RU2665112C1 - Measurement method of intraocular pressure and device for implementation thereof - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: group of inventions relates to medical equipment. Method for measuring intraocular pressure consists in exposing the surface of the eye cornea to an air stream in the form of a plurality of pneumatic pulses, the magnitude of which varies from a minimum value in increasing order. Deformation of the surface of the cornea of the eye is measured at the same time. In this case, the intraocular pressure is determined from the value of the minimum pressure of pulses of the pneumatic flow, under the influence of which the deformation of the surface of the cornea occurs. Device consists of a sealed housing with an outlet, in which a compressor, a pressure gauge and a distance sensor are located. With the help of the compressor, many pneumatic pulses are formed.EFFECT: application of this group of inventions will reduce unpleasant sensations when carrying out measurements of intraocular pressure.3 cl, 1 dwg

Description

The invention relates to medical equipment and can be used to measure intraocular, intracranial and other surface pressure.

Known methods for determining intraocular pressure (hereinafter IOP) according to Maklakov and Goldman, based on the installation on the human eye of a certain load or plunger with a flat surface. The area of contact of the cargo with the surface of the eye (the size of the punching) determines the value of intraocular pressure.

The disadvantages of all methods of measuring IOP directly through the surface of the sclera or cornea include the psychological inconvenience of patients, because the eye must be anesthetized, immobilized, and the eyelids closed, since plungers, weights and rods are installed on an unprotected eye.

Known methods for non-contact IOP measurement, patents RU 2067845, US 3585849, taken as a prototype, which use a pneumatic (air) impulse in the direction of the eye, acting on the surface of the cornea with a certain pressure, which obviously deforms the surface of the cornea of the eye. IOP is determined by the magnitude of the deformation of the surface of the cornea of the eye.

When measuring IOP using these instruments, it is necessary to ensure full flattening of the cornea of the eye with the help of a pneumatic impulse, which can cause unpleasant pain in a person and even injure the eye; significant discrepancies are observed between the results of measurements of high IOP values by the standard contact method and those presented by non-contact methods (Forbes M., Piko G., Grolman B. A noncontact applanation tonometer // Arch. Ophthalmol. 1974. Vol. 91, No. 2. P. 134 -140.); IOP measurement is difficult for defective corneas (opacities, scars, etc.), as well as for patients with significant myopia or hyperopia (Graf M., Hoffrmann, O. F. Reproducibility of NCT results comparison with the Goldmann applanation tonometer // Klin. Mbl. Augenheilk. 1992. No. 6. S. 678.). This is due to the fact that the patient must clearly see a special target with the help of a complex adjustment system, otherwise a pneumatic impulse can act tangentially on the cornea, which will lead to an overestimation of the IOP. In addition, it is known that the rigidity of the cornea affects the result of IOP measurement during deformation of the corneal surface. Rigidity of the cornea of the eye is due to the fact that the cornea and sclera of the human eye do not stretch under the influence of excessive intraocular pressure (in patients with glaucoma, the volume of the eye does not change). According to the Friedenwald formula (Nesterov A.P., Bunin A.Ya., Katsnelson L.A. Intraocular pressure. Physiology and pathology. // M .: Nauka. - 1974. - P. 32) deformation of the surface of the cornea of the eye is associated with rigidity the following relation:

where P _o is the true IOP, P _t1 and V _c1 are the pressure and volume of the eye fluid displaced during tonometry with the weight of the plunger 5.5 g, E is the eye rigidity, which is determined by the formula:

where P _t2 and V _c2 are the pressure and volume of the eye fluid displaced during tonometry with a plunger weight of 10 g. When measuring IOP with one deforming air pulse, corneal rigidity is almost impossible to take into account.

The technical result is aimed at creating a method for measuring IOP, allowing the patient to experience minimal discomfort during the procedure for measuring IOP using pneumatic pulses of minimum power directed to the surface of the cornea of the eye, while the IOP should be measured taking into account rigidity of the cornea of the eye.

