KR102088774B1 - Cell proliferation control device - Google Patents

Abstract

A cell proliferation control device is disclosed. An ultrasonic generator 100 that generates ultrasonic waves in a wavelength band that controls cell proliferation; LED 200 that outputs light of a wavelength band that controls cell proliferation and adjusts the light output angle to the skin surface according to the position where the ultrasonic generator 100 contacts the skin; LED driver 300 for driving the LED 200; And a control unit 400 that controls the ultrasonic generator 100 and the LED driver 300 to control cell proliferation. Therefore, it is possible to output ultrasound and light in a wavelength band that controls cell proliferation, and when the probe slides, the LED light output angle changes direction, so that ultrasound and light are irradiated to the skin, and the probe is moved according to the density of the cells. The output intensity of the ultrasound and light can be adjusted, and the cell growth control device can display the travel distance of the probe to display the output intensity of the ultrasound and light.

Description

Cell proliferation control device {CELL PROLIFERATION CONTROL DEVICE}

The present invention relates to a cell proliferation control device, and more particularly, to a cell proliferation control device for controlling cell proliferation.

Light sources and ultrasound are widely used in cancer treatment and regenerative applications. In addition to using laser technology for medical treatment, their use is expanding in the treatment of skin diseases, cancer, nervous system disorders, and depression.

In particular, among imaging techniques such as X-rays, positron emission tomography, and magnetic resonance imaging, ultrasound is known as a low-cost, non-invasive imaging technique. It is still being developed for treatment.

Accordingly, various treatment techniques for applying to the treatment of cancer are under research and development, and various studies for grafting light sources and ultrasound have been conducted.

Among the medical equipment is a cancer cell therapy device. Various methods are applied to the treatment of cancer cells, but are related to a cancer cell treatment device using ultrasound and light. Cancer cell therapy devices use ultrasound and light at a specific wavelength to suppress the growth of cancer cells. As an example, the cancer cell therapy device may use 1 MHz of ultrasound and 470 nm of light. Ultrasound and light in a specific wavelength band may have an effect of inhibiting cancer cell growth. The cancer cell therapy device can suppress the growth of cancer cells by irradiating the cells with ultrasound and light. However, the conventional cancer cell therapy device has a fixed ultrasound output and light output, so that even when the cancer cell density is low, strong intensity ultrasound and light may affect normal cells.

Publication No. 10-2015-0135335, Optical and ultrasonic transducer device Publication No. 10-2010-0028150, obesity treatment device using broadband ultrasound and broadband laser light

An object of the present invention for solving the above problems is to provide a cell proliferation control device for outputting ultrasound and light in a wavelength band that controls cell proliferation.

In addition, to provide a cell proliferation control device that changes the LED light output angle when the probe slides.

In addition, it is to provide a cell proliferation control device for moving the probe according to the density of the cells.

In addition, it is to provide a cell proliferation control device for displaying the distance the probe moves.

The present invention for achieving the above object, an ultrasonic generator 100 for generating ultrasonic waves of a wavelength band that controls cell proliferation; LED 200 that outputs light of a wavelength band that controls cell proliferation and adjusts the light output angle to the skin surface according to the position where the ultrasonic generator 100 contacts the skin; LED driver 300 for driving the LED 200; And a control unit 400 that controls the ultrasonic generator 100 and the LED driver 300 to control cell proliferation.

In addition, a probe 500 that includes an ultrasonic generator 100 at the distal end and slides; And it is located on both sides of the probe 500, the direction of the LED light output according to the slide movement of the probe 500 further includes a direction changing gear 600.

In addition, the direction changing gear 600 operates to adapt the LED light output angle against the skin as the probe 500 slides back and forth.

In addition, the ultrasonic generator 100 located at the end of the probe 500; A circular frame 700 which is configured in the center of the probe 500 so that the probe 500 slides and surrounds the probe 500; A direction change gear 600 configured on both side circular frames 700 of the probe 500 to change the angle of the LED light output according to the slide movement of the probe 500; A support bar 800 located on the opposite side of the probe 500 and transmitting the front and rear slide movement of the ultrasonic generator 100 to the direction changing gear 600 fixed to the circular frame 700; And a control rod 900 that is linked to the support rod 800 around the redirection gear 600 and adjusts the light output angle of the LED 200 according to the inclination of the support rod 800.

