KR20230126977A - Micro current stimulation apparatus for regenerating corneal tissue - Google Patents

Abstract

The present invention relates to a microcurrent stimulator for corneal tissue regeneration.
The microcurrent stimulator for corneal tissue regeneration according to the present invention includes an electrode unit that is seated in contact with the patient's face around the eyeball and transcutaneously transmits electrical stimulation of the microcurrent to the eyeball periphery; and a main body portion that is worn around the patient's eyeball and is mechanically and electrically connected to the electrode portion to provide a current pulse signal to the electrode portion so that the electrode portion percutaneously transmits electrical stimulation of a microcurrent to the eyeball periphery; , The first and second current pulse signals are generated by the first and second current pulse signal generators of the body part, respectively, and supplied to the first to fourth 4-channel electrodes of the electrode part, and the electrical stimulation accordingly is transcutaneous. ) to the eyeball and peripheral nerves. The current delivered to the ocular and peripheral nerves induces an increase in NGF (Nerve Growth Factor), and the increase in NGF accelerates the regeneration of the corneal nerve. In addition, electrical stimulation is applied to the tertiary nerve located around the eyeball to affect the afferent nerve to induce tear production. After all, as described above, electrical stimulation promotes the regeneration of corneal epithelial cells and nerves, leading to recovery of ocular surface diseases.

Description

Micro current stimulation apparatus for regenerating corneal tissue}

The present invention relates to a microcurrent stimulator for corneal tissue regeneration, and more particularly, by attaching an electrode patch to the skin where the eyeball and nerves around the eyeball are located, and transcutaneously transmitting electrical stimulation, nerve growth factor (NGF; It relates to a microcurrent stimulator for corneal tissue regeneration that can ultimately promote regeneration of corneal epithelial cells and nerves by inducing an increase in Nerve Growth Factor and tear production.

Ocular surface diseases caused by damage to corneal epithelial cells and corneal nerves are a situation in which the number of patients at home and abroad is greatly increasing every year due to the increase in the aging population. However, the medical device approach to this is weak.

The nerve distributed in the cornea is a part of the trigeminal nerve and performs the function of monitoring the state of the cornea through the sense of pain, determining the degree of dryness or damage of the cornea, and causing a biological response accordingly. As part of these functions, the corneal nerve is involved in tear secretion, tear film stabilization, tear component composition, blinking reflex, and repair of corneal wounds.

For the above reasons, various studies that have performed electrical stimulation to regenerate damaged nerves have been attempted, and lacrimal secretion is controlled by the response of the afferent tertiary nerve distributed on the corneal surface. There is a research result that damage can cause dry eye syndrome. In addition, there are also research results that apply electrical stimulation to the trigeminal nerve to affect the afferent nerve and induce tear production. With this principle, there have been studies that corneal scar tissue and nerves are healed, and dry eye or sensory symptoms are restored.

Although the mechanism of nerve recovery of TES (transcranial electric stimulation), which flows microscopic electricity in a non-invasive manner, has not been clarified, there are several research papers related to the eye, such as the cornea and retina, such as dry eye syndrome. In particular, according to the study of the Ghaffariyeh group, it has been reported that the sensory function of the cornea is restored to some extent with only one electrical stimulation immediately after vision correction surgery. Results included accelerated nerve regeneration and increased tissue regeneration. In addition, a study by Chang et al. revealed that electrical stimulation promotes the expression of nerve growth factor (NGF) required for nerve recovery, which was also confirmed in corneal cells of tertiary nerve electrical stimulation animal experiments. Through these previous studies, it can be hypothesized that regenerating damaged corneal nerves can be an effective method for treating ocular surface diseases. Recently, studies have been conducted for the purpose of treating corneal-related diseases using the nerve growth factor (NGF) as described above, and a dry eye treatment using NGF is being developed and studied overseas. Therefore, there is an urgent need to develop a medical device for treating ocular surface diseases caused by corneal epithelial cell damage and corneal nerve damage, and ultimately regenerating corneal epithelial cells and nerves.

