阅读说明：本技术 基于水动力软性剥离技术的皮肤抗衰处理方法及皮肤检测系统 (Skin anti-aging treatment method based on hydrodynamic soft peeling technology and skin detection system ) 是由 崔海茹 于 2021-08-26 设计创作，主要内容包括：本发明公开了一种基于水动力软性剥离技术的皮肤抗衰处理方法及皮肤检测系统,首先采集皮肤的多个检测位置的衰老程度信息；然后根据衰老程度信息,选取至少一个检测位置作为肌龄复原位置；最后将复原营养剂由肌龄复原位置注入皮下区域。本发明利用“水动力软性剥离”作用,使注入的复原营养剂能够自动避开皮下区域的血管及神经,实现对肌肤自体修复能力的激活,产生大量纤维组织增生,增加皮下组织厚度,使肌肤更为致密紧实。复原营养剂能够补充皮肤塌陷部位流失的营养,达到皮肤饱满弹滑、紧致提升的显著效果。另外,本发明无需开刀手术,大幅提高美容过程的安全性。(The invention discloses a skin anti-aging processing method and a skin detection system based on a hydrodynamic soft stripping technology, which comprises the following steps of firstly, acquiring aging degree information of a plurality of detection positions of the skin; then, selecting at least one detection position as a muscle age rehabilitation position according to the aging degree information; and finally, injecting the recovery nutrient into the subcutaneous region from the muscle age recovery position. The invention utilizes the action of hydrodynamic soft stripping to ensure that the injected restoration nutrient can automatically avoid blood vessels and nerves in a subcutaneous region, thereby realizing the activation of the self-repairing capability of the skin, generating a great amount of fibrous tissue hyperplasia, increasing the thickness of the subcutaneous tissue and leading the skin to be more compact and compact. The recovery nutrient can supplement nutrition lost at the skin collapse part, and achieves the remarkable effects of plump, elastic, smooth, compact and improved skin. In addition, the invention does not need an operation, thereby greatly improving the safety of the beauty treatment process.)

1. The skin anti-aging treatment method based on the hydrodynamic soft stripping technology is characterized by comprising the following steps:

(1) collecting aging degree information of a plurality of detection positions of skin;

(2) selecting at least one detection position as a muscle age rehabilitation position according to the aging degree information;

(3) injecting a rejuvenating nutrient into the subcutaneous region from the muscle age rejuvenation site, the rejuvenating nutrient comprising collagen, sodium hyaluronate, carnosine, amino acids, vitamin B2, vitamin C, and growth factors.

2. The method of claim 1, wherein the method comprises: the skin in the step (1) is facial skin, and the plurality of detection positions are respectively positioned at the parts of the forehead and the temple, which are positioned in the hair track, beside the ears or behind the ears.

3. The method of claim 1, wherein the method comprises: the aging degree information in the step (2) comprises the wrinkle depth of the skin, and the relation between the injected amount of the restoration nutrient and the wrinkle depth of the skin is positive correlation; and/or the aging degree information includes wrinkle density of the skin, and the relation between the injected amount of the restoration nutrient and the wrinkle density of the skin is positive correlation.

4. The method of claim 1, wherein the method comprises: in the step (3), the rejuvenation nutrient is injected in multiple times during the process of injecting the rejuvenation nutrient from the muscle age recovery site into the subcutaneous region.

5. The method for skin anti-aging treatment based on hydrodynamic soft peeling technology as claimed in claim 1 or 4, wherein: in the step (3), in the process of injecting the recovery nutrient into the subcutaneous region from the muscle age recovery position, the outer diameter of the needle tube of the injector is less than 0.35mm, and the inner diameter of the needle tube is less than 0.1 mm.

6. The method of claim 1, wherein the method comprises: further comprising, prior to the step of collecting information on the degree of aging of the skin at a plurality of test locations, cleaning the skin; and/or sterilizing the skin in the muscle age-restored area prior to the step of injecting a rejuvenating nutrient from the muscle age-restored area into the subcutaneous area; and/or anesthetizing the skin prior to the step of injecting rejuvenating nutrients from the muscle age rejuvenation site into the subcutaneous region, and after the step of sterilizing the skin in the muscle age rejuvenation site.

