KR101580036B1 - Laser electrical fusion treating apparatus - Google Patents

Abstract

The laser electromagnetic fusion therapy apparatus of the present invention is characterized in that the stimulation of the medical stimulation type invasive laser stimulator and the stimulation of the electromagnetic stimulator is performed through a hollow needle tip according to the parameters set by the user (the practitioner) The infected laser stimulator for medical treatment and the electromagnetic stimulator are embodied in one single device.
Particularly, in the apparatus of the present invention, by timely controlling the laser (optical) stimulation and the electromagnetic stimulation using a timer, it is possible to maximize the therapeutic effect by using various stimuli for pain treatment.
In addition, it is possible to ensure the reproducibility of the intensity and the shape of the signal, and the invasive laser stimulator and the electromagnetic stimulator for medical treatment are implemented in one single device, thereby making it easy to carry and manipulate.

Description

[0001] The present invention relates to a laser optical fusion treatment apparatus,

In particular, the present invention relates to a laser electromagnetic fusion therapy apparatus, and more particularly, to a laser electromagnetic fusion therapy apparatus, in which stimulation of an invasive laser stimulator for medical treatment and stimulation of an electromagnetic stimulator is performed through a hollow needle tip according to a parameter set by a user The present invention relates to a laser electromagnetic fusion therapy apparatus which is delivered to a site (e.g., a diseased part or menstrual blood), and the invasive type laser stimulator for medical treatment and the electromagnetic stimulator are implemented in one single device, thereby maximizing the therapeutic effect.

Ultrasound therapy devices, ultrasonic therapy devices, low-power laser therapy devices, and magnetic resonance imaging devices are widely used as physical therapy devices for relieving fatigue, relieving pain such as neuralgia, myalgia, and arthritis by stimulating pain parts of the body such as abdomen, joints, And a vibration therapy apparatus by tremor.

 In addition, it includes an osteoblast growth promoting airway which causes the bone to grow quickly by applying electromagnetic waves to the bone when a bone fracture due to a traffic accident occurs.

However, in the related art, there has been no technology that can simultaneously control electromagnetic stimulation and optical stimulation using a timer, and conventional electromagnetic stimulators have a problem in that the intensity of a signal is not constant. Because of these problems, the same stimulus was not given to the recipient, so it was difficult to treat correctly. In addition, the conventional electromagnetic stimulator outputs only a pulse waveform, so that it can not output various stimulation patterns.

Korean Patent Publication No. 10-2013-0011681 (published on January 30, 2013)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art, and an object of the present invention is to provide a medical stimulation type laser stimulator and a magnetic stimulator, (For example, the affected part or the menstrual blood) through the single hollow needle tip, and the medical laser ablation type stimulator for stimulation and the electromagnetic stimulator are implemented in one single device to maximize the therapeutic effect And to provide a laser electromagnetic fusion therapy apparatus having the same.

The technical requirements of the inventive device are as follows.

It is required to develop systematic treatment and treatment technology through the upgrading and scientificization of oriental medicine treatment. Laser needles can maximize the effect of phototherapy as well as the therapeutic effects of traditional acupuncture, and can be used for biomedical stimulation Semiconductor lasers include InGaAlP 633-700nm, GaAlAs 780-890nm GaAs 904nm, and also HeNe lasers. In addition, it has been reported that the use of a laser having an infrared wavelength of 800 nm or more is effective for the pain relief treatment, and in particular, GaAs is used for the treatment of muscle, tendon and joint pain HeNe lasers and InGaAlP lasers are used for skin damage and mucous membrane wounds, skin and mucous membranes, and for the treatment of inflammation, joint dysfunction and deep areas. GaAlAs are used for scarring and small joint rheumatoid arthritis, Pain, and neuralgia. Recent researches on laser therapy for these therapies have been actively carried out, and their application to oriental medicine has been studied.

Conventionally, acupuncture using 630 ~ 670 nm laser for hyperthermia has been tried, but research on acupuncture using laser of wavelength has been hardly done.

In the present invention, the optical stimulation by the semiconductor laser and the electrical stimulation by the electric stimulation are performed at the same time, and this is expected to contribute to the development of the herbal medicine treatment technology in a new field.

