in one or more vertical rows on the elongated Klement are arranged. Then the second ends of the light receiving light guide arranged one above the other on one side of the element in one or more rows be and the ends of the reflected light leading light head in the same way the other side. There can also be both light-absorbing elements on each side of the element Light guides as well as reflected light leading light guides each one on top of the other in a vertical position Rows can be arranged, with the corresponding rows side by side or one above the other arranged his ability. It s also possible to receive and light in rows To arrange reflected light guiding light guides alternately or in groups.

In a second variant of the applanation tonometer with optoelectronic Measured value acquisition is the measuring element Eaxf on the side used to flatten the eye also ground and polished. On the opposite of the applanation surface Side of the movable element are on the ends of the individual fibers of the light guide alternately as light source photoelectronic transmitters and photoelectronic receivers arranged. Each from a photoelectronic transmitter in a light-absorbing fiber-optic catcher is radiated into the applanation surface reflected and through an adjacent reflected light leading optical fiber to the phot oil ctronic receiver arranged on this.

In a third variant with the gleicban measuring principle, the side of the movable element opposite the applanation surface the ends of the individual fibers of the light guide on each fiber via one Part of the cross section of the surface optoelectronic receiver can be arranged.

An external source of light shines through the part that has remained free of the cross section light is radiated into the optical fiber and after reflection on the applanation surface in the same optical fiber as the optoelectronic Receiver fed back and converted into electrical signals.

The optoelectronic which is arranged on each fiber of the light guide takes up Receiver advantageously half the cross section of the optical fiber. He can do both be cited as a circle segment area, in particular as a semicircle area, as well in the form of a circular ring or a preferably concentrically arranged circular area, which is smaller than the cross-sectional area of the optical fiber.

The light source, which is arranged in the fixed part of the housing is, can in this variant, but also in the embodiment with attached Prism may be formed by one or more light-emitting diodes, which are in the third variant in the axial direction with respect to the movable element behind a Scatter film is / are arranged.

Any electromagnetic wavelength from ultraviolet can be considered as light to infrared, both in the visible and in the invisible range. To switch off interference from unavoidable secondary light, the wavelength are advantageously in the infrared range from 0.85 to 25 μm, preferably of the order of magnitude of 1.3 µm. Timed light can also be used.

In order to switch off incorrect measurements due to the Trinenfluid, only Detected reflected light of a certain intensity. Because of this, it is in itself known electronic, tronic measuring transducer circuit, a threshold value transmitter is provided.

In a further variant of the tonometer according to the invention for measurement the intraocular pressure according to the applanation principle, which is an axially movable measuring element possesses, by which a force is exerted on the eye, around part of the surface of the eye absuflacOn and the means used together to determine the GDOB of the flattened Surface at a given pressure, or to determine the pressure exerted at a given size of the flattened surface are used as measuring sensors on the axially movable measuring element on the applanation surface used to make the eye smile one or more surface acoustic wave transducers arranged, each two or have more interdigital transducers.

The input interdigital converter (s) is / are with a specific High-frequency voltage is fed into it, which converts it into a surface sound wavelength that is dependent on its dimensions reshape.

These surface acoustic waves are generated by the output or receiver interdigital transducers recorded and converted back into electrical signals of a certain frequency, which by means of known electronic means to an analog or digital display are further processed.

The interdigital transducers can be used to flatten the eye Be arranged in such a way that they are located outside of the area that the is touched by the flattened obscuration surface of the eye, i.e. in the peripheral area. she but can also be arranged so that they are completely or partially flattened from the Surface of the eye to be covered.

By putting on the surface acoustic wave converter provided applanation surface on the Angle, the surface waves between the interdigital transducers damped The damping is a measure of the size of the flattened surface of the eye. Known evaluation methods can be used calibrate the amount of attenuation in units of intraocular pressure.

Furthermore, the route between the transmitter interdigital converter and the receiver interdigital converter as a delay line of a feedback Generators are operated.

The change in the properties of this feedback path through the flattened surface of the eye in contact with it can be known by electronic evaluation circuits are converted into a frequency change, wherein the resulting frequency can be calibrated in units of intraocular pressure. Surface acoustic wave converters are generally known components. You insist from a mostly piezoelectric substrate on which a surface acoustic wave is located spreads. Via the input and output converters (interdigital converter) electrical energy converted into acoustic energy and vice versa. When the electrodes are pushed into one another like a finger, their distance determines the wavelength and thus the frequency of the surface wave that can be coupled in.

It has now been found that there is also a variation in the output frequency is possible if a foreign body in the form of a solid, semi-solid on the transducer or liquid medium is applied and that by this measure also a damping the vibrations can be caused, depending on the pressure and / or the area is detectable.

After this inzip, an easy-to-use Device for measuring intraocular pressure to be created. This is when using on the patient lying down, the axially movable measuring element is vertically movable in one Housing arranged and given a constant weight with which it presses on the eye. The axially movable measuring element is designed so that it rests on the eye Applanation surface of the surface acoustic wave transducer or transducers arranged are whose input or transmitter interdigital converter via optocoupler from the housing be supplied with electrical energy of a predetermined frequency, wherein the Optocoupler preferably of two light-emitting devices arranged in the housing Diodes and the corresponding number arranged on the axially movable measuring element There are photodiodes or phototransistors.

The receiver interdigital converter (s) are also via optocouplers connected to the housing, the electrical supplied to them by the transducers Optical transmission of energy to the housing.

Preferably there are two light emitting devices per receiver interdigital transducer Diodes arranged on the axially movable measuring element and a corresponding one in the housing Number of photodiodes or phototransistors that restore the optically transmitted energy convert into electrical signals by means of known electronic means to an analog or digital display.

