KR20220107481A - Multimodal System for Skin care - Google Patents

Abstract

The present invention relates to a skin care multimodal system. More specifically, the present invention relates to the skin care multimodal system with excellent proliferation effect of fibroblasts through an optical stimulation and ultrasonic stimulation using blue LED. The skin care multimodal system according to the present invention comprises: an ultrasonic stimulation part that generates ultrasonic waves; and a light source irradiation part that irradiates a light source of any one among a visible light LED, an infrared light LED, or a combination thereof.

Description

Skin care multimodal system {Multimodal System for Skin care}

The present invention relates to a skin care multi-modal system, and more particularly, to a skin care multi-modal system having an excellent effect on the proliferation of fibroblasts through photostimulation and ultrasonic stimulation using blue LEDs.

The LED-based industry, which has recently emerged rapidly, is showing growth that is difficult to predict. At the same time, in the field of beauty care, various products using LED are being introduced. In fact, when LED stimulation is applied to the skin, in addition to the wrinkle improvement effect, it is effective for acne vulgaris in papillary acne lesions, and safety can also be guaranteed, so many studies using LED are underway.

Among them, the market size of the LED mask, which treats damaged skin and removes wrinkles, is also growing. LED therapy used in LED masks can improve skin appearance by regulating collagen and MMP-1 expression. Several studies are being conducted to confirm the effect of photostimulation of a specific wavelength to be used in such an LED mask on the skin.

However, compared to commercialized systems that apply a single light stimulus, quantitative analysis of the stimulus effect is limited, and in fact, some LED masks sell products that give photostimulation that have not been proven effective or sell them at low prices, raising the alarm of consumers. there is a situation

Note that all light sources do not have a positive effect on cell differentiation and, in fact, special wavelength bands do not have a direct effect on cell proliferation, wound healing, cell regeneration, etc. in many cases. If you continuously apply incorrect stimulation to your skin with an LED mask, you may not get any effect, and even side effects may occur. In this situation, there is a need to find photostimulation in the wavelength band that can give practical effects to users and develop products based on reliable data.

Blue LED is non-toxic, so it is suitable for use in LED masks. In addition, the photostimulation of the blue wavelength band shows higher absorption than the photostimulation of the red wavelength band and has a significant effect on wound healing.

However, most of the LED masks are made around a red or infrared light source, and studies on complex photostimulation and ultrasonic stimulation of a relatively short wavelength of blue are relatively insignificant.

The present inventors have developed a multi-modal stimulation system capable of simultaneous application of blue LED single or combined optical stimulation and ultrasound stimulation, and through this, an excellent fibroblast proliferation effect was confirmed, leading to the present invention.

Domestic Registered Patent No. 10-1814435 Domestic Patent Publication No. 10-2020-0099677

An object of the present invention for solving the above problems is to provide a skin care multimodal system having an excellent effect on the proliferation of fibroblasts through photostimulation and ultrasonic stimulation using blue LEDs.

The skin care multi-modal system of the present invention for solving the above problems is excellent in the proliferation effect of fibroblasts, and irradiating an ultrasonic stimulation unit that generates ultrasonic waves, visible light LEDs, infrared LEDs, or any one light source of a combination thereof. It includes a light source irradiator.

The visible light LED may be selected from any one of a blue LED (400 to 430 nm), a red LED (620 to 640 nm), or a combination thereof, and preferably, a blue LED alone or a light source in combination with a blue LED may be selected. .

The ultrasonic stimulation unit is for massaging and activating the cell tissue through vibration, and may be used to generate a sin signal of a frequency of 1 to 20 MHz, an output voltage of 15 to 30 mVpp, and a sin signal of 100 to 300 cycles.

In addition, the ultrasonic stimulation unit is linked with a separate sensing module and control means for sensing the moisture level of the skin, the skin temperature, and the contact area to control the ultrasonic stimulation time and intensity according to the moisture level and the contact area of the skin, or generated during ultrasonic stimulation It is also possible to turn off the operation of the ultrasonic wave when the skin temperature rises due to the heat generated outside the preset temperature range.

As described above, according to the skin care multi-modal system according to the present invention, there is an excellent effect in the proliferation rate of fibroblasts through photostimulation and ultrasonic stimulation using blue LEDs.