Core competitors may include areas such as hands and feet used in traditional oriental medicine, but in the case of laser, it is possible to develop various treatment techniques such as energy, wavelength, pulse and continuous irradiation, Because the treatment technique can be developed, it is considered that the acupuncture using laser can be precisely distinguished by pathology.

Electrodeposition is used in the treatment of pain and body fat decomposition in oriental medicine, and many researches have been carried out and used in combination with acupuncture of Oriental medicine.

The device of the present invention is expected to be developed in the field of oriental medical treatment technology as a new-concept laser-electric fusion acupuncture treatment device that simultaneously controls a laser needle and an electric needle according to a stimulation pattern.

The present invention is a fusion type therapeutic apparatus capable of irradiating a needle having a diameter of 300 탆, which is similar to a needle, with a laser and inserting a needle as compared to a conventional laser needle.

According to an aspect of the present invention, there is provided a laser-induced electromagnetic interference fusion therapy apparatus comprising: And the medical therapeutic ablative laser stimulator and the electromagnetic stimulator are implemented in one single device.

Wherein the medical treatment type invasive laser stimulator is configured to set a laser output parameter (condition) required for the subject person, and outputs a content of the procedure including the parameter; A power supply unit for supplying power to each component; A laser diode module that oscillates a laser of a predetermined wavelength at an arbitrary interval according to a laser output parameter set in the touch display device when power is supplied from the power supply unit; And an optical fiber for transmitting the laser oscillated from the laser diode module to the hollow needle which is placed on the treatment site of the client.

The semiconductor laser used in the medical treatment type invasive laser stimulator is characterized by outputting (oscillating) a beam of InGaAlP 633 to 700 nm, GaAlAs 780 to 890 nm, GaAs 904 nm, and InGaAs 1064 nm wavelength.

The laser output parameters required for the subject can include laser stimulus intensity, laser output wavelength, procedure time, procedure interval, and the like.

The laser diode module includes a laser diode driving unit (laser constant current supply unit) for generating a laser beam driving signal required for laser treatment, a wavelength band controllable by a laser beam driving signal generated by the laser diode driving unit, And / or a laser diode for selectively generating a laser beam of a kind.

The electromagnetic stimulator includes: a power supply unit for supplying power to each component; A touch display device configured to set an electromagnetic output parameter (condition) necessary for the subject person and outputting the contents of the procedure including these parameters; An electromagnetic stimulation generator for generating electromagnetic stimulation of a predetermined type according to an electromagnetic output parameter set in the touch display device when power is supplied from the power supply; And an electromagnetic stimulation delivery unit for delivering the electromagnetic stimulation generated by the electromagnetic stimulation unit to the hollow needle which is placed on the treatment site of the client.

The output waveform of the electromagnetic stimulator includes a pulse wave, a sine wave, a triangle wave, a square wave, and a fusion wave of a triangle wave and a square wave.

The laser output parameters required for the subject instructor include electromagnetic stimulus intensity, electromagnetic output waveform, procedure time, procedure interval, and the like.

As an example of the electromagnetic stimulator, a stimulating electrode for supplying a constant micro current to the hollow needle; A frequency voltage generator for generating a voltage according to a frequency; A voltage-to-current converter for converting a voltage generated by the frequency voltage generator into a current; And a magnetic pole electrode driver for driving the magnetic pole electrode according to an output of the voltage-current converter.

The following effects can be obtained by providing the above-described laser electromagnetic fusion therapy apparatus.

That is, in the device of the present invention, by timely controlling optical stimulation and electromagnetic stimulation using a timer, it is possible to maximize the therapeutic effect by using various stimuli for pain treatment.

In addition, it is possible to ensure the reproducibility of the intensity and the shape of the signal, and the invasive laser stimulator and the electromagnetic stimulator for medical treatment are implemented in one single device, thereby facilitating portability and operation.