Yet another variant of the tonometer according to the invention for measurement the intraocular pressure according to the applanation principle, which is an axially movable measuring element possesses, by which a force is exerted on the eye, around part of the surface of the eye to flatten and the cooperating means of determining the size of the flattened surface at a given pressure or to determine the exerted Contains pressure at a given size of the flattened surface on the axially movable measuring element on the applanation surface used to flatten the eye a variety of pressure sensors based on semiconductor crystals.

These semiconductor pressure sensors expediently consist of a silicon substrate, which is neutron-doped with different resistance materials, with several Resistors are metered into the bridge circuit. Such halide iter pressure sensors NEN with a doped bridge circuit are known per se.

Snn such a pressure sensor is exposed to a pressure occurs a detuning of the bridge circuit, the detuning of the bridge circuit occurring differential voltage represents a measure of the pressure on the pressure sensor works. The response value of the known pressure sensors is in the order of magnitude of the counterpressure generated by intraocular pressure on the applanated surface of the eye.

Be on the applanation area of the tonometer according to the invention a plurality of such pressure sensors in the form of one or more semiconductor pressure sensor substrates arranged doped bridge circuits, the arrangement useful in the form a matrix. But it is also possible to use the pressure sensors in the form of a To arrange a star, a spiral or even just a cross. The grid dimension for the individual pressure sensors is expediently below 300 μm, advantageously. in the order of magnitude from 50 to 100 µm or less if possible. The size of the grid is a question the manufacturing technology, and the value should be as low as possible.

The one present in the pressure sensor in the form of an electrical signal Information is pushed out in pulses and taken line by line, like this z. B. takes place in the known CCD Bauelsmenten, so that the control and the The information can be picked up in each case via just one line, with the gain of the output signal takes place in a known form (Elektronik 1980 H. 10: p 49).

In the same way, the opto-electronic ar ».

the reflexes selected and as number of reflexes and not only fed to the evaluation circuit as reflected light quantity.

The evaluation of the individual electrical signals from the pressure sensors takes place by means of known electronic circuits. It can be the integral of the measured values can be read out and in terms of the pressure analog, digital, with short-term storage or output in the current display. There can also be the pressure differences between the center of the applanation surface and the edge thereof are determined, wherein individual isobars can be determined, reveal possible irregularities about hardening of individual places. By providing a threshold value generator it is also possible to eliminate the influence of the tear fluid, its counter pressure yes, it is considerably less than that of the applanated surface of the eye.

According to this invention, a simple Operable device for measuring intraocular pressure on the lying Patients will be geohat'e-. The axially movable measuring element can be moved vertically arranged in a housing and given a constant weight with which it is placed on the Pressed. The axial. movable measuring element is designed so that on the The half-liter pressure sensors are arranged on the applanation surface resting on the eye.

For all tonometers intended for use on the patient lying down the axially movable measuring element is arranged in a housing against which it is a Relative movement executes. It has a predetermined dead weight, and the Sensors arranged on its applanation surface are available with the sensors required for evaluation Means that are used together with the batteries and the Display itself are arranged in the housing suitable for handling, smoothly in.Yirkrelationship.

This is achieved through a purely optical coupling of the movable measuring element achieved with the housing, so that a completely smooth working with the device is possible, whereby any falsification of the measured value is closed. It is appropriate when the optical coupling is at the end opposite the applanation surface of the axially movable measuring element is carried out, the measuring element then being advantageous is designed prism-shaped. In order to avoid that the axially movable measuring element WIL its longitudinal axis is twisted, it is advisable not to design it as a cylinder, but it has a polygonal cut in a guide with the same cross-section to be arranged in the housing. In the case of a cylindrical cross-section, however, suitable ones can also be used Means are provided that prevent twisting or the optical coupling enable anyway.

It is also possible to reduce the energy between the housing and the axially movable measuring element to transmit smoothly by inductive means. This is done in the Housing an inductive encoder provided with a at the appropriate point of the axially movable measuring element arranged inductive receiver in operative relationship which in turn is connected to the input of the measuring sensors. The exit of the measuring sensors is arranged with a measuring element on the axially movable measuring element inductive encoder connected, the one with an inductive receiver is in operative relationship in the housing, which is arranged in the same at a suitable point is.

The inductive elements can be in the form of coils as well in the form of vapor-deposited or otherwise applied by known methods Structures may be provided, it being expedient to arrange coils in the housing and vapor-deposited or otherwise opened onto the axially movable measuring element to arrange te structures.

To be able to work properly with the tonometer while the patient is lying down to ensure this must be kept exactly vertical. Therefore, on the housing, at the exit point of the axially movable measuring element at least three optopplers, preferably reflex couplers, arranged distributed over the U & ang.

In the area of the axially movable measuring member, which when measuring the Opposite optocouplers, this is with a ring-shaped, reflective Covering provided. If the device is exactly vertical, the from the optical transmitter The light beam emitted by the reflex coupler when the device is placed on the eye reflected from the reflective coating and from the optical receiver of the reflex coupler receive. The generated electrical signal can be used for the measurement process trigger. If the device is placed in such a way that the exially movable measuring element does not stands vertically, i.e. is tilted and rests against the housing, the from the transmitter of the reflex coupler outgoing light beam from the reflective coating of the measuring element deflected up or down and does not reach the recipient. The nonexistent electrical signal blocks the measuring process. When executing the reflective covering in a suitable width it is achieved at the same time that the device is not attached State not working. Two different colored LEDs, which are placed in a suitable place on the Housing are arranged, indicate whether the device is measuring or whether the measuring process is interrupted so that those who work with the device are informed about the state of the device and the time to which it is held exactly perpendicular is informed.