On the other hand, Korean Patent Publication No. 10-2017-0058958 (Patent Document 1) discloses "a multi-wavelength phototherapy device, system, and method for non-invasive treatment of damaged or diseased tissue", and patients according to this A self-contained device for delivery of light therapy to ocular tissue of an eye of a person comprising: a housing comprising an interior; an eyepiece disposed on the housing, constructed and arranged for placement of a patient's eye adjacent the eyepiece; a first light source that generates a first light beam having a first therapeutic wavelength and is disposed within the housing; a second light source that produces a second light beam having a second therapeutic wavelength and disposed within the housing, the second therapeutic wavelength differing from the first therapeutic wavelength by at least 25 nm; and an aperture disposed within the housing constructed and arranged to direct the first and second light beams therethrough and through the eyepiece to provide light therapy to the eye of the patient. characterized by

In the case of Patent Document 1 as described above, by generating and directing the first and second light beams having the first and second treatment wavelengths to the patient's ocular tissue, there will be some effect of treating the damaged or diseased ocular tissue. However, as the light beam is irradiated to the inside of the eyeball tissue, the light beam is irradiated to other optic nerves inside the eyeball, which poses a risk of adversely affecting the normal optic nerve.

Korean Patent Publication No. 10-2017-0058958 (May 29, 2017)

The present invention was created in consideration of the above matters comprehensively, and by attaching an electrode patch to the skin where the eyeball and the nerves around the eyeball are located, and transmitting electrical stimulation transcutaneously, Nerve Growth Factor (NGF) Its purpose is to provide a microcurrent stimulator for corneal tissue regeneration that can ultimately promote regeneration of corneal epithelial cells and nerves by inducing increase and tear production.

In order to achieve the above object, the microcurrent stimulator for corneal tissue regeneration according to the present invention,

An electrode unit that is seated in contact with the patient's face around the eyeball and transfers electrical stimulation of microcurrent to the eyeball periphery transcutaneously; and

A main body that is worn around the patient's eyeball and is mechanically and electrically connected to the electrode unit to provide a current pulse signal to the electrode unit so that the electrode unit percutaneously transmits electrical stimulation of a microcurrent to the eyeball periphery. has its characteristics.

Here, the electrode part,

a 4-channel electrode composed of four x-shaped branches and transcutaneously transmitting microcurrent electrical stimulation of first to fourth channels to the periphery of the eyeball; and

Including an electrode-body connection part integrally formed with a 4-channel electrode at about the middle of the 4-channel electrode and mechanically and electrically connected to the connection part provided in the main body part when the patient wears the main body part around the eyeball can be configured.

In addition, the body part,

a housing in the form of goggles;

a first current pulse signal generating unit installed inside the housing and generating a first current pulse signal;

a second current pulse signal generating unit installed inside the housing and generating a second current pulse signal;

an up/down button unit installed on a predetermined portion of the housing and configured to increase or decrease the strength of the current pulse signal generated by the first and second current pulse signal generators;

a communication unit that communicates with an external electronic device or network system;

The first and second pulse signal generating units, the up/down button unit, and the communication unit respectively control state checks and operations, and allow the electrode unit to transcutaneously transmit electric stimulation of a microcurrent to the eyeball periphery. a controller configured to send control command signals to the first and second current pulse signal generators, respectively, to generate current pulse signals to the first and second current pulse signal generators; and

It may be configured to include a power supply unit for supplying power necessary for driving the first and second current pulse signal generators, the up/down button unit, the communication unit, and the control unit, respectively.

Here, the first current pulse signal generated by the first current pulse signal generator is a positive (+) current pulse signal, and the second current pulse signal generated by the second current pulse signal generator is negative ( -) of the current pulse signal.

In addition, the first current pulse signal generated by the first current pulse signal generator is supplied to the first and second channel electrodes among the first to fourth 4-channel electrodes, and the second current pulse signal generator The second current pulse signal generated by may be configured to be supplied to the third and fourth channel electrodes.

In addition, the first current pulse signal generator may be configured to generate the first current pulse signal for 250 μs, and the second current pulse signal generator may be configured to generate the second current pulse signal for 250 μs.

At this time, after the first current pulse signal generator generates the first current pulse signal for 250 μs and then has an interface interval in which the current intensity is 0 (zero) for 5 μs, the second current pulse signal generator generates the second current pulse signal. The first current pulse signal is generated for 250 μs, or the second current pulse signal generation unit generates the second current pulse signal for 250 μs and then has an interface interval in which the current intensity is 0 (zero) for 5 μs. The pulse signal generator may be configured to generate the first current pulse signal for 250 μs.

In addition, the overall shape of the current pulse generated by the first current pulse signal generator and the second current pulse signal generator is 'positive → 0 → negative → 0 → negative → 0 → positive → 0 → positive → 0. It can be configured in the form of '..'.

In this case, one cycle of current pulses generated by the first current pulse signal generator and the second current pulse signal generator may have a frequency of 2 Hz.

In this case, the current pulses respectively generated by the first current pulse signal generator and the second current pulse signal generator may have a current intensity of 4 mA to 7 mA, respectively.