1 is an overall system diagram of a laser electromagnetic fusion therapy apparatus according to an embodiment of the present invention.
FIG. 2 is a view showing the overall system diagram of the laser-induced electromagnetic interference fusion therapy apparatus of FIG. 1 in more detail.
3 is a view illustrating a stimulus transmitting portion and hollow needle of a laser stimulator according to an embodiment of the present invention.
4 is a detailed view of an electromagnetic stimulator according to an embodiment of the present invention.
FIGS. 5 to 7 are a front view, a rear view, and a plan view of a laser-induced electromagnetic interference fusion therapy apparatus according to an embodiment of the present invention.
8 is an output waveform diagram of an electromagnetic stimulator according to an embodiment of the present invention.
9 is an electric output waveform diagram of the conventional electric needle output and the laser electromagnetic fusion therapy apparatus of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. In the following detailed description of the preferred embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The same or similar reference numerals are used throughout the drawings for portions having similar functions and functions.

Also, to "include" an element means that it may include other elements, rather than excluding other elements, unless specifically stated otherwise.

1 is an overall system diagram of a laser electromagnetic fusion therapy apparatus according to an embodiment of the present invention.

The laser-magnetic fusion therapy apparatus of the present invention is characterized in that the stimulation of an invasive laser stimulator for medical treatment and the stimulation of an electromagnetic stimulator is performed through a hollow needle tip according to a parameter set by a user (a practitioner) (E. G., A lesion or menstrual blood) 25.

1, the laser-based electromagnetic fusion therapy apparatus of the present invention includes a power supply unit 10, a touch pad (touch display device) 21, a system control board (system control unit) 22, (Laser constant current supply unit) 23, a laser diode 24, an electrostatic precipitator output control unit 26, and an electrostatic precipitator 27.

The power supply unit 10 is connected to each component (touch pad, system control board, laser diode driver, laser diode 24, electromechanical output regulator 26, electret output unit 27, etc.) Supply power.

The touch pad (touch display device) 21 is configured to set the laser output parameters (conditions) (e.g., laser stimulus intensity, laser output wavelength, procedure time, procedure interval, etc.) necessary for the subject person, Print the contents.

In addition, the touch pad (touch display device) 21 is configured to set electromagnetic output parameters (conditions) (e.g., electromagnetic stimulus intensity, electromagnetic output waveform, procedure time, procedure interval, etc.) Outputs the entire contents of the procedure.

The laser diode driving part (laser constant current supplying part) 23 generates a laser beam driving signal necessary for laser treatment.

The laser diode 24 is controlled in operation by a laser beam driving signal generated in the laser diode driving unit to selectively generate a laser beam of a wavelength band and / or a type that can be manipulated in the human body. This beam is transmitted to the treatment site (e.g., the affected part or menstrual blood) 25 of the patient. The laser diode 24 is configured such that the laser is output from the laser diode 24 in accordance with the amount of current supplied from the laser constant current supply unit 23. [

The laser diode 24 outputs (oscillates) a beam of InGaAlP 633 to 700 nm, GaAlAs 780 to 890 nm, GaAs 904 nm, and InGaAs 1064 nm as an example.

Also, the laser diode 24 may emit red, green, and infrared rays. Here, the red laser beam may include, for example, 635 nm, 650 nm, 654 nm, 655 nm, 658 nm, 660 nm, 670 nm and 690 nm wavelength, and the green laser beam has a wavelength of 532 nm belonging to about 530 nm to about 555 nm as an example, and the laser beam of the infrared series As an example, has a wavelength of 808 nm belonging to 800 nm to 890 nm.

The electroacupuncture regulator 26 generates an electrical stimulation drive signal necessary for electrical therapy.

The electrospin output section 27 outputs a predetermined electric stimulus in accordance with the electric stimulation drive signal generated by the electrospin output control section 26. This electric stimulus is transmitted to the treatment site (e.g., the affected part or menstrual blood) 25 of the subject. The electrostatic precipitator 27 is configured such that a voltage is output from the electrostatic precipitator 27 in accordance with the voltage supplied from the electrostatic precipitator 26.

The system control board (system control unit) 22 receives the output of the touch pad 21 and transmits control signals to the laser constant current supply unit 23 and the electrostatic precipitator control unit 26. This control signal includes a signal for controlling the output of the laser diode 24 and the output of the electric dipstick.

The laser constant current supply unit 23 turns on the laser diode 24 by converting the voltage supplied from the power supply unit 10 to a constant current and supplying the constant current to the laser diode 24. [

The laser diode 24 of the present invention may further include a first lens unit, a light attenuating filter unit, and a second lens unit in order to transmit the laser generated by the laser diode 24 of the present invention to the treatment site.