7. A skin detection system, comprising:

the acquisition module is used for acquiring and generating image information of a plurality of detection positions of the skin; and

and the processing module is connected with the acquisition module and used for receiving and converting the image information into aging degree information, and selecting at least one detection position as a muscle age recovery position according to the aging degree information so as to inject a recovery nutrient into a subcutaneous region from the muscle age recovery position.

8. The skin detection system of claim 7, wherein the acquisition module comprises:

the image acquisition unit is used for acquiring the image information in an optical photographing mode; and/or

And the sound wave transceiving unit is used for calculating and acquiring the image information by sending sound waves and receiving echoes to the detection position.

9. The skin detection system of claim 7, wherein the processing module comprises:

the information conversion unit is connected with the acquisition module and used for receiving the image information and converting the image information into the aging degree information;

the comparison selection unit is connected with the information conversion unit and is used for comparing a plurality of pieces of aging degree information to select at least one detection position to which the aging degree information belongs as a muscle age recovery position; and

and the interaction unit is connected with the comparison selection unit and used for displaying the image information and/or the aging degree information of the muscle age rehabilitation position selected by the comparison selection unit so as to be extracted by a user.

10. The skin detection system of claim 7, wherein: the aging degree information is characterized by wrinkle depth and/or wrinkle density of the skin.

Technical Field

The invention belongs to the technical field of skin anti-aging, and particularly relates to a skin anti-aging treatment method and a skin detection system based on a hydrodynamic soft peeling technology.

Background

The skin is affected by many factors such as heredity, age, living environment, gravity, etc., and as nutrients such as collagen are lost, cell cytoplasm is reduced, and the skin gradually generates aging states such as wrinkles, collapse, shriveling, prolapsed, atrophy, etc.

Taking facial skin as an example, in order to perform anti-aging treatment on the skin, the existing scheme adopts facial tightening (namely skin-pulling operation) to improve the facial contour, so as to achieve the effect of youth recovery. Specifically, existing solutions typically design cut lines on the face. The skin is cut along the incision line and peeled off along the subcutaneous fat layer by a surgical instrument, thereby stimulating the collagen recombination, realizing the effects of tightening the skin and reducing wrinkles, and lifting the loose skin of the face to the back upper part, thereby eliminating the aging and loosening phenomenon of the wrinkles of the face, and solving the proud flesh phenomenon.

However, after the above-described conventional facial tightening treatment, wrinkles are not actually removed, and a state of aging is still exhibited. The reasons include: the above-mentioned existing treatment solutions only tension the skin and do not fundamentally solve the aging of the skin, in particular: existing treatment regimens do not slow or address the progression of skin aging; the existing treatment scheme has no proper way to solve the pull-down effect of gravity on skin and facial tissues; the skin treated by the existing treatment scheme has no elasticity, fullness and compact feeling.

The hydrodynamic force soft stripping technology is that the injected liquid enters the bottom layer of the skin of a human body, the bottom layer of the skin is stripped through pressing, after skin tissues are stripped, the human body can automatically repair the skin tissues to generate scars, and the hyperplasia capability and the contracture force of the scars can resist aging. Compared with the existing blunt instrument in the skin-pulling operation, the hard stripping can damage the tiny blood vessels in the skin, the hydrodynamic soft stripping can automatically avoid the blood vessels, the safety of the anti-aging and beautifying process of the skin is improved, the anti-aging treatment of the skin is carried out based on the hydrodynamic soft stripping technology, so that the skin with different degrees of aging can return to an ideal state according to the needs of the skin, the effects of improving compactness, returning youth contour and plumpness are achieved, and the safety of the beautifying process is greatly improved.

Disclosure of Invention

The invention aims to overcome the defects of poor safety and poor effect of the existing skin anti-aging treatment method, and provides a skin anti-aging treatment method and a skin detection system based on a hydrodynamic soft peeling technology.

Technical scheme

In order to achieve the technical purpose, the invention provides a skin anti-aging treatment method based on a hydrodynamic soft stripping technology, which is characterized by comprising the following steps:

(1) collecting aging degree information of a plurality of detection positions of skin;

(2) selecting at least one detection position as a muscle age rehabilitation position according to the aging degree information;

(3) injecting a rejuvenating nutrient into the subcutaneous region from the muscle age rejuvenation site, the rejuvenating nutrient comprising collagen, sodium hyaluronate, carnosine, amino acids, vitamin B2, vitamin C, and growth factors.