In the present invention, the technical result is achieved by the action of air flow on the surface of the cornea of the eye in the form of a plurality of pneumatic pulses, while the pressure value of the pneumatic pulses changes according to a certain program, and the IOP value is determined by the minimum value of the pneumatic pulsed pressure, under which the surface of the cornea of the eye begins to deform.

The method of measuring intraocular pressure and a device for its implementation is illustrated by figure 1.

The figure 1 shows a device for measuring intraocular pressure.

Typically, when IOP is measured by pneumatic methods, the surface of the cornea of the eye is deformed by a single powerful pneumatic shock, which uniquely crushes the surface of the cornea and allows one to measure a significant amount of deformation of the surface of the cornea of the eye. This leads to the fact that after a pneumatic impulse the eye reflexively closes, and the person starts.

, то согласно уравнению (2) ригидность будет равна:If the cornea of the eye is affected by a load of not 5.5 g, but the minimum load at which the deformation of the cornea begins

, then according to equation (2) the rigidity will be equal to:

Using the Friedenwald formula lg (P _t1 ) -lg (P ₀ ) = E⋅V _c1 in the form:

and substituting equation (4) in equation (3) we have:

P _IOP = P _t1 .

The obtained result suggests that the minimum pressure at which deformation of the cornea occurs is equal to intraocular pressure. It is practically impossible to select the pressure equal to the IOP using weights, and it is possible to determine the minimum value of the pressure of pneumatic pulses on the surface of the cornea of the eye, at which deformation of the surface of the cornea of the eye begins. Therefore, instead of one powerful pneumatic (air) shock, it is enough to form an air flow on the surface of the cornea of the eye in the form of a plurality of pneumatic pulses of increasing force (from the minimum value). At the same time, high-precision optical methods, for example, the triangulation method (patent RU 2315949), measure the deformation of the surface of the cornea - the distance to the surface of the cornea. To measure IOP, taking into account rigidity of the cornea of the eye, the value of the minimum pneumatic pulsed pressure is determined when the surface of the cornea of the eye begins to deform.

The authors propose a method for measuring intraocular pressure, which consists in exposure to the surface of the cornea of the eye with an air stream in the form of many pneumatic pulses, the magnitude of which varies from the minimum value in increasing order, and at the same time measuring the deformation of the surface of the cornea of the eye, while the intraocular pressure is determined by the value of the minimum pressure pulses of pneumatic flow, under the influence of which there is a deformation of the surface of the cornea.

The method for measuring intraocular pressure works as follows (see Fig. 1): at a certain distance from the surface of the cornea of the eye 1, an outlet is installed in the body of the device 2, through which the air stream exits in the form of many pneumatic pulses. An air pulse flow is generated using a compressor 3 installed in a sealed enclosure 2 with an outlet, and the pressure generated by the compressor in a sealed enclosure is measured by an air pressure sensor — manometer 4. Pneumatic pulses having a known pressure in the sealed volume exit through the outlet of the enclosure 2 and extend toward the surface of the cornea of the eye 1. The pressure of the air pulse flow decreases with increasing distance from the outlet to the surface of the cornea g aza. If the distance is known exactly, then the pressure on the surface of the cornea of the eye is determined accurately. If the distance changes, which is more likely, then the distance sensor 5 can measure, take into account and accurately determine the pressure of the pneumatic impulse on the surface of the cornea. As a distance sensor, you can use triangulation, interference, ultrasound, etc. rangefinders. Further, the pressure of the pneumatic pulses of the air flow varies from the minimum value to increasing, while simultaneously measuring the deformation of the surface of the cornea of the eye. IOP is determined by the minimum pressure of the pulses of the pneumatic flow at which the deformation of the surface of the cornea occurs. The deformation of the surface of the cornea of the eye is measured by the same distance sensor 5, which measures the distance from the outlet of the body 2 to the surface of the cornea of the eye 1.