In addition, the sensor 1000 for sensing the density of the cells; And a moving unit 1100 moving the probe 500 back and forth according to the density of the sensed cells.

In addition, the circular frame 700 includes a display unit 710 that displays the moving distance of the probe 500.

When using the cell proliferation control device according to the present invention as described above, it is possible to output ultrasound and light in a wavelength band that controls cell proliferation.

In addition, when the probe slides, the LED light output angle changes direction, so that ultrasound and light are irradiated to the skin.

In addition, according to the density of cells, the probe is moved, so that the output intensity of ultrasound and light can be adjusted.

In addition, the cell proliferation control device may display the moving distance of the probe to display the output intensity of ultrasound and light.

1 is a block diagram showing the configuration of a cell growth control device.
2 is an exemplary view showing the configuration of the probe 500.
3 is an exemplary view showing a configuration of the direction change gear 600.
4 is an exemplary view showing an embodiment of the probe 500.
5 is an exemplary view showing a configuration of a cell growth control device that moves the probe 500 according to the density of cells.
6 is an exemplary view showing a configuration of the display unit 710.
7 is an exemplary view illustrating probe movement buffering.
8 is a block diagram showing a configuration for measuring a probe movement distance.
9 is a diagram illustrating the cell proliferation inhibitory effect of cervical cancer cells.
10 is a diagram illustrating the cell proliferation inhibitory effect of glioma cancer cells.

The terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "include" or "have" are intended to indicate the presence of features, numbers, steps, actions, components, parts or combinations thereof described herein, one or more other features. It should be understood that the existence or addition possibilities of fields or numbers, steps, operations, components, parts or combinations thereof are not excluded in advance.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person skilled in the art to which the present invention pertains. Terms such as those defined in a commonly used dictionary should be interpreted as having meanings consistent with meanings in the context of related technologies, and should not be interpreted as ideal or excessively formal meanings unless explicitly defined in the present application. Does not.

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

The cell proliferation control device can output ultrasound and light in a wavelength range that controls cell proliferation. When the probe slides, the LED light output angle changes direction, so that ultrasound and light are irradiated to the skin. Depending on the density of the cells, the probe is moved, so that the output intensity of ultrasound and light can be adjusted. The cell proliferation control device may display the moving distance of the probe to display the output intensity of ultrasound and light.

1 is a block diagram showing the configuration of a cell growth control device.

The cell proliferation control device includes an ultrasonic generator 100 that generates ultrasonic waves in a wavelength band that controls cell proliferation; LED 200 that outputs light of a wavelength band that controls cell proliferation and adjusts the light output angle to the skin surface according to the position where the ultrasonic generator 100 contacts the skin; LED driver 300 for driving the LED 200; And a control unit 400 that controls the ultrasonic generator 100 and the LED driver 300 to control cell proliferation.

The ultrasonic generator 100 generates ultrasonic waves having a wavelength that controls cell proliferation. Ultrasound at specific wavelengths controls cell proliferation. In order to control cell proliferation, an ultrasonic generator 100 that generates ultrasonic waves in a specific wavelength band is used. Ultrasound is used for medical treatment purposes, and ultrasound at a specific wavelength can suppress cell proliferation. The ultrasonic generator 100 may use a frequency oscillator to generate ultrasonic waves having a specific wavelength. The frequency oscillator generates a specific frequency to drive the ultrasonic oscillator, so that the ultrasonic oscillator generates ultrasonic waves having a specific wavelength.