The first lens unit is, for example, a collimating lens unit. The first lens unit is disposed on the optical path of the laser beam generated by the laser diode 24 so as to adjust the laser beam to be coherence parallel light without spreading.

The light attenuating filter unit constantly adjusts the amount of coherent parallel light emitted through the first lens unit.

The second lens unit is, for example, an objective lens unit, and focuses the laser beam emitted through the light attenuating filter unit onto the optical fiber.

1, the system control board 22, the electroacupuncture regulating unit 26, and the electret output unit 27 can be embodied in a single printed circuit board (PCB).

In addition, the laser-based electromagnetic fusion needle system of the present invention is controlled by the system control board 22 including a DSP (Digital Signal Processor), and is used as a laser source in a laser acupuncture treatment apparatus A semiconductor laser can be controlled in a CW / sine wave mode, a frequency can be adjusted (for example, 1 to 200 Hz) in a sine mode by a control board 22 of a system including a processor chip, 22) displays the laser output on the output screen (LCD) in real time, and the frequency in Sine mode. In addition, a timer function is added to the processor chip to control the irradiation time of the laser output and the electromagnetic output, and the laser source of the laser acupuncture treatment device is 650 nm, 830 nm, 905 nm and 1064 nm wavelength visible and infrared semiconductor lasers are used. The signal received from the processor chip (DSP) enables waveform shape, size and frequency drive control, and each module has four outputs. It is configured to be able to output up to 20mW.

Also, a red laser (650 nm) guide beam is added to the module of wavelengths of 830 nm, 905 nm and 1064 nm so that laser light can be confirmed.

In addition, the laser-magnetic fusion needle system of the present invention is controlled in all operations through a system control board 22 including a processor chip, and the output from the electromagnetic therapy apparatus is converted into a microwave / triangular wave / square wave / sine wave / fusion wave mode And the electromagnetic output can be controlled by the control board 22 of the system including the processor chip so that the frequency can be adjusted up to 200 Hz and the size adjustment can be performed in the range of 0 to 5 V It can be adjusted in 0.1V increments. In addition, the output voltage, frequency, and waveform type are displayed on the LCD window in real time by the control board 22 of the present system, and a timer function is added to the laser electromagnetic fusion therapy to investigate the laser output and the electromagnetic output Time is controlled.

In addition, the system control board (control unit) 22 of the laser-based electromagnetic fusion therapy apparatus of the present invention controls the selective operation in the continuous mode and the pulse mode in the laser oscillation, generates a sine wave required for driving the pulse laser, When acupuncture is driven, small wave / triangle wave / square wave / sine wave / fusion wave are generated.

The TMS320F28335 is used as a DSP (Digital Signal Processor) chip for controlling all of the functions of the system control board (control unit) 22 of the laser- ), The digital signal that is commanded from the DSP chip is converted into an analog signal to control all input and output signals. Signals output through the system control board (controller) 22 are used as inputs to the laser diode driver and the electrical output part, respectively.

FIG. 2 is a view showing the overall system diagram of the laser-induced electromagnetic interference fusion therapy apparatus of FIG. 1 in more detail.

2, the laser electromagnetic fusion therapy apparatus of the present invention includes an output parameter setting unit 31, a system control unit 32, a laser stimulating unit 33, a laser stimulating unit 34, Electric) stimulation generating unit 36, an electromagnetic (electric) stimulation transmitting unit 37, and a hollow needle 35.

The output parameter setting unit 31 sets a laser stimulus (output) and an electric stimulus (output) parameter required by the practitioner for the subject. The output parameter setting unit 31 corresponds to the touch pad 21 of FIG.

Examples of the laser stimulus (output) parameters include laser stimulus intensity, laser output wavelength, procedure time, and procedure interval.

Examples of electric stimulation (output) parameters include electromagnetic stimulus intensity, electromagnetic output waveform, procedure time, procedure interval, and the like.

The system control unit 32 corresponds to the system control board 22 shown in FIG. 1 and receives the output of the touch pad 21 to generate a predetermined control signal and supplies it to the laser stimulation generator 33 and the electromagnetic And transmits it to the stimulation generating unit 36.

