KR101758203B1 - Method for evaluating flexibility of skin and flexibility improvement degree of cosmetic composition - Google Patents

Abstract

The present invention relates to a skin flexibility and a method for evaluating the degree of flexibility improvement of a cosmetic composition, which can accurately (quantitatively) evaluate (measure) the flexibility of the skin and the degree of improvement of the flexibility of the cosmetic preparation to the skin. The present invention provides a method for evaluating the flexibility of skin and a method for evaluating the degree of flexibility improvement of a cosmetic, which are evaluated based on the average displacement value of the skin when the pressure is applied to the skin.

Description

FIELD OF THE INVENTION The present invention relates to a method of evaluating the flexibility of a skin and a method of evaluating the flexibility of a cosmetic composition,

The present invention relates to a skin flexibility and a method for evaluating the degree of flexibility improvement of a cosmetic composition, which can accurately (quantitatively) evaluate (measure) the flexibility of the skin and the degree of improvement of the flexibility of the cosmetic preparation to the skin.

In general, a cosmetic such as a moisturizer is used for the purpose of improving the flexibility of the skin. The evaluation of the efficacy of the moisturizing agent and the like is evaluated in terms of a sensory aspect such as "moist" or "not pulling" that a person feels after applying the product (moisturizer) to the skin. This sensory aspect is mainly evaluated (panel test) through specialized panelists. However, the evaluation method using the panel test requires a lot of time and cost, and the objectivity is always pointed out.

Efforts to scientifically interpret and objectively evaluate the degree of skin flexibility and feeling of use of cosmetics (such as moisturizers) have been around for a long time, but there are no satisfactory results yet. The most frequently used method is a method of evaluating the effect of the moisturizing agent by measuring the moisture content of the stratum corneum through a corneometer in addition to the panel test.

However, the measurement of moisture alone does not explain much more. In addition, moisture content and skin elasticity are not in complete proportion. The method using water content may be more objective than just panel test, but it is not an objective and accurate evaluation method of skin flexibility.

On the other hand, regarding the measurement of elasticity of the skin, there is a method using a cutometer as a device for measuring the degree of pulling (displacement value) when the sound pressure is applied to the skin and the degree of restoration when the sound pressure is removed.

The skin has a multi-layered structure with different properties. The elasticity and flexibility of each layer are different. For example, a dermis layer having collagen fiber, elastin fiber, reticular fiber and the like has elasticity and flexibility, and a stratum corneum composed of a polygonal, dry and dry keratinocyte is called a desmosome It is tightly connected with the sieve, so flexibility is low and curability is high. Thus, when sound pressure is applied to the skin of a multi-layered structure having different flexibility, the dermal layer with high flexibility is changed first, and the change of the horny layer with high hardness occurs after the change of the dermal layer.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view for explaining a conventional method for evaluating skin elasticity using a cutometer. Fig. 1 is a view showing a displacement (pulling degree) with time when sound pressure is applied to an object such as a balloon through a cutometer Graph.

Referring to FIG. 1, when negative pressure is applied to a test object such as a balloon or skin through a cutometer, the displacement (degree of pulling) increases linearly at an initial stage, and then increases curvilinearly at a certain point of time Ue. After having the maximum displacement (Uf) and then removing the negative pressure, it rapidly decreases and then remains constant.

Conventionally, in evaluating elasticity of skin using a curtometer, when a negative pressure is applied for a certain period of time, the skin displacement value (Ue, 0.1 second) at 0.1 second and the skin displacement The ratio (Ur / Ue) of the difference (Ur) to the skin displacement value at the time of 0.1 second when the sound pressure was removed from the value (Uf) was used as an index of skin elasticity. That is, the value of R5 (= Ur / Ue) calculated by the following formula was used as an evaluation index of skin elasticity.

                    R5 = Ur / Ue

In the above equation,

Ur: maximum skin displacement value (maximum skin displacement value)

             The difference between the displacement value at 0.1 second when the sound pressure is removed,

Ue: is the skin displacement value in 0.1 second time.

However, the above-described conventional elasticity evaluation method reflects the degree of restoration of the skin, which can not be considered as a method of evaluating the flexibility of the skin. In addition, the conventional method for evaluating skin elasticity is a method for evaluating elasticity limited to the dermal layer, and the stratum corneum is not reflected.

As described above, conventionally, it has not been possible to evaluate the flexibility of the skin, in particular, the objective and accurate flexibility of the skin including the stratum corneum.

Accordingly, the present invention provides a novel method for assessing flexibility of a skin, a skin flexibility evaluation method and an evaluation method of degree of flexibility improvement of a cosmetic material that can quantitatively evaluate (measure) the flexibility of the skin objectively and accurately, There is a purpose.