The LED 200 outputs light of a wavelength band that controls cell proliferation, and the light output angle is adjusted to the skin surface according to the position where the ultrasonic generator 100 contacts the skin. Light at a specific wavelength controls cell proliferation. To control cell proliferation, LEDs 200 of a specific wavelength are used. In the LED 200, the light output angle is adjusted so that light of a specific wavelength band is irradiated to the point where the ultrasound generating unit 100 outputs ultrasound to the skin. Light is used for medical treatment purposes, and light at a specific wavelength can suppress cell proliferation. The LED 200 outputs light of a specific wavelength band, and the LED driver 300 drives the LED 200. The LED driver 300 can control the light output by PWM control of the LED 200.

The control unit 400 controls the ultrasonic generator 100 and the LED driver 300 to control cell proliferation. The control unit 400 controls the ultrasonic generator 100 and the LED driver 300 to control ultrasonic generation and light output.

2 is an exemplary view showing the configuration of the probe 500.

The cell proliferation control device includes an ultrasonic generator 100 at its end and a slide moving probe 500; And it is located on both sides of the probe 500, the direction of the LED light output according to the slide movement of the probe 500 further includes a direction changing gear 600.

The probe 500 includes the ultrasonic generator 100 at its end and slides. The probe 500 slides to move the ultrasonic generator 100.

The direction changing gear 600 is located on both sides of the probe 500 to change the direction of the LED light output angle according to the slide movement of the probe 500. The direction changing gear 600 operates so that the LED light output angle changes direction according to the slide movement of the probe 500.

3 is an exemplary view showing a configuration of the direction change gear 600.

The direction changing gear 600 operates to adapt the LED light output angle against the skin as the probe 500 slides back and forth. When the probe 500 moves back and forth, the position of the ultrasonic generator 100 changes. The direction changing gear 600 switches the LED light output angle so that the LED light output is irradiated to the position of the ultrasonic generator 100.

4 is an exemplary view showing an embodiment of the probe 500.

The cell proliferation control device includes an ultrasonic generator 100 located at the end of the probe 500; A circular frame 700 which is configured in the center of the probe 500 so that the probe 500 slides and surrounds the probe 500; A direction change gear 600 configured on both side circular frames 700 of the probe 500 to change the angle of the LED light output according to the slide movement of the probe 500; A support bar 800 located on the opposite side of the probe 500 and transmitting the front and rear slide movement of the ultrasonic generator 100 to the direction changing gear 600 fixed to the circular frame 700; And a control rod 900 that is linked to the support rod 800 around the redirection gear 600 to adjust the light output angle of the LED 200 according to the inclination of the support rod 800.

The ultrasonic generator 100 is located at the end of the probe 500. The ultrasonic generator 100 generates ultrasonic waves having a wavelength that controls cell proliferation. Ultrasound at specific wavelengths controls cell proliferation. In order to control cell proliferation, an ultrasonic generator 100 that generates ultrasonic waves in a specific wavelength band is used. Ultrasound is used for medical treatment purposes, and ultrasound at a specific wavelength can suppress cell proliferation. The ultrasonic generator 100 may use a frequency oscillator to generate ultrasonic waves having a specific wavelength. The frequency oscillator generates a specific frequency to drive the ultrasonic oscillator, so that the ultrasonic oscillator generates ultrasonic waves having a specific wavelength.

The circular frame 700 is configured in the center of the probe 500 so that the probe 500 slides and surrounds the probe 500. The probe 500 slides along the inner surface of the circular frame 700.

The direction change gear 600 is configured on the circular frame 700 on both sides of the probe 500 to change the angle of the LED light output according to the slide movement of the probe 500. The direction changing gear 600 operates to adapt the LED light output angle against the skin as the probe 500 slides back and forth. When the probe 500 moves back and forth, the position of the ultrasonic generator 100 changes. The direction changing gear 600 switches the LED light output angle so that the LED light output is irradiated to the position of the ultrasonic generator 100.

The support rod 800 is located at the opposite end of the probe 500 and transmits the front and rear slide movement of the ultrasonic generator 100 to the direction changing gear 600 fixed to the circular frame 700.