Further, the skin in step (1) is facial skin, and the plurality of detection positions are located at the parts of the forehead and the temple located in the hair track, beside the ear or behind the ear, respectively.

Further, the aging degree information in the step (2) includes the wrinkle depth of the skin, and the relationship between the injected amount of the restoration nutrient and the wrinkle depth of the skin is positive correlation; and/or the aging degree information includes wrinkle density of the skin, and the relation between the injected amount of the restoration nutrient and the wrinkle density of the skin is positive correlation.

Further, in the step (3), the rejuvenation nutrient is injected in multiple times during the process of injecting the rejuvenation nutrient from the muscle age rejuvenation site into the subcutaneous region.

Further, in the step (3), in the process of injecting the rejuvenating nutrient from the muscle age rehabilitation site into the subcutaneous region, the outer diameter of the needle tube of the injector is less than 0.35mm, and the inner diameter of the needle tube is less than 0.1 mm.

Further, the method comprises the steps of cleaning the skin before the step of collecting the aging degree information of a plurality of detection positions of the skin; and/or sterilizing the skin in the muscle age-restored area prior to the step of injecting a rejuvenating nutrient from the muscle age-restored area into the subcutaneous area; and/or anesthetizing the skin prior to the step of injecting rejuvenating nutrients from the muscle age rejuvenation site into the subcutaneous region, and after the step of sterilizing the skin in the muscle age rejuvenation site.

The invention also provides a skin detection system, which comprises an acquisition module and a processing module; the acquisition module is used for acquiring and generating image information of a plurality of detection positions of the skin; the processing module is connected with the acquisition module and used for receiving and converting the image information into aging degree information, and at least one detection position is selected as a muscle age recovery position according to the aging degree information so as to inject a recovery nutrient into a subcutaneous region from the muscle age recovery position.

Further, the acquisition module comprises an image acquisition unit and/or a sound wave transceiving unit; the image acquisition unit is used for acquiring the image information in an optical photographing mode; the sound wave transceiving unit is used for obtaining the image information through sending sound waves to the detection position and receiving echo calculation.

Furthermore, the processing module comprises an information conversion unit, a comparison selection unit and an interaction unit; the information conversion unit is connected with the acquisition module and used for receiving the image information and converting the image information into the aging degree information; the comparison selection unit is connected with the information conversion unit and is used for comparing a plurality of pieces of aging degree information to select at least one detection position to which the aging degree information belongs as a muscle age recovery position; the interaction unit is connected with the comparison selection unit and used for displaying the image information and/or the aging degree information of the muscle age rehabilitation position selected by the comparison selection unit so as to be extracted by a user.

Further, the aging degree information is characterized by wrinkle depth and/or wrinkle density of the skin.

Advantageous effects

The skin anti-aging treatment method and the skin detection system based on the hydrodynamic soft stripping technology can collect skin information, select the skin age recovery position according to the aging degree of the skin, and inject the recovery nutrient into a subcutaneous area from the skin age recovery position. Therefore, under the action of hydrodynamic soft stripping, the injected restoration nutrient can automatically avoid blood vessels and nerves in a subcutaneous region, so that the self-repairing capability of the skin is activated, a large amount of fibrous tissue hyperplasia is generated, the thickness of subcutaneous tissues is increased, and the skin is more compact and firmer. Meanwhile, rich nutrients contained in the recovery nutrient can supplement nutrients lost at collapse parts of the skin, and the remarkable effects of plump, smooth, compact and improved skin are achieved. In addition, compared with the existing treatment schemes such as facial tightening and the like, the method disclosed by the invention does not need a scalpel operation, can realize the injection of the recovery nutrient only through minimally invasive injection, is safe and convenient, does not generate scars, can realize quicker postoperative recovery, and greatly improves the safety of the beauty process.

Drawings

FIG. 1 is a schematic flow chart of a skin anti-aging treatment method in an embodiment of the invention

FIG. 2 is a schematic diagram of the connection of the skin detection system in an embodiment of the invention.