As a more specific object, the object of the present invention is to provide a method for assessing the flexibility of skin and the degree of flexibility improvement of a cosmetic composition, which can objectively and accurately quantitatively (measure) the flexibility of the stratum corneum.

According to an aspect of the present invention,

Provided is a method for evaluating the flexibility of the skin, which evaluates the flexibility of the skin based on the average displacement value of the skin when the pressure is applied to the skin.

According to a concrete embodiment, the skin flexibility evaluation method according to the present invention evaluates the flexibility of the skin based on the average displacement value (Um) defined by the following formula (1).

[Equation 1]

　 Um = ( Ufm +? Utm ) / (n + 1)

In Equation (1) above,

Ufm is the maximum displacement value of the skin when applied to the skin,

Utm is a displacement value in a range of time (t) excluding the maximum displacement value (Ufm)

t is the time from the time point after the pressure application (0 second) to the point when the pressure is removed,

n is the number of times applied to the Utm, and is a natural number of 2 or more.

According to a preferred embodiment, the skin flexibility evaluation method according to the present invention preferably evaluates the flexibility of the skin with a Uvm value defined by the following formula (2).

&Quot; (2) "

Uvm = Um - Uem

In the above equation (2)

Um: The average value of the displacement value of the skin when the pressure is applied to the skin,

Uem: Displacement value at the point where the linearity disappears from the graph of skin displacement value with time.

The Uem of Equation (2) can be used as a skin displacement value at the time when the R ² value obtained through the following equation starts to be less than 0.98.

In the above equation,

X: measurement time (t)

Y: skin displacement value according to measurement time (t)

n: number of measurement times t (number of skin displacement values).

INDUSTRIAL APPLICABILITY The present invention has an effect of providing a new flexibility evaluation method for skin.

Specifically, according to the present invention, it is possible to objectively and accurately quantitatively (measure) the flexibility of the skin and the degree of improvement of the flexibility of the cosmetic preparation to the skin. Further, according to the present invention, it is possible to accurately (quantitatively) evaluate the flexibility of the stratum corneum.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a graph for explaining a conventional method for evaluating skin elasticity using a curitometer, showing displacement with time (degree of pulling). Fig.
Fig. 2 is a graph for explaining an evaluation method according to the present invention, showing a skin displacement (degree of pulling) with time measured by a cutometer when pressure is applied to skin through a cutometer. Fig.

As described above, there has conventionally been a method using a cutomter. However, this method can not be used as an evaluation index for flexibility of the skin as a method for evaluating the elasticity of the skin. In addition, this is an elasticity evaluation method confined to the dermal layer, and can not be used as an objective and accurate flexibility evaluation method for the skin including the stratum corneum.

Accordingly, the present invention relates to a new flexibility evaluation method for skin, which redefines parameters related to skin flexibility evaluation, reflects differences between subjects and measurement sites through a new evaluation index, Flexibility, and flexibility of the cosmetic material to the skin can be objectively and accurately quantitatively evaluated (measured). Further, according to the present invention, it is possible to evaluate (measure) the flexibility of the stratum corneum by allowing the minute changes of the stratum corneum to be well reflected by redefining the parameters.

Hereinafter, the present invention will be described in detail.

The method for evaluating the flexibility of skin according to the present invention (hereinafter referred to as "flexibility evaluation method") evaluates the flexibility of the skin based on the average displacement value of the skin when pressure is applied to the skin. That is, the larger the average displacement value, the better the flexibility of the skin.

At this time, the pressure applied to the skin may be a negative pressure or a vacuum pressure, and the pressure is not particularly limited, but may be in the range of 400 to 450 mbar, for example. The pressure is appropriately selected by the tester (evaluator) within the above range, and can be appropriately selected from among concrete examples, for example, 400 mbar, 420 mbar, 430 mbar, or 450 mbar.

The flexibility evaluation method according to the present invention can be implemented using a measuring instrument capable of measuring the displacement value of the skin when the pressure is applied to the skin. At this time, the measuring instrument can be any element that can measure the displacement value of the skin when the pressure is applied to the skin. For example, the degree of the pulling when the pressure (sound pressure) is applied to the skin (Displacement value), and a cutometer for measuring the degree of restoration when the pressure is removed. In the present invention, the displacement value refers to the length [mm] of the skin that has been stretched at a predetermined time (t), to the extent that the skin is pulled when pressure is applied to the skin through a measuring device such as a cutometer. Specifically, referring to FIG. 2, the x-axis is the measurement time (t, sec) and the y-axis is the skin displacement value (mm) according to each time t.

In evaluating the flexibility of the skin, the present invention is evaluated based on the average of the skin displacement values. Specifically, the average of the skin displacement values measured at an arbitrary time t is evaluated based on the average displacement value Um expressed by the following equation (1).

