KR20110054584A - Intraocular pressure measuring device - Google Patents

Abstract

PURPOSE: An intraocular pressure measuring device is provided to accurately check causes of an intraocular pressure change, thereby increasing the accuracy of measuring intraocular pressure. CONSTITUTION: A micro injection needle(10) has a hollow structure. An ultra thin film(20) blocks the entrance of the fine injection needle to perform a waterproof function. A pressure sensor(30) is attached to an ultra thin film while the pressure sensor is inserted into the micro injection needle. The pressure sensor measures intraocular pressure applied to the ultra thin film in real time. A micro chip(40) is electrically connected to the pressure sensor while the micro chip is inserted into the micro injection needle. The micro chip collects pressure data measured by the pressure sensor and transmits the pressure data to an RFID transmitter(50). The RFID transmitter is electrically connected to the micro chip while the RFID transmitter is inserted into the micro injection needle. The RFID transmitter amplifies pressure data received from the micro chip and transmits the pressure data to the outside by a high frequency wave.

Description

Intraocular Pressure Measuring Device

TECHNICAL FIELD The present invention relates to a medical technique, and relates to an apparatus for measuring intraocular pressure of a patient in the diagnosis and treatment of glaucoma.

Glaucoma is a disease in which optic nerve damage occurs because the optic nerve cannot tolerate the increased pressure due to intraocular pressure in the eye. Therefore, the most important problem in diagnosing and treating glaucoma is how accurately the intraocular pressure is measured.

To date, intraocular pressure has been called indirect measurement. In the analogy of a full-fledged soccer ball, the easiest way to tell if a soccer ball is out of wind (= pressure is down) or if the wind is full (= pressure up) is Will press. In other words, the pressure is applied to the feeling of fingertips. The same is true of intraocular pressure measurement, which indirectly measures intraocular pressure by pressing the corneal surface of the eye with a specific instrument.

What I really want to know is the actual intraocular pressure in the snow, but if you're a soccer ball, you can put a pressure sensor in the wind hole and apply pressure, but the human eye can't do that.

However, as with all indirect methods, there are many variables that affect the measurement of intraocular pressure, but many of them do not yet know the variable, and the known variable is used in terms of intraocular pressure. It has not been proved to be an exact match.

The present invention has been proposed to solve the above problems, and an object of the present invention is to provide an intraocular pressure measurement device capable of purely measuring intraocular pressure while controlling other variables that may affect intraocular pressure. In addition, as a concept of glaucoma, the trend of continuous 24-hour intraocular pressure and measurement of real-time intraocular pressure have emerged as a very important concept for etiology and treatment. It is an object of the present invention to provide an intraocular pressure measurement device that can measure in real time.

Other objects and advantages of the present invention will be described below, which are not limited to the matters set forth in the claims and the disclosure of the embodiments thereof, but also to the broader ranges by means and combinations within the range readily recited therefrom. Add that it will be included.

In order to achieve the above object, the present invention, the hollow fine needle; Ultra-thin film to block the inlet of the fine injection needle to be waterproof; A pressure sensor attached to the ultra-thin film in the state inserted into the micro-scan needle, for measuring the intraocular pressure acting on the ultra-thin film in real time; A microchip electrically connected to the pressure sensor in a state of being inserted into the fine injection needle, and collecting the pressure data measured by the pressure sensor and transmitting the collected data to the RFID transmitter; The present invention provides an intraocular pressure measurement apparatus including an RFID transmitter which is electrically connected to a microchip in a state of being inserted into a microscanning needle, and amplifies the pressure data received from the microchip and transmits it to the outside in a high frequency form.

Traditionally, intraocular pressure-measuring instruments indirectly estimate the intraocular pressure in the eye through a medium called the cornea, and it is difficult to control the various variables that may affect the intraocular pressure measurement, so these are the intraocular pressures. It is difficult to form a causal relationship between the progression and the progression of glaucoma, making accurate diagnosis and treatment difficult. Therefore, how to overcome these problems was the main concern of ophthalmologists (especially glaucoma specialists).

In addition, the 'variable variables' described above are changed every time (for example, even when the blood pressure is measured, the values vary depending on when the diastolic diastolic blood pressure is measured. In patients with elevated intraocular pressure and poor glaucoma, it is difficult to know what causes intraocular pressure change without control of these variables and thus obscure the decision of treatment direction.

According to the present invention, it is possible to exclude variables that may affect intraocular pressure from the beginning, so that only intraocular pressure in pure eyes can be measured, and thus, a causal relationship can be established to track pathology. In addition, it is possible to track the 24-hour intraocular pressure change, which is gaining importance in recent years, to help uncover new mechanisms for glaucoma risk factors.

Other effects of the present invention, as well as those described in the above-described embodiments and claims of the present invention, as well as potential effects that may occur within the range that can be easily estimated therefrom and potential advantages that contribute to industrial development It will be added that it will be covered by a wider scope.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, the following will describe a preferred embodiment of the present invention, but the technical idea of the present invention is not limited thereto and may be variously modified and modified by those skilled in the art.

1 shows an overall configuration of an intraocular pressure measuring device according to the present invention.