Wherein: 100-an acquisition module;

110-an image acquisition unit;

120-an acoustic transceiver unit;

200-a processing module;

210-an information conversion unit;

220-an alignment selection unit;

230-interaction unit.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "inner", "outer", "front", "rear", "left", "right", "general side", "spare side", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted" and "connected" are to be interpreted broadly, e.g., as being either fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The present invention will be described in further detail below with reference to specific embodiments and with reference to the attached drawings.

Examples

Referring to fig. 1, a flow chart of a skin anti-aging treatment method based on hydrodynamic soft peeling technology is representatively shown. In this exemplary embodiment, the skin anti-aging treatment method proposed by the present invention is explained taking anti-aging treatment applied to facial skin as an example. Those skilled in the art will readily appreciate that various modifications, additions, substitutions, deletions, or other changes may be made to the embodiments described below in order to apply the relevant designs of the present invention to the anti-aging treatment of skin in other locations, and still be within the scope of the principles of the proposed skin anti-aging treatment method of the present invention.

As shown in fig. 1, in the present embodiment, the method for anti-aging treatment of skin based on hydrodynamic soft peeling technology at least comprises the following steps:

collecting aging degree information of a plurality of detection positions of skin;

selecting at least one detection position as a muscle age rehabilitation position according to the aging degree information;

the rejuvenating nutrients are injected into the subcutaneous region from the muscle age rejuvenation site, and comprise collagen, sodium hyaluronate, carnosine, amino acids, vitamin B2, vitamin C, and growth factors.

Through the design, the injected restoration nutrient can automatically avoid blood vessels and nerves in a subcutaneous region by utilizing the hydrodynamic soft stripping effect, so that the self-repairing capability of skin is activated, a large amount of fibrous tissue hyperplasia is generated, the thickness of subcutaneous tissue is increased, and the skin is more compact and compact. Meanwhile, rich nutrients contained in the recovery nutrient can supplement nutrients lost at collapse parts of the skin, and the remarkable effects of plump, smooth, compact and improved skin are achieved. In addition, compared with the existing treatment schemes such as facial tightening and the like, the method disclosed by the invention does not need a scalpel operation, can realize the injection of the recovery nutrient only through minimally invasive injection, is safe and convenient, does not generate scars, and can realize quicker recovery after the operation.

Alternatively, in the present embodiment, taking facial skin as an example, the plurality of detection positions may be located at the parts of the forehead and the temple located in the hair track, beside the ear, or behind the ear, respectively. Therefore, the specific position of the face is the position where the facial skin is easy to age or has serious and obvious aging degree, and the aging degree information of the facial skin can be accurately and pertinently collected. In other embodiments, the skin at other positions may be collected according to different requirements of the repair treatment, and the present embodiment is not limited thereto.

Alternatively, in the present embodiment, the aging degree information may include the wrinkle depth of the skin. On the basis, the relationship between the injection amount of the restoration nutrient and the wrinkle depth of the skin can be positively correlated. In other words, the more deep the wrinkles, the larger the amount of the restoration nutrient injected at the site.

Further, the relationship between the amount of the restoration nutrient injected and the wrinkle depth of the skin may be designed to be a positive correlation, and in the present embodiment, the relationship of the "positive correlation" may be a proportional relationship. In other words, the injection amount of the restoration nutrient may be increased in equal proportion as the wrinkle depth is increased. In other embodiments, the relationship of the "positive correlation" may not be limited to a proportional relationship, for example, when the wrinkle depth is larger, the increase of the injection amount of the restoration nutrient may gradually decrease as the wrinkle depth increases.

Further, the present invention is designed to be based on the positive correlation between the injected amount of the restoration nutrient and the wrinkle depth of the skin, and in the present embodiment, the injected amount of the restoration nutrient may have an upper threshold. For example, when the injected amount of the rejuvenating nutrients increases with wrinkle depth to the upper threshold value, the injected amount of the rejuvenating nutrients does not exceed the upper threshold value even for a greater wrinkle depth.

Alternatively, in the present embodiment, the aging degree information may include wrinkle density of the skin. On the basis, the relationship between the injection amount of the restoration nutrient and the wrinkle density of the skin can be positively correlated. In other words, the more dense the wrinkles, the larger the amount of the restoration nutrient injected at the muscle age restoration site.