When using the device on a seated patient, the device is expediently designed so that the axially movable measuring element with the measuring sensors horizontally on the applanation surface movably attached to a lever is, whose horizontal force is adjustable, to a predetermined pressure of the applanation surface to be able to adjust to the eye.

Several variants are possible in this embodiment. Bs can the device can in principle be designed in the same way as that for use on the lying surface Patient, only that the axially movable measuring element is attached to said lever which is led through a slot in the housing, and again optically to the Housing is coupled, which includes the power supply and the electronic means the ad contains.

but can also run the entire device in one piece on the fog be attached and thus axially movable, so that a design in the form of a Fixed housing and a relatively movable measuring element to this unnecessary. In this version for seated patients are axially horizontal at the front end of the movable tiebelendes arranged the measuring sensors, and the power supply, the electronic means and the digital display can be placed anywhere on the device, easily visible for the examiner.

These and other variants, especially for the device with light guides, are explained in more detail in the following exemplary embodiments.

Incorrect measurements due to tear fluid, which is caused by displacement drawn from the applanation surface and by capillary action to the applanation surface collects are avoided by the various effect of the liquid in contrast to the relatively solid body of the eye on the measuring sensors by the electronic Evaluation circuit is detected and the proportion of tear fluid is eliminated.

For easy cleaning and protection of the applanation surface and thus to enable hygienic work, the measuring sensor (s) containing applanation surface are provided with a protective layer the electronic evaluation circuit and the digital display can with known means be designed in such a way that the minimum, mean and maximum values of the Eye drowsiness, due to the dependence on the pulsation pressure of the blood, possible is. This can be done by saving the three values and querying them for only one digital display happen or by three separate digital display. It's also one with the variation concurrent display of the value is possible, which may be stopped at each value can be.

The tonometer according to the invention has compared to the known devices the following advantages: - low equipment-technical effort, - low costs, - easy handling, - usability for not specially trained people, - optoelectronic Acquisition and display of measured values, free of subjective errors, - no mechanical Friction in the measuring system, which vary due to external circumstances and lead to measuring errors can, - small dimensions, - easy to clean and disinfect, - extensive Elimination of the influence of the tear fluid, - high resolving power.

Exemplary embodiments The invention is intended below on the basis of exemplary embodiments are explained in more detail.

The accompanying drawings show: FIG. 1: a schematic representation the course of the light rays in the area of the applaaation surface with a tonometer, whose measuring element consists essentially of a light guide, in a first variant; Fig. 2: a first form of the measuring element for using the tonometer according to the invention on the lying patient with an axially movable measuring element made of light guides in drum shape, shown schematically; Fig. 3: a second form of the measuring member for Use on the patient with an axially movable measuring element made of light guides in prismatic form, shown schematically. Fig. 4: a third form of the measuring element for use on the patient with an axially movable measuring element Light guides in the shape of a frisme with lateral light supply, shown schematically; Fig. 5: a fourth form of the measuring element for use on the patient lying down an axially movable measuring element made of optical fibers in elongated form, schematically shown; 6: a second variant in which the axially movable measuring element In addition to the light guides, optoelectronic transmitters and receivers alternate contains the individual fibers of the light guide, shown schematically; Fig. 7: a third variant in which part of the cross section of each individual optical fiber is equipped with an optical-electronic sensor, shown schematically; 8: a schematic representation of the applanation surface of a tonometer with surface acoustic wave converters as measuring sensors; Fig. G: a variant of the Tonometer according to the invention for use on the patient lying down with an axially moving measuring element with optoelectronic coupling to the one used for handling Housing, shown schematically, in section; Fig. 10: a second variant of the inventive tonometer for use on the patient lying down with an axially movable measuring element with inductive coupling to the housing used for handling, shown schematically, in section; 11: a schematic Representation of the applanation surface of a tonometer with pressure sensors as measuring sensors ; Fig. 12-14: Schematic representations of device variants for use with seated patient.

Fig. 1 shows a schematic representation of a first Variant, the effectiveness of the opto-electronically measuring applanation tonometer according to the invention. The consisting essentially of a plurality of light guides 2 axially movable Measuring element 1 is placed with a pressure P on the eyeball 3, whereby a flattened surface F is created. The displaced collects to the side of this surface and tear fluid drawn in by the capillary action 4. This leads to the electrical area measurements to measurement errors and can also be the cause of a subjective optical measurement errors. In the tonometer according to the invention is now Light L irradiated into the light guide. In the area of the applanation area F is the light is reflected unbroken and passes through the same or a neighboring one Light guide as reflected light R back. In the area of the tear fluid that will Light also only reflected on the eyeball 3, under a Minkel. If reflections of this light get into a light guide as refracted reflected light 3R ', is its light intensity through the absorption in the tear fluid and the through the oblique impact on the light guide reduced the luminance weaker than the light intensity of the reflected light R. This reduced light intensity results in the optical sensors emit a weaker electrical signal, which is then transmitted to the connected known electronic evaluation circuit by a threshold value transmitter is eliminated. So only the reflected light R is measured and so is the influence the tear fluid largely eliminated.

In the embodiment of the invention shown in FIG Tonometers for use on the lying patient are the light guides from the applanation surface out to the outer wall of the drum-shaped movable measuring element 1, where they end at right angles to the applanation surface. In the housing 5 of the tonometer are light sources 6 here light-emitting diodes and optical sensors 7 here Photodiodes compared to the Arranged ends of the light guides. At the illustrated example, it should be assumed that on the left side of Fig. 2 the LED 6 and on the right side the photodiodes 7 are located. The order but can also be chosen differently. The light of the LED 6 is in the light receiving Light guide 2.1 irradiated and directed to the applanation surface F, where it is from the eyeball 3 is reflected. The reflected light R is made of light guides guiding the reflected light 2.2 led to the photodiodes 7 and converted by them into electrical signals, which has terprocessed in known electronic circuits to a digital display will.