The laser stimulating portion 33 corresponds to the laser constant current supplying portion 23 and the laser diode 24 shown in Fig. 1 and corresponds to the laser stimulating (output) parameter in accordance with the control signal outputted from the system controlling portion 32 And outputs the corresponding laser stimulating signal.

The electromagnet (electric) stimulus generator 36 corresponds to the electromagnetism output control unit 26 and the electrometric output unit 27 shown in FIG. 1 as an example. The electromagnet And outputs an electric stimulation signal corresponding to the electric stimulation (output) parameter.

The laser stimulation transmission unit 34 transmits the laser stimulus output from the laser stimulation generation unit 33 to the hollow needle 35. The laser stimulation transmission unit 34 includes, for example, an optical fiber.

The electromagnetic stimulation transmission unit 37 transmits an electric stimulus output from the electromagnetic stimulation generator 36 to the hollow needle 35. The electromagnetic stimulation transmission unit 37 includes an electric wire or the like. Specifically, the electric stimulus is transmitted to the hollow needle 35 through a conductor in the form of a clamp connected to the electric wire.

The hollow needle 35 is placed on the treated region (e.g., a diseased part or the menstrual blood) 25 of the subject and is irradiated with the laser stimulus transmitted through the laser stimulation transmission portion 34 and the electromagnetic And an electromagnetic (electrical) stimulus to the treatment part 25 of the patient.

FIG. 3 is a view showing a stimulus transmitting portion 34 and a hollow needle 35 of a laser stimulator according to an embodiment of the present invention.

The stimulation transmitting portion 34 of the laser stimulator comprises a connecting portion 51 and a laser needle 52, as shown in Fig.

The connection portion 51 is coupled to the laser constant current supply portion 23 of FIG. 1 or the laser stimulating portion 33 of FIG. 2, and receives the laser beam to transmit the laser to the optical fiber.

The laser needle 52 is connected to an output end of the connection part 51 and directly irradiates the skin with the laser beam output from the connection part 51 in an invasive manner. In particular, in this case, the laser needle 52 may be composed of the core needle 53 and the needle tube 35a. Here, the laser needle 52 corresponds to the hollow needle 35 shown in Fig.

Here, the core needle 53 can be formed by exposing the core end of the optical fiber surrounded by the cladding. The needle tube 35a is made of a tubular hollow body made of any one of a resin-based material or a metal such as stainless steel so that the core needle 53 can be inserted and guided into the inside of the tube, The distal end portion 35b may be formed with the core needle 53 so as to be inserted directly into the skin. In addition, such a cap can be configured to be variable in thickness and selectively used as needed.

4 is a detailed view of an electromagnetic (electrical) stimulator according to one embodiment of the present invention.

Referring to FIG. 4, the electromagnetic stimulator of the present invention includes a system controller 32, a key input unit 41, a memory unit 42, a display unit 43, a frequency voltage generator 44, a voltage- (45), a stimulation electrode driver (46), and a stimulation electrode (47).

The key input unit 41 and the display unit 43 correspond to the touch pad (touch display device) 21 of FIG. 1, and a detailed description thereof will be omitted.

The memory unit 42 stores programs necessary for operating the laser-based electromagnetic fusion therapy apparatus of the present invention, laser and electric stimulation (output) parameters set by the practitioner, and the like.

The frequency voltage generator 44 generates a voltage of various frequencies and outputs the voltage to the voltage-current converter 45. The frequency voltage generator 44 is driven according to a frequency voltage control signal generated in the system control unit 32 according to a signal set by the key input unit 41.

The voltage-to-current converter 45 converts the voltage generated by the frequency voltage generator 44 into a current.

The stimulating electrode driving unit 46 outputs a constant current for driving the stimulating electrode 47 from the output from the voltage-current converter 45. The stimulation electrode driver 46 outputs a constant current irrespective of the load, which can be realized by using the characteristic and / or the negative feedback effect of the operational amplifier, and the degree to which the voltage is converted into the current And a current controller (not shown) for controlling the current to be outputted to a certain extent.

The current supplied from the stimulation electrode driver 46 is an AC current. The AC constant current is applied to the skin through the stimulating electrode 47 by the stimulating electrode driving part 46.