Triangulation and interference methods allow you to measure the deviation of the position of the surface of the cornea of the eye with an accuracy of 10 μm and 0.5 μm, respectively. This accuracy is many times higher than the real minimum deformation of the surface of the cornea of the eye.

The distance from the outlet of the sealed body to the surface of the cornea of the eye can be fixed rigidly by fixing the body of the device on the eye socket, then you can not measure the distance.

To account for the movement of the eye, at which a slow change in the distance from the surface of the eye to the outlet of the body can occur, it is advisable to measure the distance, both at the moments of exposure to a pneumatic impulse and at times between pneumatic impulses.

An intraocular pressure measuring device based on the presented method consists of a sealed housing with an outlet in which a compressor is located, with which an air flow is formed in the form of a set of pneumatic pulses, the value of which increases from the minimum value, a pressure gauge with which pulse pulses are measured air in a sealed volume, and a distance sensor, while the intraocular pressure is determined by the minimum pressure of pulses of pneumatic current at which the deformation of the surface of the cornea.

As a sensor of the distance from the outlet of the body to the surface of the cornea of the eye, you can use triangulation, interference, ultrasound, etc. rangefinders.

The intraocular pressure measuring device works as follows (see figure 1) - the outlet of the sealed enclosure 2 is installed at a certain distance from the surface of the cornea of the eye 1. To accurately determine the pressure force of the variable air flow on the surface of the cornea, it is necessary to know the pressure of each air pulse in the sealed volume and the distance from the outlet of the sealed body to the surface of the cornea. To do this, a pressure gauge 4, installed in an airtight volume, and a distance sensor 5, which measures the distance from the outlet of the body to the surface of the cornea of the eye, are used. Then, using a compressor 3 installed in the sealed volume of the housing 2, an air stream is created in the form of a plurality of pneumatic pulses exiting through the outlet of the sealed housing 2. The pressure of the air flow pulses is measured by a pressure gauge 4 and increases from the minimum value. At the same time, a distance sensor 5 measures the deformation of the surface of the cornea of the eye. The IOP is measured by the minimum pressure of the pneumatic flow pulses at which the corneal surface deforms. To take into account the movement of the eye, at which a slow change in the distance from the surface of the eye to the exit opening of the body can occur, it is advisable to measure the distance both at the moments of exposure to the pneumatic impulse and at the times between the pneumatic impulses.

To reduce the unpleasant sensations of the patient associated with the effect of a constant air flow in the form of pneumatic pulses, it is advisable to form an alternating air pulse flow. Then, a continuous pulsed air stream will not flow over the surface of the cornea and sclera, leading to unpleasant sensations and drying the surface of the eye. To realize such an air flow, an alternating pulsed air flow can be formed when both pneumatic pulses of air pressure and pneumatic pulses of reverse air movement, which create rarefaction zones above the corneal surface, come out of the openings of the sealed enclosure. This mode of operation is easily implemented using a vibration compressor installed in a sealed enclosure. Impulses of rarefied pressure cannot affect the surface of the cornea of the eye, because it is inextensible (has rigidity).

Claims (3)

1. A method for measuring intraocular pressure, which consists in exposing the surface of the cornea to the air stream in the form of a plurality of pneumatic pulses, the magnitude of which varies from the minimum value to increasing, simultaneously measuring the deformation of the surface of the cornea of the eye, while the intraocular pressure is determined by the value of the minimum pressure of the pulses of the pneumatic flow, under the influence of which there is a deformation of the surface of the cornea. 2. A method for measuring intraocular pressure according to claim 1, characterized in that the surface of the cornea of the eye is affected by a plurality of alternating pneumatic pulses. 3. A device for measuring intraocular pressure, consisting of a sealed housing with an outlet in which a compressor, a manometer and a distance sensor are located, characterized in that a plurality of pneumatic pulses are generated with the help of the compressor, the magnitude of which changes from the minimum value to increasing, while the intraocular pressure is determined by the minimum pressure value of the pulses of the pneumatic flow at which the deformation of the surface of the cornea occurs.

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