In the form shown in Fig. 3, the axially movable measuring element 1 continuously prism-shaped. The light source or light sources 6 in the embodiment of Fig. 3 LEDs are above the prism-shaped, m both Sides ground flat, consisting of light guides 2 MelBelementes 1 in the housing arranged. The optical sensors 7 are located at the same point, wherein the order of the optical means is arbitrary. The light emitted by the LED 6 is passed through the light guide 2 to the applanation surface F and from the eyeball 3 reflected. The Beflexllicht is from the optical sensors 7 in electrical Signals converted, which, as already mentioned, are further processed into a digital display will. The light scattered by the tear fluid 4; is also eliminated here.

The shape in Fig. 4 shows an embodiment in which the light in a Angle is irradiated. The same elements are identified with the same reference symbols as in the other fig.

The light source used here is an incandescent lamp 8 with a converging lens 9 and a diffuser 10 generates the same light over the entire cross section. To increase the light intensity, a mirror 11 can be provided. That sideways irradiated light; 12 is illuminated by means of a half-mirrored isma 13 Head 2 passed, and the light reflected from Aigapfel 3 is through 'the prism 13, which is transparent in the direction of the reflected light, onto the optical sensors 7 radiated and evaluated in a known manner.

Fig. 5 shows yet another form, the mode of operation of which is that of the others is equivalent to. The anal movable measuring element 1 is designed here in an elongated form, The corresponding components are given the same reference numerals as in the corresponding Fig.

1 - 4 marked.

In all of these embodiments of the first variant, the axially movable measuring element 1 no electronic elements, but only light guide elements for guiding the incident light to the applanation surface and the reflex joint from the applanation surface to the opto-electronic receivers, with both the light sources and the receiver are arranged in the housing.

In a second variant of the applanation tonometer shown in FIG The axially movable measuring element 1 is open with opto-electronic measurement acquisition the side used to flatten the eye 3 is also ground and polished flat.

AS the side of the axially opposite the applanation surface F movable measuring element 1 are on the ends of the individual fibers 2 'of the light guide 2 alternately as light source 6 photoelectronic transmitter 6 'and photoelectronic Receiver 7 'arranged. The each of a photoelectronic transmitter 6 'in a light. light L radiated into the receiving fiber optic 2.1 is transmitted to the The applanation surface is reflected and guided by an adjacent, reflected light R. Optical fiber 2.2 to the photoelectronic receiver arranged on it 7 'led.

In a third variant with the same measuring principle that is shown in FIG 7, on the opposite side of the applanation surface of the axially movable element 1 on the: that of the individual fibers 2 'of the light guide 2 on each fiber 2 'each over part of the cross-section of the optoelectronic surface Receiver 7 'be arranged. From 'an external light source (not shown) the remaining free part of the cross-section light L into the light guide holder 2 'and after the reflection at the applanation surface F in the same Optical fiber returned to the optoelectronic receiver 7 'and converted into electrical Signals converted. In this case, the one arranged on each fiber 2 'of the light guide takes optoelectronic receiver 7 'advantageously half the cross section the Optical fiber 2 'sim. It can be used both as a segment of a circle, in particular as a Semicircular surface, be designed as well as in the form of a circular ring or preferably one concentrically arranged circular area, which is smaller than the cross-sectional area the optical fiber 2 '.

The light source, which is arranged in the fixed part of the housing is, can in this variant, but al2ch in the embodiment with additional Prism of the first variant formed by one or more light-emitting diodes be, but in the third variant in the axial direction compared to the axially movable Element 1 is arranged behind a scattering film to exclude measurement errors By scattered secondary light, measurements can be made in the tonometer in addition to visible light UV or IR radiation can also be used. A particularly advantageous wavelength is on the order of 1.3 µm. : Timed light can also be used.

When the tonometer according to the invention can also be used as measuring sensors acoustically Surface acoustic wave converters 30 are used which, as shown in FIG is to be arranged on the applanation surface. The surface F of the axially movable MeBelementes 1 on the eye 3 and flattens one shown with a solid line Area from. Tear fluid 4 collects around this area, in the form of a dashed line is indicated schematically.

This leads to measurement errors in the known electrical area measurements and can also be the cause of a subjective optical malfunction.

If the input interdigital converter 30.1 (transmitter) with electrical energy When excited at a certain frequency, it generates surface acoustic waves a frequency that is dependent on its dimensions and that extends over the applanation area F migrate to the output interdigital converter 30.2 (receiver) and from there again can be converted into electrical energy. This known component becomes Used for various purposes but where it is important not to interfere to er th. Now a body on this surface acoustic wave transducer 30 or a liquid is applied or the surface F on which the transducer 30 is arranged is e.g. B. pressed against one eye, attenuation or frequency imbalance occurs on, which is dependent on the size of the area F and by means of known electronic Circuits is assessed. This change is in the area of undressed Circular area, which represents the flattened area F of an eye 3, different than in Area of the circular area drawn with the dashed line that contains the tear fluid should represent. This fact makes it possible to reduce the influence of the tear fluid to be switched off as far as possible.

It is also possible to use suitable pressure sensors based on semiconductor crystals to be used as measuring sensors. Such an embodiment is shown schematically in FIG dsgrierter.

The lower applanation surface F containing the pressure sensors 40 of the axially movable measuring element 1 presses the eye 3 and flattens a, with a solid line in Fig. 11 dargestell te area. Gathers around this area tear fluid 4, which is shown schematically in the form of a dashed line is. This is common for electrical or manual-optical area measurements to measurement errors.