The stimulation electrode 47 is for stimulating the patient by supplying a constant micro current to the treatment site of the skin (for example, a diseased part or a menstrual blood). The stimulation electrode 47 is used for stimulating the constant current output from the stimulation electrode driver 46, Menstrual blood, etc.). That is, the stimulating electrode 47 applies the AC constant current output from the stimulating electrode driving part 46 to the skin through the hollow needle 35, at this time, the electric current is applied in a dipole manner, And one of the electrodes is used in common with the ground of the power source.

The output waveform of the electromagnetic (electric) stimulator is, for example, a pulse wave, a sine wave, a triangle wave, a square wave, and a fusion wave of a triangle wave and a square wave.

FIGS. 5 to 7 are a front view, a rear view, and a plan view of a laser-induced electromagnetic interference fusion therapy apparatus according to an embodiment of the present invention.

Referring to FIG. 5, a front surface of a laser-induced electromagnetic interference (EMI) fusion therapy apparatus according to the present invention will be described. Reference numeral 1 denotes a main body, which includes a power supply unit 10, (2) is a laser output unit which outputs a laser beam to be transmitted to an optical fiber, (3) a low frequency stimulator output unit which outputs a low frequency of a selected waveform, and Reference numeral 4 denotes a key switch, which is a safety device that permits only authorized persons to use the device by using a unique key, and reference numeral 5 denotes an emergency switch, which is an emergency switch, It is a switch to stop the operation of the device when it occurs.

6, reference numeral 6 denotes a power cord, which is connected to an AC power source (for example, 220 V), and reference numeral 7 denotes a power source cord (Fan), which dissipates the heat generated from the inside to outside to protect the internal electronic components. Reference numeral 8 denotes an interlock, which is used to temporarily stop the apparatus when the door is opened while the laser is being radiated. It is designed safety device.

Referring to Fig. 7, the plane (upper surface) of the laser induced electromagnetic interference fusion therapy apparatus of the present invention will be described. Reference numeral 9 denotes an apparatus for executing, controlling and setting a program as a touch monitor.

The operation principle of the apparatus of the present invention will be described. A laser having a wavelength of 650 nm, 830 nm, 905 nm, or 1064 nm is emitted from a laser diode module using a power supply unit mounted inside the main body. To set the laser output parameters and low frequency output parameters and to control the output via the START switch. Then, the oscillated laser output is transmitted through the optical fiber beam transmission device (fiber optic fiber), and the output of the low frequency stimulator is outputted through the output stage to the clip in the form of a clamp, and the stimulus is transmitted along the hollow needle 35 .

8 is an output waveform diagram of an electromagnetic (electric) stimulator according to an embodiment of the present invention.

The output waveform of an electromagnetic (electric) stimulator of the present invention is limited to a square wave, a sine wave, and the like. However, the output waveform of the electromagnetic (electric) , A sine wave, a triangle wave, and a fusion wave of a triangle wave and a square wave.

9 shows the output of the conventional electric needle and the electric output waveform of the laser electromagnetic fusion therapy apparatus of the present invention.

When an electric needle is used, a needle is inserted into a human body, and an electric dip probe is connected to the tip of the needle. The resistance at this time is regarded as about 500 ohms. Conventional electrometry shows that when the 500 ohm resistor is connected, the output voltage drops and the output waveform becomes unstable, but the output of the electromagnetic part of this system (laser electromagnetic fusion needle) remains constant and maintains a stable pulse waveform.

Next, effects of the present invention having the above-described configuration will be described.

1) Effects of von Frey filament on cold allodynia. - To observe the effect of laser on the laser beam and the propagation effect of the probe, (1064 nm) saliva on the physical allodynia of the neuropathic pain induced by tibial and sural nerve transection were compared in the normal group and the control group, , 3 times and 6 times, respectively. In the comparison between control and experimental groups, the tendency of increasing in the first, second and sixth times was higher than that of the control group. , And the tendency of increase in the 4th to 6th cases of the group showed a tendency to increase.

2) Acetone-induced physical allodynia - To observe the effect of laser on the laser beam and the ocular effect of the ocular wave, we used a probe + laser (658nm), a probe + laser (830nm), a probe + laser (904nm) As a result of observing the effects of elbow + laser (1064 nm) saliva on cold allodynia in neuropathic pain induced by tibial & sural nerve transection, the control group showed 2, 3, 5, and 6, respectively. In comparison between control and experimental group, the number of elderly + laser needle 658 group was significantly decreased at 6th, and that of elbow + laser needle 830 group was decreased There was no statistically significant difference between the two groups. There was no significant difference between group 1 and group 2, 3 and 6, I could.