According to the present invention, an electrode patch is attached to the skin where the eyeball and the nerves around the eyeball are located, and electrical stimulation is transmitted transcutaneously, thereby inducing an increase in NGF (Nerve Growth Factor) and tear production, ultimately resulting in It has the effect of promoting the regeneration of corneal epithelial cells and nerves.

1 is a view showing a microcurrent stimulator for corneal tissue regeneration according to the present invention.
2 is a diagram schematically showing the internal system configuration of the main body of the microcurrent stimulator for corneal tissue regeneration according to the present invention.
3 is a view showing waveforms of current pulses generated by the first and second current pulse signal generators of the microcurrent stimulator for corneal tissue regeneration according to the present invention.
4 is a diagram showing the change in the corneal epithelial damage rate over time in the test group and the control group.
5 is a diagram showing changes in corneal epithelial damage in Visit 0 and Visit 3 in the test group and the control group.

The terms or words used in this specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventors can properly define the concept of terms in order to best explain their invention. Based on the principle, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Throughout the specification, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated. In addition, terms such as "...unit", "...unit", "module", and "device" described in the specification mean a unit that processes at least one function or operation, which is hardware or software, or a combination of hardware and software. can be implemented as

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 shows a microcurrent stimulator for corneal tissue regeneration according to the present invention, (a) shows a state where the microcurrent stimulator of the present invention is worn around the patient's eyeball, and (b) shows an electrode part shows the structure.

Referring to FIG. 1 , the microcurrent stimulator 100 for corneal tissue regeneration according to the present invention includes an electrode unit 110 and a body unit 120.

The electrode unit 110 is seated in contact with the patient's face around the eyeball and transcutaneously transmits the electrical stimulation of the microcurrent to the eyeball periphery.

As shown in (b), the electrode unit 110 as described above is composed of four x-shaped branches and transmits microcurrent electrical stimulation of the first to fourth channels transcutaneously to the periphery of the eyeball. (110a to 110d); and integrally formed with the 4-channel electrodes 110a to 110d at approximately the midpoint of the 4-channel electrodes 110a to 110d, and when the patient wears the body portion 120 around the eyeball, the body portion 120 It may include an electrode-body connection part 110e that is mechanically and electrically connected to the provided connection part 120c. For example, terminals for electrical connection with magnets may be respectively installed in the connection part 120c and the electrode-body connection part 110e. Therefore, when the patient wears the body part 120 around the eyeball in a state where the electrode part 110 is first attached around the eyeball, the magnet installed in the electrode-body connection part 110e of the electrode part 110 and Due to the interaction (attractive force) between the magnets installed in the connection part 120c of the body part 120, the electrode-body connection part 110e sticks to the connection part 120c (that is, is mechanically connected) (FIG. 1 (refer to the middle part of (a)), at the same time, the terminals respectively provided in the electrode-body connecting portion 110e and the connecting portion 120c come into contact with each other (ie, are electrically connected).

Here, also, preferably, the body contact portion 110f made of a special material is provided on the 4-channel electrodes 110a to 110d to improve contact with the skin and to allow electrical stimulation to be smoothly transmitted to the periphery of the eyeball transcutaneously. Each can be provided.

The main body part 120 is worn around the patient's eyeball, and is mechanically and electrically connected to the electrode part 110 so that the electrode part 110 transcutaneously transmits electric stimulation of a microcurrent to the eyeball. A signal is provided to the electrode part 110 .

The body portion 120 as described above includes a goggle-type housing 120h; As shown in FIG. 2, a first current pulse signal generator 121 installed inside the housing 120h and generating a first current pulse signal; a second current pulse signal generator 122 installed inside the housing 120h and generating a second current pulse signal; It is installed at a predetermined portion of the housing 120h (eg, one side of the upper end of the housing), and increases or decreases the intensity of the current pulse signal generated by the first and second current pulse signal generators 121 and 122. an up/down button unit 123 for doing so; a communication unit 124 communicating with an external electronic device or network system; The first and second pulse signal generating units 121 and 122, the up/down button unit 123 and the communication unit 124 respectively control state checks and operations, and the electrode unit 110 controls the microcurrent The first and second current pulse signal generating units 121 and 122 respectively generate control command signals for generating first and second current pulse signals for percutaneously transmitting electrical stimulation to the periphery of the eyeball. a control unit 125 that transmits to the second current pulse signal generators 121 and 122, respectively; and a power supply unit 126 supplying power necessary for driving the first and second current pulse signal generators 121 and 122, the up/down button unit 123, the communication unit 124, and the control unit 125, respectively. ). Here, the first and second current pulse signal generators 121 and 122 may generate the current pulse signal as a pulse width modulation (PWM) signal in the form of a square wave when generating the current pulse signal, respectively. In addition, the communication unit 124 may be configured as a wireless communication modem capable of wireless communication with a smartphone or computer. In addition, the controller 125 may be composed of a microprocessor, a microcontroller, and the like. In addition, the power supply unit 126 may be composed of a rechargeable battery.