Further, the relationship between the amount of the restoration nutrient injected and the wrinkle density of the skin may be designed to be a positive correlation, and in the present embodiment, the relationship of the "positive correlation" may be a proportional relationship. In other words, as the density of wrinkles increases, the injection amount of the restoration nutrient may be increased in equal proportion. In other embodiments, the relationship of the "positive correlation" may not be limited to a proportional relationship, for example, when the wrinkle density is high, the increase of the injection amount of the restoration nutrient may gradually decrease as the wrinkle density increases.

Further, the present invention is designed based on the fact that the relationship between the injected amount of the restoration nutrient and the wrinkle density of the skin can be a positive correlation, and in the present embodiment, the injected amount of the restoration nutrient may have an upper threshold. For example, when the injected amount of the restoring nutrient increases to the upper threshold value with wrinkle density, the injected amount of the restoring nutrient does not exceed the upper threshold value even for a larger wrinkle density.

Alternatively, in the present embodiment, the content of collagen in the rejuvenating nutrient may be 1mg/ml to 10mg/ml, for example, 1mg/ml, 2mg/ml, 5mg/ml, 10mg/ml, or the like. In other embodiments, the content of the collagen in the restoring nutritional agent may be adjusted according to actual needs, and may be less than 1mg/ml, or may be greater than 10mg/ml, such as 0.9mg/ml, 12mg/ml, and the like, and is not limited to this embodiment.

Alternatively, in the present embodiment, the content of sodium hyaluronate in the reconstituted nutritional agent may be 1mg/ml to 10mg/ml, for example, 1mg/ml, 2mg/ml, 5mg/ml, 10mg/ml, or the like. In other embodiments, the content of the sodium hyaluronate in the restoration nutrient may be adjusted according to actual needs, and may be less than 1mg/ml, or may be greater than 10mg/ml, such as 0.9mg/ml, 12mg/ml, and the like, and is not limited to this embodiment.

Alternatively, in this embodiment, the amino acids in the reconstituted nutrient may comprise one or a combination of more of a plurality of types of amino acids, such as glycine, alanine, and the like. The content of the amino acid in the reconstituted nutrient may be 0.1mg/ml to 0.5mg/ml, for example, 0.1mg/ml, 0.2mg/ml, 0.4mg/ml, 0.5mg/ml, or the like. In other embodiments, the content of the amino acid in the reconstituted nutrient may be adjusted according to actual needs, and may be less than 0.1mg/ml, or may be greater than 0.5mg/ml, such as 0.05mg/ml, 0.6mg/ml, and the like, and is not limited to this embodiment.

Alternatively, in this embodiment, the vitamin B2 content in the reconstituted nutrient may be between 1 μ g/ml and 10 μ g/ml, such as 1 μ g/ml, 2 μ g/ml, 5 μ g/ml, 10 μ g/ml, and the like. In other embodiments, the content of vitamin B2 in the reconstituted nutrient may be adjusted according to actual needs, and may also be less than 1 μ g/ml, or may be greater than 10 μ g/ml, such as 0.9 μ g/ml, 12 μ g/ml, and the like, and is not limited to this embodiment.

Alternatively, in the present embodiment, the content of vitamin C in the reconstituted nutrient may be 100mg/ml to 500mg/ml, for example, 100mg/ml, 150mg/ml, 300mg/ml, 500mg/ml, or the like. In other embodiments, the content of vitamin C in the reconstituted nutrient may be adjusted according to actual needs, and may also be less than 100mg/ml, or may be greater than 500mg/ml, such as 80mg/ml, 550mg/ml, and the like, and is not limited to this embodiment.

Alternatively, in this embodiment, the growth factors in the rejuvenating nutrient may include one or a combination of more of a plurality of types of human intrinsic growth factors, such as EGF, bFGF, kGF, and the like. The content of the growth factor in the reconstituted nutrient may be 1. mu.g/ml to 100. mu.g/ml, for example, 1. mu.g/ml, 20. mu.g/ml, 50. mu.g/ml, 100. mu.g/ml, or the like. In other embodiments, the content of the growth factor in the reconstituted nutrient may be adjusted according to actual needs, and may also be less than 1 μ g/ml, or may be greater than 100 μ g/ml, such as 0.9 μ g/ml, 110 μ g/ml, and the like, and is not limited to this embodiment.