3) Significance - Electrode was applied at 1.7V ~ 2.0V, 20Hz, which is the stimulation condition of this instrument, and 20mW 20Hz is added for each wavelength of 658nm, 830nm, 904nm and 1064nm And to investigate the effect of pain on intersection stimulation.

In the present study, it was suggested that the combination of an acupuncture needle and a laser needle would be more effective in suppressing pain in the model of this study. In the laser wavelength range of 658 nm, 830 nm, 904 nm, and 1064 nm And it was found that there were significant results for each band. Especially, it was found that the long band of 904 nm and 1064 nm is more effective.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10: Power supply
21: Touchpad
22: System control board
23: laser constant current supply part
24: Laser diode
25: Treatment site
26: Electroacupuncture regulator
27: Electrochemical precipitator
31: Output parameter setting section
32:
33: Laser stimulation generator
34: Laser stimulation transmission part
35: hollow needle
35a: bowing
35b: end
36: Electromagnetic (electric) stimulation generator
37: Electromagnetic (electric) stimulation transfer part
41:
42:
43:
44: frequency voltage generator
45: voltage-to-current converter
46: Stimulation electrode driver
47: Stimulation electrode
51: Connection
52: laser needle
53: core needle

Claims (9)

The stimulation of the medical laser ablation laser stimulator and the stimulation of the electromagnetic stimulator are transmitted to the treatment part of the recipient through one hollow needle tip according to parameters set by the operator, Wherein the stimulator is implemented in one single device. The method according to claim 1,
The infra-red laser stimulator for medical treatment,
A touch display device configured to set a laser output parameter necessary for the subject person and outputting the entire contents of the procedure including these parameters;
A power supply unit for supplying power to each component;
A laser diode module for emitting a laser of a predetermined wavelength according to a laser output parameter set in the touch display device when power is supplied from the power supply unit; And
And an optical fiber for transmitting the laser oscillated from the laser diode module to the hollow needle which is placed on the treatment site of the client. 3. The method of claim 2,
Wherein the semiconductor laser used in the medical treatment type invasive laser stimulator outputs a beam of InGaAlP 633 to 700 nm, GaAlAs 780 to 890 nm, GaAs 904 nm, and InGaAs 1064 nm wavelength. 3. The method of claim 2,
Wherein the laser output parameters required for the subject include a laser stimulus intensity, a laser output wavelength, a treatment time, and a treatment interval. 3. The method of claim 2,
The laser diode module includes a laser diode driver for generating a laser beam driving signal required for laser treatment,
And a laser diode for selectively generating a laser beam and / or a laser beam of a wavelength band and / or a type that can be manipulated by a human body, the operation of which is controlled by a laser beam driving signal generated by the laser diode driving unit. . The method according to claim 1,
The electromagnetic stimulator includes:
A power supply unit for supplying power to each component;
A touch display device configured to set an electromagnetic output parameter required for a physician and outputting an entire contents of the procedure including these parameters;
An electromagnetic stimulation generator for generating electromagnetic stimulation of a predetermined type according to an electromagnetic output parameter set in the touch display device when power is supplied from the power supply; And
And an electromagnetic stimulation transmission unit for delivering the electromagnetic stimulation generated by the electromagnetic stimulation unit to the hollow needle which is placed on the treatment area of the client. The method according to claim 6,
Wherein the output of the electromagnetic stimulator is any one of a pulse wave, a sine wave, a triangle wave, a square wave, and a fusion wave of a triangle wave and a square wave. The method according to claim 6,
Wherein the laser output parameter required for the subject includes the electromagnetic stimulus intensity, the electromagnetic output waveform, the treatment time, and the treatment interval. The method according to claim 6,
The electromagnetic stimulator includes:
A stimulation electrode for supplying a constant micro current to the hollow needle;
A frequency voltage generator for generating a voltage according to a frequency;
A voltage-to-current converter for converting a voltage generated by the frequency voltage generator into a current; And
And a stimulation electrode driver for driving the stimulation electrode according to an output of the voltage-current converter.

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