The intraocular pressure measuring apparatus according to the present invention has a structure in which the pressure sensor 30, the microchip 40, and the RFID transmitter 50 are inserted into the fine injection needle 10 having the ultra-thin film 20 attached to the inlet. Thus, the device for measuring intraocular pressure according to the present invention appears to be in appearance only one fine injection needle 10.

The fine injection needle 10 is a hollow, narrow needle. In other words, the fine injection needle 10 may be referred to as a form in which the general injection needle is reduced to a very small size. The micro-injection needle 10 should be small and thin enough to remain plugged or plugged into the patient's eye without causing pain because the patient's eye pressure needs to be continuously held in the patient's eye for a predetermined time. .

2 shows a state in which the micro-injection needle 10 (the intraocular pressure measuring device according to the present invention) measures the intraocular pressure in a state where the microneedle 10 is inserted into the patient's eye.

The micro injection needle 10 is inserted into the eye of the patient using a separate injector 60. In the case of the present invention, the injector 60 is not particularly limited, and thus, the injector 60 having various forms or working principles may be applied to the present invention.

For example, a groove (A in FIG. 1) to which the micro-injection needle 10 can be mounted at the end of the injector 60 is loosely configured and the micro-injection needle 10 is slightly attached thereto, and the injector 60 ) To the patient's eye can be used to insert the micro-injection needle 10 in the patient's eye and then only take out the injector 60 again. Alternatively, the forceps type injector 60 may be used to pick a fine injection needle 10 and stick it to the patient's eye.

The ultra-thin film 20 blocks the inlet of the fine injection needle 10 to be waterproof. Therefore, in this state, when the micro-needle 10 is inserted into the patient's eye (more precisely, the boundary between the cornea and the white of the eye), the entrance of the micro-needle 10 is waterproof in the eye (which forms intraocular pressure in the eye). Contact with water) and the intraocular pressure acts on the ultra-thin film 20.

The pressure sensor 30 measures the intraocular pressure acting on the ultra-thin film 20 in real time. The pressure sensor 30 is attached to the ultra-thin film 20 while being inserted into the fine injection needle 10.

The microchip 40 is electrically connected to the pressure sensor 30 in a state of being inserted into the fine injection needle 10. The microchip 40 is a packaged computer circuit made of a very small size using a material such as silicon. In the present invention, the microchip 40 collects pressure data measured by the pressure sensor 30, and thus After performing the analog-to-digital conversion for the RFID transmitter 50 serves to transmit again.

The RFID transmitter 50 is electrically connected to the microchip 40 in the state of being inserted into the fine injection needle 10. The RFID transmitter 50 amplifies the pressure data received from the microchip 40 and transmits it to the outside in a high frequency form.

In this case, if the receiver of the pressure data sent to the outside is attached to the place of glasses, real-time or 24-hour intraocular pressure can be recorded and stored in the patient's home, and the doctor recalls and records the pressure data when the patient comes out of the hospital. Can be analyzed and used as a reference. Some kind of ubiquitous is applied.

On the other hand, in the embodiment of the present invention, while holding the RFID transmitter 50 as a medium for transmitting the pressure data received from the microchip 40 to the outside, it is to be clear that it is not intended to limit only to the RFID transmitter 50. do. Therefore, in the present invention, the RFID transmitter 50 is preferably interpreted to encompass short-range wireless communication-WIFI and the like that can perform a similar role.

As described above, according to the present invention, since a variable that may affect intraocular pressure can be excluded from the beginning, only intraocular pressure in pure eyes can be measured, and thus, a causal relationship can be established to track pathology. In addition, it is possible to track the 24-hour intraocular pressure change, which is gaining in importance in recent years, to help uncover new mechanisms for glaucoma risk factors.

The above description is merely illustrative of the technical idea of the present invention, and various modifications, changes, and substitutions may be made by those skilled in the art without departing from the essential characteristics of the present invention. will be. Accordingly, the embodiments disclosed in the present invention and the accompanying drawings are not intended to limit the technical spirit of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by the embodiments and the accompanying drawings. . The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

1 shows an overall configuration of an intraocular pressure measuring device according to the present invention.

2 shows a state in which the intraocular pressure measurement device according to the present invention measures the intraocular pressure in the state of being plugged into the eyes of the patient.

<Description of Major Symbols in Drawing>

10: fine injection needle

20 ultrathin

30: pressure sensor

40: microchip

50: RFID transmitter

60: injector

Claims (1)

Hollow micro needles; Ultra-thin film to block the inlet of the fine injection needle to be waterproof; A pressure sensor attached to the ultra-thin film in the state inserted into the micro-scan needle, for measuring the intraocular pressure acting on the ultra-thin film in real time; A microchip electrically connected to the pressure sensor in a state of being inserted into the fine injection needle, and collecting the pressure data measured by the pressure sensor and transmitting the collected data to the RFID transmitter; The RFID transmitter is electrically connected to the microchip in the state of being inserted into the micro needle, and amplifies the pressure data received from the microchip and transmits it to the outside in high frequency. Intraocular pressure measurement device comprising a.

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