Alternatively, for the step of "injecting the rejuvenating nutrient from the muscle age rejuvenation site into the subcutaneous region", in the present embodiment, the rejuvenating nutrient may be injected in multiple times for any one muscle age rejuvenation site. Through the design, the invention can enable the rehabilitation nutrient injected into the subcutaneous region of one muscle age rehabilitation position to enter for multiple times through the treatment method of injecting the rehabilitation nutrient for multiple times, and simultaneously can reduce the stimulation on the subcutaneous tissue caused by injecting the rehabilitation nutrient for a large amount in a single time.

Alternatively, for the step of "injecting the reconstituted nutrient into the subcutaneous region from the muscle age reconstituted site", in the present embodiment, the syringe employed in this step may have a needle tube with an outer diameter of less than 0.35mm and an inner diameter of less than 0.1 mm. Through the design, the injection of the recovery nutrient can be realized by using the small-needle injector, the injection effect is more accurate, the skin damage is less, and the postoperative recovery is quicker.

Further, based on the design that the outer diameter of the syringe of the injector may be less than 0.35mm and the inner diameter may be less than 0.1mm, in the present embodiment, the outer diameter of the syringe of the injector may preferably be 0.33mm, and the machining tolerance of the outer diameter of the syringe is ± 0.005mm, and the inner diameter may preferably be 0.08mm, and the machining tolerance of the inner diameter of the syringe is ± 0.005 mm.

Optionally, in this embodiment, the method for anti-aging treatment of skin provided by the present invention may further include: the skin is cleaned prior to the step of collecting information on the degree of aging at the plurality of test locations of the skin. Among them, for the step of "cleaning the skin", a commonly used skin cleaning product, such as a face wash, etc., may be used to clean the skin of the user.

Optionally, in this embodiment, the method for anti-aging treatment of skin provided by the present invention may further include: the skin in the muscle-aged recovery site is sterilized prior to the step of injecting the recovery nutrient from the muscle-aged recovery site into the subcutaneous region. In the step of "sterilizing the skin of the aged recovery site", the skin of the user may be wiped with 75% medical alcohol to sterilize the skin.

Optionally, in this embodiment, the method for anti-aging treatment of skin provided by the present invention may further include: anesthesia is applied to the skin prior to the step of injecting rejuvenating nutrients from the muscle age rejuvenation site into the subcutaneous region, and after the step of sterilizing the skin in the muscle age rejuvenation site.

It is noted herein that the skin anti-aging treatment methods illustrated in the drawings and described in the present specification are but a few examples of the many ways in which the principles of the present invention can be employed. It should be clearly understood that the principles of the present invention are in no way limited to any of the details or any of the steps of the skin anti-aging treatment methods shown in the drawings or described in the specification.

Referring to fig. 2, a system diagram of the skin detection system of the present invention is representatively illustrated. In this exemplary embodiment, the skin detection system proposed by the present invention is explained taking aging detection applied to facial skin as an example. Those skilled in the art will readily appreciate that many modifications, additions, substitutions, deletions, or other changes may be made to the embodiments described below in order to apply the inventive concepts related to skin detection in other locations, and still fall within the scope of the principles of the skin detection system set forth herein.

As shown in fig. 2, in the present embodiment, the skin detection system provided by the invention includes an acquisition module 100 and a processing module 200. In particular, the acquisition module 100 is configured to acquire and generate image information of a plurality of detected locations of the skin. The processing module 200 is connected to the collecting module 100, and is configured to receive and convert the image information into aging degree information, and select at least one detection position as a muscle age recovery position according to the aging degree information, so as to inject a recovery nutrient into a subcutaneous region from the muscle age recovery position.

Optionally, as shown in fig. 2, in this embodiment, the acquisition module 100 may include an image acquisition unit 110 and an acoustic transceiver unit 120. Specifically, the image capturing unit 110 can acquire image information of the detected position of the skin by means of optical photographing. The acoustic wave transceiver unit 120 can calculate and acquire image information of a detected position of the skin by transmitting an acoustic wave to the detected position and receiving an echo. Accordingly, the acquisition module 100 can perform acquisition by using at least one of the image acquisition unit 110 and the acoustic wave transceiver unit 120, or perform combined acquisition by using both units, so as to meet the acquisition requirements of different specific states of the skin. In other embodiments, the acquisition module may also include only the image acquisition unit, or may include only the acoustic transceiver unit, and is not limited to this embodiment.