<Formula 1>

Um  = Σ Ut / N

In the above equation,

Ut is the displacement value at time t,

t is the time from when pressure is applied (0 second) to when pressure is removed,

N is the number of times applied to the Ut, and is a natural number of 2 or more.

At this time, in Equation (1), Ut is at least two or more, and it may preferably include the maximum displacement value. Specifically, at least two of the various displacement values from a certain time after the pressure application (0 second) to the point when the pressure is removed (time) may be selected, but the skin displacement value which is pulled to the maximum may be included.

For example, when pressure is applied to the skin for 3 seconds, t is a time from the time point after the pressure application (0 second) to the point when the pressure is removed, and is in the range between 0 <t? do. If, for example, t = 2.96 seconds, t = 2.97 seconds, t = 2.98 seconds, and t = 2.99 seconds are selected from among these ranges, Ut in Equation 1, the four values corresponding to each time t , And N is 4 as the number of times applied to Ut. In Equation (1),? Ut is the sum of the Ut values corresponding to each time (t) (four sums). Here, N is 4, but in the present invention, N is the number of times applied to Ut as described above, and is at least two natural numbers. The upper limit of N is not particularly limited and is determined according to the judgment of the tester (evaluator). For example, N may be a natural number of 2 to 100, and more specifically, a natural number of 3 to 20. However, the present invention is not limited to this range.

Also, as described above, Ut preferably includes the maximum displacement value. For example, when Ut has a maximum displacement value at t = 3.00 seconds, Ut includes a displacement value at t = 3.00 seconds good. Taking the above example as an example, it is possible to select five values as displacement values (maximum displacement values) at t = 2.96 sec, t = 2.97 sec, t = 2.98 sec and t = 2.99 sec plus t = 3.00 sec desirable. At this time, the number of times N applied to Ut is 5, and in Equation (1),? Ut is the sum of five Ut values including the maximum displacement value.

Further, in the present invention, the time for applying pressure to the skin is not limited, but may be, for example, 0.1 second to 60 seconds. It may be given in the range of 2 seconds to 10 seconds, 2 seconds to 7 seconds, 2 seconds to 5 seconds, or 2 seconds to 3 seconds depending on the subject and the measurement site (forearm, face, etc.).

According to the present invention, after applying pressure to the skin, evaluation based on the average of the displacement values, that is, the average displacement value (Um) according to Equation (1), can be objectively and accurately evaluated. Specifically, evaluation results that reflect the influence of each subject, measurement site, and stratum corneum can be obtained. Preferably, it is evaluated by the method described below.

According to a preferred embodiment, the flexibility evaluation of the skin is preferably evaluated on the basis of the mean displacement value (Um) defined by the following equation (1). As described above, it is preferable that Ut includes the maximum displacement value, which is specified by the following equation (1).

[Equation 1]

　 Um = ( Ufm +? Utm ) / (n + 1)

In Equation (1) above,

Ufm is the maximum displacement value of the skin when applied to the skin,

Utm: Displacement value in the range of time (t) excluding the maximum displacement value (Ufm)

t is the time from the time point after the pressure application (0 second) to the point when the pressure is removed,

n: number of times applied to Utm, which is a natural number of 1 or more

The Um in Equation (1) necessarily considers the maximum displacement value (Ufm) of skin to be pulled in redefining Um in Equation (1). That is, Ut in Equation (1) is defined to include the maximum displacement value (Ufm). In the case of evaluating with the Um value defined by the formula (1), a more accurate evaluation can be achieved. In this case, the Ufm is a displacement value at which the skin is maximally extended. For example, when the pressure is applied to the skin for 3 seconds (0 <t? 3), the displacement value at the time of removing the pressure, But the present invention is not limited thereto.

In the above Equation 1 and Equation 1, N = n + 1. In this case, in the equation (1), n is a natural number of 1 or more, and n may be a natural number of 2 to 100, for example, a natural number of 3 to 20, but is not limited thereto.

According to a more preferred embodiment of the present invention, it is preferable to evaluate the Uvm value defined by the following equation (2).

&Quot; (2) &quot;

Uvm = Um - Uem

In the above equation (2)

Um: The mean displacement value of the skin when pressure is applied to the skin,

Uem: Displacement value at the point where the linearity disappears from the graph of skin displacement value with time.

In this case, Um in Equation (2) is as described above. That is, in Equation (2), Um can be a value calculated by Equation (1) or a value defined by Equation (1), and preferably a value defined by Equation .