1 is a conceptual diagram showing a process of preparing a cell well for a cell culture experiment according to an embodiment of the skin care multi-modal system of the present invention.
Figure 2 is a cell culture flask position design for each photostimulation group according to an embodiment of the skin care multi-modal system of the present invention.
3 is a conceptual diagram of a multi-modal simulation system according to an embodiment of the skin care multi-modal system of the present invention.
4 is a representative image of cells for each group stimulated with us according to an embodiment of the skin care multi-modal system of the present invention.
5 is a representative image of cells for each group stimulated with an LED according to an embodiment of the skin care multi-modal system of the present invention.
6 is a representative image of cells for each group stimulated with us+LED according to an embodiment of the skin care multimodal system of the present invention.
7 is a MATLAB code used for image processing according to an embodiment of the skin care multi-modal system of the present invention.
8 is an image before and after image processing according to an embodiment of the skin care multi-modal system of the present invention.
9 is a graph comparing the average increase in cell activity by LED alone irradiation group according to an embodiment of the skin care multimodal system of the present invention.
10 is a graph comparing the average increase in cell activity for each LED + us complex treatment group according to an embodiment of the skin care multimodal system of the present invention.

Specific features and advantages of the present invention will be described in detail below with reference to the accompanying drawings. Prior to this, if it is determined that the detailed description of the function and its configuration related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

The present invention relates to a skin care multi-modal system, and more particularly, to a skin care multi-modal system having an excellent effect on the proliferation of fibroblasts through photostimulation and ultrasonic stimulation using blue LEDs.

1. Experimental method

1.1 Cell culture experiment

1 is a conceptual diagram showing a process of preparing a cell well for a cell culture experiment. The fibroblasts used in the experiment were CCD-986sk cells (Korea Cell Line Bank, Korea). The medium solution used for the cells was mixed with IMDM (Isocove's Modified Dulbecco's Medium) containing glucose, 10% FBS (Fetal Bovine Serum, pH 7.4), and 1% Penicillin Streptomycin.

In addition, the cells were grown in a cell culture medium containing 5% carbon dioxide at 37°C while periodically changing the medium. Cells were washed twice with 5mL PBS each time the medium was replaced, and in this process, suspended matter and proteins were removed.

Before the experiment, in order to bring the fibroblasts to be tested from the flask, the process of detaching the cells from the flask is as follows. When Trypsin was used to detach cells, 5 mL of Trypsin was injected into the cells and stored in a cell incubator for 5 minutes. After that, the cell suspension containing the Trypsin solution was separated using a centrifuge, and the cells under the mini tube were checked, and then injected into the wells to be used for the experiment, and the experiment was performed.

The experiment was carried out for a period of about 7 days, and the day when no stimulation was applied was marked as day 0, and the day when stimulation was first applied was marked as day 1. When observing cells under a microscope, images were acquired before the experiment for each day and then the experiment was performed. In order to check the proliferation rate of cells, photos of cells proliferating at the same location as taken on day 0 were taken until the end of the experiment to confirm the exact growth rate. When single stimulation was applied, LED or ultrasound (hereinafter referred to as us) was applied to each well. When multi-stimulation was applied, both LED and us stimulation were applied at the same time, and all stimulations were given for 20 minutes. 2 shows the design of the cell culture flask for each photostimulation group.

1.2 Light source experiment

When manufacturing the light stimulation system, LEDs (LG Innotek 3528, LG Innotek, Korea), which are mainly used in existing LED masks, were used. 620 ~ 640nm, Infrared is 840 ~ 860nm. A single stimulus of LED or us was applied, or multi-stimulus that included both LED and us was applied.

Then, the stimulus system used to apply the us stimulus was a waveform generator (Function generator, Tecktronics Inc., Beaverton, OR, USA). For the experiment, a sine wave signal with a frequency of 10 MHz and an output voltage of 20 mVpp and 100 cycles was generated. After that, it is transmitted to the ultrasonic probe through the amplifier under the waveform generator and the corresponding photostimulation is applied to the cells. In order not to cause contamination of cells by the ultrasonic probe in case of stimulation of us, the experiment was carried out by disinfecting the inlet of the probe with alcohol each time an experiment was performed. In addition, the system was constructed using a stand support in order to not only allow the stimulation to go exactly to the same location, but also to prevent the probe from directly touching the cell. When multi-stimulation is given by using a multi-modal stimulation system, the LED gives stimulation from the bottom of the well, and us has the form of stimulation from the top of the well. 3 shows a conceptual diagram of a multi-modal simulation system.