When on the arranged on the applanation surface F pressure sensors 40 pressure is applied, e.g. B. by the back pressure of the ges 3, which depends on Intraocular pressure, a verb mood of the bridge circuits occurs, with the the resulting differential voltage is a measure of the size of the pressure.

By querying the size of the detuning of the individual pressure sensors the pressure at a given area determined by counting the detuned pressure sensors 40 is determined, or the size of the area, can be determined by counting the detuned Pressure sensors, at a given pressure. The latter can be due to its own weight of the axially movable measuring element 1 or be defined by other means, wherein a control through the size of the detuning is possible.

The pressure sensors 40 can have any configuration the applanation area F are arranged, the area determination by counting of detuned sensors such as matrix, star, spiral or cross shapes. The resolution depends on the density of the arrangement of the sensors and the pitch should be in the range of 50 to 100 µm or less.

Figures 9 and 10 show easy-to-use small and light ones He applanation tone for use on the patient lying down, where the axial movable measuring element 1, which azfWEIS a constant specific weight, with the The applanation surface F is placed on the eye 3. The battery series are in housing 5 24 for energy supply and the electronic means 25 for processing the measured values arranged to a preferred digital display.

The arranged on the applanation surface F of the movable measuring element 1 Measuring sensors are supplied with electron energy via optocouplers 26, and the outputs the measuring sensors are also connected to the movable measuring element 1 via optocouplers 27 to the electronic means 25 of the evaluation circuit located in the housing 5 transmitted, which processes these signals to a digital display 28, which can be displayed on any Position can be made visible.

As shown in Fig. 10, the coupling between the housing 5 and the axially movable measuring element j also take place inductively. Then on the Input side, the energy in the housing 5, an inductive transmitter 31 is provided is connected to the energy source. Opposite it is located on the axially movable one Measuring element 1 an inductive receiver 32, which is connected to the X input of the measuring sensor is. The output energy is sent from the output of the measuring sensor to an inductive transmitter 31 passed, which is on the axially movable measuring element 1 compared to an inductive Receiver 32 is arranged. The latter forwards its signals to an electronic one Evaluation circuit, which it processes into a display.

To check that the device is held exactly vertically, or to Ensuring that the device only measures on exactly vertical days and thus friction by grinding on the walls of the housing or incorrect measurements by inclined Avoid exposure to all devices for use on the lying patient a monitoring device is provided. This consists of at least three Optocouplers, preferably reflex couplers 22, with adjacent transmitters and recipients. These reflex couplers 22 are uniform at the location of the housing 5 arranged over the circumference distributing on which the axially movable measuring element from to the Housing 5 exits. in the place of the axially movable measuring element 1, which when measuring, d. H. when the measuring element 1 is placed on the eye 3, the reflex couplers 22 is located opposite, a reflective coating 23 is applied in a ring.

When the device is standing exactly vertically, the z. B. a photodiode, emitted light beam when placed on the eye 3 Device reflected from the reflective coating 23 and from the optical receiver, e.g. a photodiode or a phototransistor. That generated electrical Signal can be used to trigger the measurement process.

If the axially movable measuring element 1 and the housing 5 are not on the same axis The light beam emitted by the photodiode of the reflex coupler 22 becomes perpendicular deflected by the reflective coating 23 of the measuring element 1 up or down and does not reach the recipient. The non-existent electrical signal blocks the Measuring process.

If the covering is made in a suitable width, it is achieved at the same time, that the device does not work if it is not switched off.

Two different colored LEDs 33 and 34, which are placed in a suitable place on the Housing are arranged, indicate whether the device is measuring or whether the measuring process is interrupted is. This means that the person working with the device is over the period in which the device works, always informed and also about the fact that it is not exactly X set.

With all of the above variants for use with the patient lying down the electronic means 25 are also in the housing 5 required for handling for processing the electrical signals from the optical sensors into digital ones Display 28, this display itself and the required battery 24 for power supply housed. This makes the device completely independent and easy to use. There only the applanation surface F of the axially protruding relatively far from the housing movable measuring element 1 comes into contact with the eye and this either as Ground, polished glass surface executed or with a smooth coating 36 Surface F made of a suitable material is easy to clean, too a hygienic application ensured.

It goes without saying that the axially movable measuring elements are secured against falling out of the housing.

The possible embodiments shown in FIGS. 12, 13 and 14 are suitable for the use of the tonomster according to the invention on the seated patient. This form is mainly used in devices for clinical examinations, which is why a higher technical equipment expenditure and a not so easy handling as with the variants explained above can be taken in Rauf.

In the embodiment according to FIG. 12, the axially movable measuring element is which in this example consists essentially of light guides 2, as an integral part a first arm 14 of a lever 15 formed, on the second arm 16 a variable, preferably displaceable weight 17 for regulating the horizontal Pressure P is provided with which the planar surface F presses on the eyeball 3. The change in pressure can of course also be effected in a different manner. The light guides 2 are in a cable 18, expediently at the pivot point 19 of the lever 15 led out to an evaluation and display device 20, which the power supply, the light source or light sources, the optical sensors, the electronic evaluation circuit and the digital display 21 contains.

That from the light sources inside the evaluation and display device 20 light radiated into the light guide is directed to the applanation surface F, reflected from the eyeball 3 and to the likewise in the evaluation and display device 20 arranged optical sensors returned. The generated electrical signals are processed into a digital display, as has already been done several times above was mentioned. In the embodiment according to Fig.