Here, the first current pulse signal generated by the first current pulse signal generator 121 is a positive (+) current pulse signal, and the first current pulse signal generated by the second current pulse signal generator 122 2 The current pulse signal may be composed of a negative (-) current pulse signal.

In addition, the first current pulse signal generated by the first current pulse signal generating unit 121 is transmitted to the first and second channel electrodes 110a among the first to fourth 4-channel electrodes 110a to 110d ( 110b) and generated by the second current pulse signal generator 122 may be configured to be supplied to the third and fourth channel electrodes 110c and 110d.

In addition, the first current pulse signal generator 121 is configured to generate a first current pulse signal for 250 μs, and the second current pulse signal generator 122 generates a second current pulse signal for 250 μs. can be configured to

At this time, as shown in FIG. 3, the first current pulse signal generator 121 generates the first current pulse signal for 250 μs and then has an interface interval in which the current intensity is 0 (zero) for 5 μs. After the second current pulse signal generation unit 122 generates the second current pulse signal for 250 μs, or after the second current pulse signal generation unit 122 generates the second current pulse signal for 250 μs, the current The first current pulse signal generating unit 121 may be configured to generate the first current pulse signal for 250 μs after having an interface interval in which the intensity of is 0 (zero) for 5 μs.

In addition, the overall shape of the current pulse generated by the first current pulse signal generator 121 and the second current pulse signal generator 122 is 'positive → 0 → negative → 0 → negative → 0 → positive → It can be configured in the form of 0 → amount → 0...'.

In this case, one cycle of current pulses generated by the first current pulse signal generator 121 and the second current pulse signal generator 122 may have a frequency of 2 Hz.

At this time, the current pulses respectively generated by the first current pulse signal generator 121 and the second current pulse signal generator 122 may have a current intensity of 4 mA to 7 mA, respectively.

Hereinafter, the operation or operation of the microcurrent stimulator for corneal tissue regeneration according to the present invention having the above configuration will be briefly described.

After first attaching the electrode part 110 to the skin where the eyeball and the periocular nerve of the patient with ocular surface disease where damage to the corneal epithelial tissue continues, the body part 120 in the form of goggles is worn around the eyeball. Then, as described above, the interaction (attractive force) between the magnet installed in the electrode-body connection part 110e of the electrode part 110 and the magnet installed in the connection part 120c of the body part 120 As a result, the electrode-body connection part 110e and the connection part 120c stick to each other (that is, are mechanically connected), and at the same time, the terminals provided on the electrode-body connection part 110e and the connection part 120c are also in contact with each other. (i.e. electrically connected). In this state, the first and second current pulse signals are generated by the first and second current pulse signal generators 121 and 122 of the body part 120, respectively, and the first to fourth current pulse signals of the electrode part 110 are generated. is supplied to the 4-channel electrodes 110a to 110d, and the resulting electrical stimulation is transcutaneously transmitted to the eyeball and peripheral nerves. The current delivered to the ocular and peripheral nerves induces an increase in NGF (Nerve Growth Factor), and the increase in NGF accelerates the regeneration of the corneal nerve. In addition, electrical stimulation is applied to the tertiary nerve located around the eyeball to affect the afferent nerve to induce tear production. After all, as described above, electrical stimulation promotes the regeneration of corneal epithelial cells and nerves, leading to recovery of ocular surface diseases.

Meanwhile, FIG. 4 is a diagram showing the change in corneal epithelial damage rate over time in the test group and the control group, and FIG. 5 is a diagram showing the change in corneal epithelial damage in Visit 0 and Visit 3 in the test group and the control group.

4 and 5, the corneal epithelial damage rate of the initial (visit 0) test group was 0.373±0.121, the control group was 0.281±0.235, and the corneal epithelial damage rate at the end of the clinical trial (visit 3) was 0.044 of the test group. ± 0.067 and control group 0.352 ± 0.320, but there was no statistical difference (p = 0.157). At the time of visit 3, the test group showed a 10% change in the extent of corneal epithelial damage compared to visit 0, and the control group showed a change of 132%, which was a statistically significant difference (p = 0.034).

As described above, the microcurrent stimulator for corneal tissue regeneration according to the present invention attaches an electrode patch to the skin where the eyeball and the nerves around the eyeball are located, and transmits electrical stimulation transcutaneously, thereby nerve growth factor (NGF; Nerve Growth Factor) increase and tear production are induced, ultimately promoting the regeneration of corneal epithelial cells and nerves.