The adjustment rod 900 is linked to the support rod 800 around the redirection gear 600 to adjust the light output angle of the LED 200 according to the inclination of the support rod 800. The LED 200 outputs light of a wavelength band that controls cell proliferation, and the light output angle is adjusted to the skin surface according to the position where the ultrasonic generator 100 contacts the skin. Light at a specific wavelength controls cell proliferation. To control cell proliferation, LEDs 200 of a specific wavelength are used. In the LED 200, the light output angle is adjusted so that light of a specific wavelength band is irradiated to the point where the ultrasound generating unit 100 outputs ultrasound to the skin. Light is used for medical treatment purposes, and light at a specific wavelength can suppress cell proliferation. The LED 200 outputs light of a specific wavelength band, and the LED driver 300 drives the LED 200. The LED driver 300 can control the light output by PWM control of the LED 200.

To describe the operation, the probe 500 slides. The support bar 800 transmits the front and rear slide movement of the probe 500 to the direction changing gear 600 fixed to the circular frame 700. The direction change gear 600 is configured on the circular frame 700 on both sides of the probe 500 to change the angle of the LED light output according to the slide movement of the probe 500. The adjustment rod 900 is linked to the support rod 800 around the redirection gear 600 to adjust the light output angle of the LED 200 according to the inclination of the support rod 800.

5 is an exemplary view showing a configuration of a cell growth control device that moves the probe 500 according to the density of cells.

The cell proliferation control device includes a sensor 1000 for sensing the density of cells; And a moving unit 1100 moving the probe 500 back and forth according to the density of the sensed cells.

The sensor 1000 senses the density of the cells. The sensor 1000 transmits the sensed cell density value to the moving unit 1100. The moving unit 1100 moves the probe 500 to the back of the skin when the cell density value is small, instructs the control unit 400 to lower the LED light output intensity, and when the cell density value is large, moves the probe 500 toward the skin. It can be moved and instructed to the control unit 400 to increase the LED light output intensity. The moving part 1100 moves the probe 500 back and forth according to the density of the sensed cells.

The control unit 400 may control the intensity of the ultrasound and light according to the intensity of the probe 500 touching the skin. When the intensity of the probe 500 touching the skin is strong, the controller 400 is operated to lower the intensity of ultrasound and light, and when the intensity of the contact is weak, the controller 400 can be operated to increase the intensity of ultrasound and light.

6 is an exemplary view showing a configuration of the display unit 710.

The circular frame 700 includes a display unit 710 displaying a moving distance of the probe 500.

The display unit 710 is mounted on the surface of the circular frame 700 to display the moving distance of the probe 500. The display unit 710 may display the moving distance of the probe 500 to indirectly display ultrasound and light intensity. In an embodiment, when the intensity at which the probe 500 touches the skin is strong, the moving distance of the probe 500 is largely displayed, and when the intensity at which the touch is weakened, the moving distance of the probe 500 is small. The display unit 710 may be designed such that the magnitude of the moving distance value indicates the intensity of ultrasound and light.

In summary, the cell proliferation control device can output ultrasound and light in a wavelength band that controls cell proliferation.

When the probe slides, the LED light output angle changes direction, so that ultrasound and light are irradiated to the skin.

Depending on the density of the cells, the probe is moved, so that the output intensity of ultrasound and light can be adjusted.

The cell proliferation control device may display the moving distance of the probe to display the output intensity of ultrasound and light.

[Example 1]

7 is an exemplary view illustrating probe movement buffering.

The cell proliferation control device includes a spring 510 that buffers the movement of the probe 500. The spring 510 cushions the front and rear movement of the probe 500.

[Example 2]

8 is a block diagram showing a configuration for measuring a probe movement distance.

The cell proliferation control device includes a disk 520 for converting linear motion into rotary motion; A link 530 for transmitting the linear motion of the probe 500 to the disk 520; An optical sensor 540 that senses rotation of the disk 520 and outputs a sensing value; And a control unit 400 for calculating the moving distance of the probe 500 according to the sensing value. The disk 520 converts linear motion into rotary motion. The link 530 transmits the linear motion of the probe 500 to the disk 520. When the link 530 is connected to the inner radius of the disk 520 and the optical sensor 540 is located at the outer radius of the disk 520, the movement of the link 530 may be detected by multiplying the optical sensor 540. . Due to this, the optical sensor 540 can more accurately measure the movement of the probe 500. The optical sensor 540 detects the rotation of the disk 520 and outputs a sensing value. The control unit 400 calculates the moving distance of the probe 500 according to the sensing value. The display unit 710 may display the moving distance of the probe 500 to indirectly display ultrasound and light intensity.