13 are the possibly occurring inaccuracies due to mechanical Effects of the fiber optic cable on the lifting forces are eliminated by the Transition from the movable to the fixed part of the device on optical Ways done. It is therefore a fixed housing 5 is provided in which the axially movable measuring element 1 attached to the lever arm 14 moves without friction. The embodiments of the measuring element 1 and the housing 5 are arbitrarily analogous those of the embodiments for use with the patient lying down possible. In Fig. 13 is the measuring element 1 with its light guides 2 as a continuous prism shown, and the LED 6 and shotodiodes 7 are on the back wall of the housing 5 arranged. However, as already mentioned, other forms are also possible. The light conductor cable 18 runs here from the fixed housing 5 to the evaluation and display device 20.

In a variant according to FIG. 14, the entire evaluation and Display elements executed with the measuring element in one piece, without relab tive mobility will. The housing 5 is then fixedly arranged on the lever 15 and has a diameter of the measuring element of the other variants corresponding approach 35, on the front surface the measuring sensors are arranged in the manner already described. The electronic The means (not shown) and the digital display 9 are then connected to the lever 15 pivotable and movable housing 5 housed. The energy supply can also be used here take place by means of an external energy source, in which case the supply line (not shown) expediently at the I) rehpunkt 19 of the lever 15 was introduced to the repercussions to keep the torque low. But there can also be a battery in the housing be provided.

Here, too, the front surface 37 can be provided with a suitable smooth coating 36 to facilitate cleaning and disinfection.

Claims (64)