2.3 Image processing and quantitative analysis

Among the images of cells obtained using an inverted fluorescent microscope (IX73, Olympus, Japan), representative images for each group are shown in FIGS. 4 to 6 . 4 is a representative image of cells for each group stimulated with us, FIG. 5 is a representative image of cells for each group stimulated with LED, and FIG. 6 is a representative image of cells for each group stimulated with us+LED.

Matlab (Mathworks, USA) was used for image processing, and the cell proliferation rate was checked by making a code to distinguish non-cellular and cellular parts. At this time, the MATLAB code used for image processing is shown in FIG. 7 . To summarize this simply, use the imflatfield function to remove the error part of the image. Afterwards, check the difference in color between the cellular and non-cellular parts of the image through MATLAB. And, using im2bw, make the cell part appear white and the non-cell part black to check the accuracy, then use the drawpolygon function to remove the error part such as scratch to increase the accuracy. Then, the noise is removed using the ExtractNLargestBlobs function, which is an open function, so that only the cell part is extracted by removing the noise, not the cell part, with a small number of dots. After obtaining the area of the cell, a boundary line appears on the image to confirm the result of detecting the cell. The code requires an image processing toolbox, and images before and after image processing are shown in FIG. 8 , respectively. Fig. 8(A) is before image processing, and Fig. 8(B) is after image processing.

3. Results

Tables 1 and 2 below show the results of comparison of the increased area of the experimental group to which photostimulation consisting only of LEDs was applied and the experimental group to which ultrasonic stimulation was applied together, respectively.

Representative images of the experimental group and the control group were obtained using an optical microscope, and quantified by comparing the proliferation area of the cells using Matlab, and compared in FIGS. 9 and 10 . In the case of the experimental group and the control group to which photostimulation consisting only of LEDs was applied, respectively, the highest proliferation rate was shown in B, followed by the highest growth rate in IR+R+B. If this is expressed as an inequality sign, B > IR+R+B > R+B > IR+B > IR+R > R for the LED stimulus, and B+US > IR+B+US > R+US for the us stimulus. > IR+R+US > IR+R+B+US > R+B+US. Therefore, in the case of the experimental group and control group to which ultrasound stimulation was applied, the highest proliferation rate was shown in B+US, followed by the highest growth rate in IR+B+US. As a result, it can be confirmed that the highest proliferation rate is shown when the blue wavelength is applied. In addition, it was confirmed that multi-modal stimulation and single stimulation showed different proliferation rates for each wavelength band.

4. Conclusion

In this design study, CCD-986sk cell experiments were conducted using LED and ultrasonic equipment, and then the cell proliferation rate was checked using matlab. The results were confirmed by applying photostimulation in the blue wavelength band, which showed the best growth rate in the last experiment, and photostimulation centered on ultrasound. When the results of all the experiments conducted following the last semester were combined, it was confirmed that R+B and B+US had the highest proliferation rate, respectively, in the case of light stimulation only with LEDs without us and stimulation with us. . This is a result that is theoretically most affected by the blue wavelength, and shows that it has been proven through experiments. This design is different in that it confirmed whether various optical stimuli, including blue LED and ultrasound, have an irritating effect on the skin. In the future, based on the results of this experiment, it will be helpful to solve the problems of the existing LED mask in the development of light care beauty equipment by appropriately using the respective advantages of LED and ultrasonic equipment. It is also expected to provide data that can be used for research and development to find optimal development conditions. In the future, additional studies are planned to be conducted to optimize the accuracy and system optimization of quantitative evaluation of the proliferation effect using optical and ultrasonic fusion stimulation of different wavelength bands.

As described above, the present invention has been mainly described with reference to the accompanying drawings, but those of ordinary skill in the art to which the present invention pertains within the scope not departing from the technical spirit and scope described in the claims of the present invention. Various modifications or variations of the present invention can be practiced. Accordingly, the scope of the present invention should be construed by the appended claims to include examples of many such modifications.

Claims (4)

an ultrasonic stimulation unit that generates ultrasonic waves; and
A light source irradiator for irradiating any one of a visible light LED, an infrared LED, or a combination thereof;
Skin care multimodal system.
The method of claim 1,
The visible light LED is
Blue LED, red LED, or any one of a combination thereof, characterized in that
Skin care multimodal system.
The method of claim 1,
The ultrasonic stimulation unit
1 to 20 MHz of ultrasonic waves, characterized in that
Skin care multimodal system.
The method of claim 1,
Characterized in having a proliferative effect of fibroblasts
Skin care multimodal system.

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