9 is a diagram illustrating the effect of inhibiting cell proliferation of cervical cancer cells, and FIG. 10 is a diagram illustrating the effect of inhibiting cell proliferation of glioma cancer cells.

The cell proliferation inhibitory effect of cervical cancer cells is summarized in FIG. 9, and the cell proliferation inhibitory effect of glioma cancer cells is summarized in FIG. 10. In the case of cervical cancer cells, the cell proliferation inhibitory effect was suppressed in proportion to the given time when compared to the control group, which was not given stimulation of LED or ultrasound. Among them, the group irradiated with LED and lens (LED + LENS) for 30 minutes showed the lowest density value of 38.7% compared to the control group. However, within the LED group irradiated with LED only, the group exposed to stimulation for 15 minutes showed additional cell proliferation inhibition by 4% compared to the group exposed to stimulation for 30 minutes. On the other hand, in the case of glioma cells, the cell-inserted LED and ultrasonic stimulation group (LED + LENS + ULTRASOUND) analyzed cell density to 39.5% of the unit area, indicating that cell proliferation inhibition was most active. Specifically, in the group (ULTRASOUND), which only irradiated ultrasound, cancer cells were proliferated up to 32.5% more than the control. It is difficult to expect the same or similar inhibitory effect of all types of cancer cells and complex LED and ultrasound stimulation used for the purpose of cancer treatment, and different treatment methods are used depending on the type of cells to be treated and the stimulation source of fusion treatment. It can be said that it shows the result to be set.

Although described above with reference to preferred embodiments of the present invention, those skilled in the art variously modify and change the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. You can understand that you can.

100: ultrasonic generator 200: LED
300: LED driver 400: control unit
500: probe 600: turning gear
700: circular frame 710: display
800: support bar 900: adjustment bar
1000: sensor

Claims (6)

An ultrasonic generator 100 that generates ultrasonic waves in a wavelength band that controls cell proliferation;
LED 200 that outputs light of a wavelength band that controls cell proliferation, and that the light output angle is adjusted to the skin surface according to the position where the ultrasonic generator 100 contacts the skin;
LED driver 300 for driving the LED 200; And
Control unit 400 for controlling the ultrasonic generator 100 and the LED driver 300 to control cell proliferation,
A probe 500 that includes the ultrasonic generator 100 at its end and slides; And
The probe 500 is located on both sides of the probe 500 further comprises a direction change gear 600 for changing the direction of the LED light output angle according to the slide movement,
Sensor 1000 for sensing the density of the cells; And
Cell proliferation control device further comprises a moving unit (1100) for moving the probe 500 back and forth according to the density of the sensed cells. delete According to claim 1,
The redirection gear 600 is a cell growth control device that operates to adapt the LED light output angle against the skin as the probe 500 slides back and forth. According to claim 1,
An ultrasonic generator 100 located at the end of the probe 500;
A circular frame 700 configured in the center of the probe 500 so as to slide the probe 500 and surrounding the probe 500;
A direction change gear 600 configured on both sides of the probe 500 and configured on the circular frame 700 to change the angle of the LED light output according to the slide movement of the probe 500;
A support rod 800 located on the opposite side of the probe 500 end and transmitting the front and rear slide movement of the ultrasonic generator 100 to the direction changing gear 600 fixed to the circular frame 700; And
Cells comprising a control rod (900) that is linked to the support rod (800) around the redirection gear (600) and adjusts the light output angle of the LED (200) according to the inclination of the support rod (800). Proliferation control device. delete According to claim 4,
The circular frame 700 is a cell growth control device including a display unit 710 for displaying the moving distance of the probe (500).

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