Claims of the invention 71. Applanation tonometer for measuring intraocular pressure according to the applanation principle, which has an axially movable measuring element with the a force is applied to the eye to flatten a portion of the surface of the eye and the cooperating means for determining the size of the flattened Surface at a given pressure, or to determine the pressure exerted at a given size of the flattened surface contains, labeled in that the axially movable measuring element (1) consists essentially of light guides (2) consists and the means interacting therewith one or more light sources (6) and optical sensors (7), the light guides (2) sf of the one for the flattening of the eye (3), the side is ground and polished and buffed the other, opposite side are arranged so that they light (L) from the or record the light sources (6) and, if the flattening of it (3) is used Side on which Ange (3) rests, from the eye (3) reflected light (R) to the optical Conduct sensors (7). 2. Appianation tonometer according to claim 1, characterized in that that the axially movable measuring element (1) is drum-shaped and the light guide (2) are arranged in the drum-shaped Rorper so that their first ends on the lower surface of the drum-shaped body ends in parallel and ground flat and are polished to form an applanation surface (F) while their second ends at right angles to it on the outer peripheral surface of the drum-shaped body end up. 3. Appianation tonometer according to claim 2, characterized in that that the light guides (2) are arranged so that the second ends of the light receiving Light guide (2.1) on half a side of the circumference of the drum-shaped body are arranged and the second ends of the Reflexlicixt (R) leading light guide (2.2) on the other half side. 4. applanation tonometer according to claim 2, characterized ddii: rch, that the light guides (2) are arranged so that the second ends of the light guide are arranged in horizontal rows on the drum-shaped body in such a way that the ranks of upper half light-absorbing light guide (2.1) are and the rows of the lower half reflected light leading light guide (2.2) or reversed. 5b applanation tonometer according to claim 4, characterized in that that the horizontal rows of light receiving light guides (2.1) and reflected light leading light guide (2.2) alternate one after the other. 6. applanation tonometer according to claim 4, characterized in that that the horizontal rows of light receiving light guides (2.1) and Refle1icbt leading light guide (2.2) one after the other in groups. 7. applanation tonometer according to claim 2, characterized in that that the light guides (2) are arranged so that the second ends of the light receiving Light guide (2.1) and the second ends of the reflected light guiding light guide (2.2) are each arranged in vertical rows on the drum-shaped body. 8. applanation tonometer according to claim 7, characterized in that. that the vertical rows of light absorbing tichtleiter (2.1) and Alternating light guides (2.2) leading to reflected light. 9. applanation tonometer according to claim 7, characterized in that the vertical rows of light-absorbing light guides (2.1) and reflected light guiding Light guides (2.2) follow one another in groups. 10. applanation tonometer according to claim 2, characterized in that that the drum-shaped body is designed so that the circumference of the applanation surface (F) is smaller than the circumference of the body in the area of the exit surfaces of the light guides (2). 11. applanation tonometer according to claim 1, characterized in that that the axially movable measuring element (1) is prism-shaped and the ends the light guide (2) are ground flat at both ends. 12. applanation tonometer according to claim l, characterized in that that the light guides (2) in the prism-shaped element run in parallel order. 13. applanation tonometer according to claim 11, characterized in that that on the side opposite the applanation surface (F) to the light guide (2) a semi-reflective prism (13) for fading in the light (L) under one Angle is put on. 14. applanation tonometer according to claim 9, characterized in that that the axially movable measuring element (1) above the applanation surface (B) a has an elongated shape and that the light guide (2) from the applanation surface (F) are guided starting in such a way that their opposite second ends are one above the other end in one or more vertical rows. 215. applanation tonometer according to claim 14, characterized in that that the light guides (2) are arranged so that the ends of the light; absorbing tichtleiter (2.1) one above the other on one side of the elongated element in one or more rows end and the ends of the reflected light guiding light guides (2.2) in the same way on the other side of the elongated element. 16. applanation tonometer according to claim 14, characterized by, that the light guides (2) are arranged so that on each side of the elongated Element both light receiving light guide (2.1) and reflected light leading Light guides (2.2) each end one above the other in vertical rows, the rows for the ends of the light-absorbing light guides (2.1) and the rows of reflected light leading light guides (2.2) are arranged side by side. 17. applanation tonometer according to claim 16, characterized in that that the rows for the ends of the light receiving light guide (2.1) and the rows the ends of the reflected light guiding light guides (2.2) are arranged one above the other. 18. applanate; ion tonometer according to claim 14, characterized in that that in the vertical rubbing of the second ends of the light guide (2) alternately a light receiving light guide (2.1) and a reflected light guiding light guide (2.2) are arranged. 19. applanation tonometer according to claim 14, characterized in that that in the vertical rows of the second ends of the light guide (2) alternating groups Light-absorbing light guides (2.1) and groups of reflected light-guiding light guides (2.2) are arranged. 20. applanation tonometer according to claim 1, characterized in that that the light sources (6) are light-emitting diodes. 21. applanation tonometer according to claim 1 and 13, characterized in that that the light source (6) is an incandescent lamp with a condenser (9). 22. applanation tonometer according to claim 1, characterized in that that the light source (6) is an incandescent lamp with a diffuser (10). 23. applanation tonometer according to claim 1 to 20, gekE ¢ nazeich in that for each light provided in the axially movable measuring element (1) absorb Light guide (2.1) a light-emitting diode is arranged in the housing in such a way that it emits light into the light guide (2). 24. applanation tonometer according to claim 1 to 20, characterized in that that for each in the axially movable measuring element (1) provided reflected light leading Light guide (2.2) an optical sensor (7) is arranged in the housing such that he receives reflected light (R) from the light guide. 25. Applanation tonometear for measuring intraocular pressure the applanation principle, which has an axially movable 8S element, with the one aft is applied to the eye to flatten part of the surface of the eye and the cooperating means for determining the size of the flattened surface at a predetermined pressure or for detecting applied pressure at a predetermined one Size of the flattened surface contains, the axially movable measuring element consists essentially of light guides and the means interacting therewith contain one or more light sources and optical sensors. marked in that the light guides (2) serve on one of them to flatten the face (3) The side is ground and polished flat and on the opposite side to the planation surface (F) page of the movable element (1) on the ends of the individual fibers (2 ') of the light guide (2) alternately as light source (6) photoelectronic transmitter (6 ') and photoelectronic electronic Receiver (7 ') are arranged in such a way that each of a photoelectric Transmitter (6 ') in a light guide holder (2') sent light after reflection on the applanation surface (F) through the adjacent optical fiber (2 ') to the arrives on it arranged photoelectric receiver (7 '). 26. Applanation tonometer for measuring intraocular pressure after Applanation principle, which has an axially movable measuring element with which a force is applied to the eye to flatten part of the surface of the eye and that cooperating means for determining the size of the flattened surface at a given pressure or to determine the pressure exerted at a predetermined size of the flattened surface, the axially movable Measuring element consists essentially as light guides and the interacting therewith Means containing one or more light sources and optical sensors, characterized in that the light guide (2) on the side serving to flatten the eye of the movable element (1) are ground and polished flat, and that on the the side of the movable element (1) opposite the applanation surface (F) on the ends of the individual fibers (2 ') of the light guide on each fiber (2') respectively an optoelectronic receiver over a portion of the cross section of the surface (7 ') is arranged such that the from an external light source (6) through the The remaining free part of the section irradiated into the optical fiber (2 ') and light reflected by the applanation surface (F) from this receiver (7 ') can be recorded and converted into electrical signals. 27. applanation tonomster according to claim 26, gekennzeicbnet characterized, that on each fiber (2 ') of the light guide (2) arranged optoelectronic Receiver (7 ') covers half the cross section of the optical fiber (2'). 