Optionally, as shown in fig. 2, in this embodiment, the processing module 200 may include an information converting unit 210, a comparing and selecting unit 220, and an interacting unit 230. Specifically, the information conversion unit 210 is connected to the acquisition module 100, and is configured to receive the image information and convert the image information into aging degree information. The comparing and selecting unit 220 is connected to the information converting unit 210, and is configured to compare the aging degree information to select a detection position to which at least one aging degree information belongs as a muscle age recovery position. The interaction unit 230 is connected to the comparison selection unit 220, and is configured to display at least one of the image information and the aging degree information of the muscle age recovery position selected by the comparison selection unit 220 for the user to extract, so as to perform the next operation.

As further shown in fig. 2, based on the design that the processing module 200 includes the interaction unit 230, in this embodiment, the interaction unit 230 may also be connected to the acquisition module 100, for example, connected to the image acquisition unit 110 and the acoustic wave transceiver unit 120, respectively, so as to display the image information of the detected position of the skin acquired by the acquisition module 100 in real time for the user to extract.

Further based on the design that the processing module 200 includes the interaction unit 230, in this embodiment, the interaction unit 230 may include a display screen (e.g., a touch screen), a speaker, and related operation keys.

Alternatively, in this embodiment, the characterization of the aging degree information converted by the processing module 200 may be at least one of wrinkle depth and wrinkle density of the skin.

It should be noted herein that the skin detection systems shown in the figures and described in this specification are only a few examples of the wide variety of skin detection systems that can employ the principles of the present invention. It should be clearly understood that the principles of the present invention are in no way limited to any of the details or any of the components of the skin detection system shown in the drawings or described in this specification.

In summary, the skin anti-aging treatment method provided by the invention selects the skin age recovery position according to the aging degree of the skin, and injects the recovery nutritional agent into the subcutaneous region from the skin age recovery position. Therefore, under the action of hydrodynamic soft stripping, the injected restoration nutrient can automatically avoid blood vessels and nerves in a subcutaneous region, so that the self-repairing capability of the skin is activated, a large amount of fibrous tissue hyperplasia is generated, the thickness of subcutaneous tissues is increased, and the skin is more compact and firmer. Meanwhile, rich nutrients contained in the recovery nutrient can supplement nutrients lost at collapse parts of the skin, and the remarkable effects of plump, smooth, compact and improved skin are achieved. In addition, compared with the existing treatment schemes such as facial tightening and the like, the method disclosed by the invention does not need a scalpel operation, can realize the injection of the recovery nutrient only through minimally invasive injection, is safe and convenient, does not generate scars, and can realize quicker recovery after the operation.

In particular, the traditional skin-pulling operation has adverse reactions or risks such as infection, hemorrhage and hematoma, skin necrosis, mental injury and the like. In the traditional skin-pulling operation, the wound surface is wide, and part of hair is exposed in the operation field, so that infection may occur. The most common complications of the traditional skin-pulling operation are hemorrhage and hematoma, the hematoma appears within more than 24 hours after the operation, the symptoms of aggravation of pain, swelling and purplish ecchymosis are shown, and medical treatment is required in serious cases. Necrosis of superficial skin resulting from conventional skin stretching procedures occurs and usually requires at least two subsequent treatments. In addition, the conventional skin stretching operation causes nerve injuries such as swelling of the scalp and facial skin, dysesthesia, etc., which bring abnormal sensations to the user even after 3 months of the operation. Compared with the traditional scheme, the skin anti-aging treatment method provided by the invention has the advantages that the adverse reaction on the skin of a user is very little, the skin is only reddened at an accidental injection part, the skin anti-aging treatment method can be naturally eliminated completely within 1-3 days, and no other discomfort is caused.

Compared with the traditional skin-pulling operation, the skin anti-aging treatment method provided by the invention only injects the restoration nutrient in an injection mode, so that no scar is left, and no hair-free area appears.

Moreover, the recovery nutritional agent injected by the skin anti-aging treatment method provided by the invention can be quickly absorbed by the skin, then the self-repairing capability of the skin is activated, a large amount of fibrous tissue hyperplasia is generated, the thickness of the skin tissue is increased, and the skin can quickly achieve the effects of recovering plumpness, compactness and tenderness.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, those skilled in the art will appreciate that; the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.