Although the present invention has been described in detail through preferred embodiments, the present invention is not limited thereto, and various changes and applications can be made without departing from the technical spirit of the present invention. self-explanatory for technicians Therefore, the true scope of protection of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100: (Invention) Microcurrent stimulator for corneal tissue regeneration
110: electrode units 110a to 110d: 4-channel electrodes
110e: electrode-body connection part 110f: body contact part
120: body part 120h: housing
121: first pulse signal generator 122: second pulse signal generator
123: up/down button unit 124: communication unit
125: control unit 126: power supply unit

Claims (10)

An electrode unit that is seated in contact with the patient's face around the eyeball and transfers electrical stimulation of microcurrent to the eyeball periphery transcutaneously; and
A cornea including a main body that is worn around the eyeball of a patient and is mechanically and electrically connected to the electrode unit to provide a current pulse signal to the electrode unit so that the electrode unit percutaneously transmits electrical stimulation of a microcurrent to the eyeball periphery. Microcurrent stimulation device for tissue regeneration.
According to claim 1,
the electrode part,
a 4-channel electrode composed of four x-shaped branches and transcutaneously transmitting microcurrent electrical stimulation of first to fourth channels to the periphery of the eyeball; and
Including an electrode-body connection part integrally formed with a 4-channel electrode at about the middle of the 4-channel electrode and mechanically and electrically connected to the connection part provided in the main body part when the patient wears the main body part around the eyeball A microcurrent stimulator for regenerating corneal tissue.
According to claim 1,
The body part,
a housing in the form of goggles;
a first current pulse signal generating unit installed inside the housing and generating a first current pulse signal;
a second current pulse signal generating unit installed inside the housing and generating a second current pulse signal;
an up/down button unit installed on a predetermined portion of the housing and configured to increase or decrease the strength of the current pulse signal generated by the first and second current pulse signal generators;
a communication unit that communicates with an external electronic device or network system;
The first and second pulse signal generating units, the up/down button unit, and the communication unit respectively control state checks and operations, and allow the electrode unit to transcutaneously transmit electric stimulation of a microcurrent to the eyeball periphery. a controller configured to send control command signals to the first and second current pulse signal generators, respectively, to generate current pulse signals to the first and second current pulse signal generators; and
A microcurrent stimulator for corneal tissue regeneration comprising a power supply unit for supplying power required for driving the first and second current pulse signal generators, the up/down button unit, the communication unit, and the control unit, respectively.
According to claim 3,
The first current pulse signal generated by the first current pulse signal generator is a positive (+) current pulse signal, and the second current pulse signal generated by the second current pulse signal generator is negative (-). A microcurrent stimulator for corneal tissue regeneration composed of a current pulse signal of
According to claim 3,
The first current pulse signal generated by the first current pulse signal generator is supplied to the first and second channel electrodes among the first to fourth 4-channel electrodes, and is supplied by the second current pulse signal generator. A microcurrent stimulator for corneal tissue regeneration configured to supply the generated second current pulse signal to the third and fourth channel electrodes.
According to claim 3,
The first current pulse signal generator is configured to generate a first current pulse signal for 250 μs, and the second current pulse signal generator is configured to generate a second current pulse signal for 250 μs. Microcurrent stimulation for corneal tissue regeneration Device.
According to claim 6,
After the first current pulse signal generation unit generates the first current pulse signal for 250 μs and then has an interface interval in which the current intensity is 0 (zero) for 5 μs, the second current pulse signal generation unit generates the second current pulse signal For 250 μs, or after the second current pulse signal generation unit generates the second current pulse signal for 250 μs and then has an interface interval in which the current intensity is 0 (zero) for 5 μs, the first current pulse signal A microcurrent stimulator for corneal tissue regeneration configured to generate a first current pulse signal for 250 μs.
According to claim 3,
The overall shape of the current pulse generated by the first current pulse signal generator and the second current pulse signal generator is 'positive → 0 → negative → 0 → negative → 0 → positive → 0 → positive → 0... A microcurrent stimulator for corneal tissue regeneration configured in the form of '.
According to claim 8,
Microcurrent stimulator for corneal tissue regeneration, wherein one cycle of current pulses generated by the first current pulse signal generator and the second current pulse signal generator has a frequency of 2Hz.
According to claim 8,
The current pulses generated by the first current pulse signal generator and the second current pulse signal generator, respectively, have a current intensity of 4 mA to 7 mA, respectively. Microcurrent stimulator for corneal tissue regeneration.