28. applanation tonometer according to claim 26, characterized in that that on each fiber (2 ') of the light guide (2) arranged optoelectronic Receiver (7 ') is designed as a circle segment area or semicircle area. 29. applanation tonometer according to claim 26, characterized in that that the optoelectronic arranged on each fiber (2 ') of the light guide (2) Receiver (7 ') is designed as a circular ring. 30. applanation tonometer according to claim 26, characterized in that, that on each fiber (2 ') of the light guide (2) arranged optoelectronic Receiver (7 ') is arranged as a central circular surface, which is one than the Cross-sectional area of the optical fiber. 31. applanation tonometer according to claim 26, characterized in that that the light source (6) in the fixed part of the housing by one or more formed opposite the movable element arranged light-emitting diodes and is arranged behind a scattering film. 32. applanation tonometer according to claim 1: 25 and 26, characterized in that as light any electromagnetic wavelength from ultraviolet to Infrared, both in the light bar and in the invisible range is used. 33. applanation tonometer according to claim 1; 25 and 26, marked in that the wavelength of the light in the InSraS red range from 0.85 to 25 µm lies. 34. applanation tonometer according to claim 1: 25 and 26, characterized in that the wavelength is on the order of 1.3 µm. 35. applanation tonometer according to claim 1: 25 and 26, characterized in that the light is clocked. 36. applanation tononeter according to claim 1; 25 and 26, marked in that a Sckwellenwertgeber is provided for eliminating the electrical signals is caused by light below a given light intensity from the optical Sensors (7: 7 ') are generated. 37. Applanation tonometer for measuring intraocular pressure after Applanation principle, which has an axially movable measuring element with which a force applied to the eye to flatten part of the surface of the eye and that cooperating means for determining the size of the flattened surface contains, characterized in that the axially movable measuring element (1) on the one or more acoustic applanation surfaces (F) serving to flatten the eye (3) Has surface acoustic wave transducers (30), the input or transmitter interdigital transducers thereof (30.1) are fed with a certain input frequency and their output or receiver interdigital transducer (30.2) connected to electronic means are in which one occurs due to the application of the applanation surface to the eye (3) Attenuation or change in the transit time is converted into a frequency change and the resulting frequency can be further processed into an analog or digital display that is calibrated in units of intraocular pressure. 38. applanate; ion tonometer according to claim 37, characterized in that that the surface acoustic wave transducer (30) on the to flatten the eye (3) serving surface (F) of the axially movable measuring element (1) are arranged so that they are located outside the flattened surface of the eye in the peripheral area of the applanation surface (F) are located. 39. applanation tonometer according to claim 37, characterized in that that the acoustic surface wave converter (30) on the applanation surface (F) of the axially movable measuring element (1) are arranged so that they are wholly or partially be covered by the flattened surface of the eye. 40. applanation tonometer for measuring intraocular pressure after Applanation principle, which has an axially movable measuring element with which a force exerted on the eye to flatten part of the surface of the eye and that cooperating means for determining the size of the flattened surface at a predetermined pressure, or to determine the pressure exerted at a specified size of the flattened surface contains, marked through this, that on the flattening of the eye (3) serving the applanation surface (F) of the bewebaren measuring element (1) a plurality of pressure sensors (40) ad the base of Semiconductor crystals is arranged, the different by Noutronendotierw te Resistor materials are formed with multiple resistors in bridge circuit are doped in that a supply voltage is fed to the bridge circuits and there are output lines leading to an electronic evaluation circuit guided; are. 41. applanation tonometer according to claim 40, marked; through this, that the pressure sensors (40) are arranged on the applanation surface (F) in the form of a matrix are. 42. applanation tonometer according to claim 40, characterized in that that the pressure sensors (40) are arranged on the applanation surface (F) in the form of a star are. 43. applanate; ion tonometer according to claim 40, characterized in that that the pressure sensors (40) on the applanation surface (F) in the form of a spiral are arranged 44. applanation tonometer according to claim 40, characterized in that that the pressure sensors (40) on the applanation surface (B) in the form of a cross are arranged. 45. applanation tonometer according to claim 40, characterized in that that the grid dimension of the pressure sensors (40) is below 300 µm. 46. applanation tonometer according to claim 40, characterized in that that the grid dimension of the pressure sensors (40) in a range of 50 to 100 microns or is below. 47. applanation tonometer according to claim 40, characterized in that that the information present in the form of an electrical signal in the pressure sensor (40) is pushed out in pulses and removed line by line. 48. applanation tonometer according to claims 1, 25, 26, 37 and 40, characterized in that the axially movable measuring element (1) is in a housing (5) is arranged against which it performs a relative movement that there is a predetermined Assigns its own weight and that the measuring sensors arranged on its application surface (F) are smoothly in operative relationship with the housing (5). 49. applanation tonometer according to claim 48, characterized in that that the housing (5) used for handling, the batteries used for power supply (25), the coupling means for smooth energy transfer to and from the axially movable Measuring element (l), the entire electronic evaluation circuit (26) and the display (27) contains. 50. applanation tonometer according to claim 48, characterized in that that the smooth coupling of the axially movable measuring element (1) with the housing (5) takes place via optocouplers (22.1 and 22.2). 51. applanation tonometer according to claim 50, characterized in that that the optocoupler (22.1 and 22.2) from light-emitting diodes and photodiodes or ototranistors exist. 52. applanation tonometer according to claims 1, 25, 37, 40 and 48, characterized in that the axially movable measuring element (1) is designed in the shape of a prism is and. that the optocoupler elements connected to the measuring sensors (22.1 and 22.2) on the surface of the prism-shaped, axially movable measuring element (1). are arranged. 53. applanation tonometer according to claim 50, characterized in that that the provided in the housing opt ocoupler element e (22.1 and 22.2) opposite the upper surface of the prism-shaped, axially movable measuring element (1) in the Housing (5) are arranged. 54. applanation tonometer according to claim 48, characterized in that that the smooth coupling of the axial. movable measuring element (1) with the housing (5) takes place inductively. 55. applanation tonometer according to claim 54, characterized in that that for energy transmission from the housing (5) to the measuring sensors anf the axially movable Measuring element (1) in the housing (5) an inductive transmitter (28) is arranged and ad the axially movable measuring element (1) each with an inductive receiver (29) connected to the inputs of the measuring sensors is connected, and that the outputs of the measuring sensors for energy transmission on the housing (5) each with aaf the axially movable measuring element (1) arranged inductive encoder (28) are connected, each with an inductive Receiver (29) in the housing (5) is in operative relationship. 56. applanation tonometer according to claim 55, characterized in that that the inductive elements are listed as coils. 57. applanation tonometer according to claim 55, characterized in that that the inductive elements as aifgedampfte or other known methods applied strands are executed. 58. applanate; ion tonometer according to claim 48, characterized in that that at the point of the housing (5) at which the anal movable measuring element (1) emerges, on the inner wall of the housing (5) at least three optocouplers (22) over the circumference are arranged distributed and that at the point of the axially movable measuring element (1) which is opposite the optocouplers (22) when the device is on, a reflective coating (23) is applied in a ring. 59. Applanation tonometer according to Auilct 58, characterized in that the optocouplers (22) are reflex couplers. 60. applanation tonometer according to 1inkt 58 and 59, characterized in that that the receiver of the optocoupler (22) is connected to a monitoring circuit are. 61. applanation tonometer according to claim 1, 25, 26, 37, 40 and 48, characterized in that the applanation surface (F) has a smooth coating. 62. applanation tonometer according to claim 1, 25 and 26, characterized in that photoelectronic transmitters and photoelectronic receivers in connection find with L'ichtleiterelementon as dimensional sensors use. 63. applanation tonometer according to claim 37, characterized in that that surface acoustic wave transducers are used as measuring sensors. 64. applanation tonometer according to claim 41, characterized in that that semiconductor pressure sensors are used as directly applied measuring sensors.