In Equation (2), Uem denotes a point at which the linearity disappears in the graph of the skin displacement value with time (x axis: time (t), y axis: skin displacement value) Time). Specifically, the Uem is a displacement value at a time point when the linearity disappears (a point at which the slope of the graph suddenly changes) in a graph appearing on a measuring instrument (such as a curtometer), which is a displacement value corresponding to a boundary between a straight line portion and a curved portion . Referring to FIG. 2, when pressure is applied to the skin through the curtometer, the skin displacement linearly increases at an early stage, and increases curvilinearly at a certain point (Ue). At this time, the displacement value at the time when the linearity starts to disappear (that is, at the time when the curve starts) is the Uem value. Such Uem (the point at which the linearity starts to disappear) may be different for each person, for each measurement site, and for each cosmetic formulation applied to the skin.

The Uem can be calculated by various methods such as a Pearson moment correlation coefficient method (hereinafter referred to as a linear correlation coefficient method) using a differential method or an RSQ function based on the measured data (time, skin displacement value). Although not particularly limited, the Uem can be calculated on the basis of measurement data for all measured skin displacement values from 0.03 seconds (the time at which the actual measured value is recorded at the cutter meter) to the measurement end time (the point at which the pressure is removed) . Preferably, the Uem of Equation (2) may be used as a displacement value at any one time (t) existing between 0.05 second and 0.2 second after applying pressure to the skin. Such a time range (0.05 to 0.2 seconds) takes into account the difference between the formulations of the subject and cosmetics, and when the Uem value in the time range is selected and used, objective and accurate evaluation can be made. That is, the Uem value at which the slope of the cosmetic material changes suddenly varies depending on the person (subject) and cosmetic formulation (cosmetic formulation), and the Uem value corresponding to the time range (0.05 seconds to 0.2 seconds) , The differences between the formulations of the subject and the cosmetic composition are taken into account and an objective and accurate evaluation is achieved. More preferably, the Uem of Equation (2) is preferably used as the displacement value at any one time (t) existing between 0.07 sec and 0.17 sec.

The Uem can be obtained by using a differential method or the like as described above. However, the R ² value is obtained using the linear correlation coefficient method, and the skin displacement value at the time when the R ² value starts to become less than 0.98 (point where the linearity is lost) Can be used. In this case, the linear correlation coefficient R ² value is used by the RSQ function expression shown in <Formula 2> below the calculated value of R ^2.

<Formula 2>

In Equation 2, X is the measurement time t, Y is the skin displacement value according to the measurement time t, and n is the number of measurement times t (= number of skin displacement values). More specifically, when the R ² value was calculated by the linear correlation coefficient method using Equation 2 based on the skin displacement value (preferably, all skin displacement values between 0.07 seconds and 0.17 seconds) with respect to time, , A skin displacement value at a time point when the R ² value starts to become less than 0.98 (a point at which the linearity is lost), for example, a skin displacement corresponding to a point (time) at which the linear correlation coefficient R ² value starts to become 0.97 or less Value can be used.

The Uem in Equation (2) may be an average value within a predetermined time range. For example, when the R ² value is calculated using Equation 2 with respect to the subject's left arm, R ² = 0.97 at t = 0.12 seconds, the average of the time zones including before / after The average of the skin displacement values corresponding to t = 0.11 sec, t = 0.12 sec and t = 0.13 sec may be used as the Uem.

Further, according to a preferred embodiment of the present invention, when evaluating with the Uvm value defined by Equation (2), more objective and accurate evaluation is performed, and skin flexibility can be evaluated quantitatively. At this time, the Uvm in the above equation (2) can be used as an evaluation index for skin flexibility.

In Equation (1), it is preferable to use two or more skin displacement values existing between Uem and Ufm. More specifically, it is preferable that Utm in Equation (1) uses two or more skin displacement values existing between 2.0 seconds and the pressure removal time (Ufm) after applying pressure to the skin. For example, Utm in Equation (1) can use two or more skin displacement values existing between a displacement value of 2.0 seconds and a displacement value of 10.0 seconds. Further, more preferably, Utm can use a value close to Ufm. For example, when a pressure is applied to the skin for 3 seconds, for example, if the Uem value is measured at 0.12 seconds and has a maximum value (Ufm) at 3 seconds, the Utm is present between 0.12 seconds and 3 seconds It is preferable to use a displacement value in a time zone close to Ufm (3 seconds). For example, if four utm are used, let t = 2.96, t = 2.97, and t = 2.97, respectively, be the skin displacement values between 0.12 and 3 seconds, 2.98 and t = 2.99 are preferred.

INDUSTRIAL APPLICABILITY According to the present invention described above, it is possible to evaluate the flexibility of the skin objectively as a new flexibility evaluation method. In addition, the mean displacement value (Um) is applied to reflect the differences in subjects, differences in measurement sites, and impacts on the stratum corneum, so that objective and accurate evaluation is possible. Specifically, the displacement value is redefined as an average displacement value (Um) as shown in Equation (1) and Equation (1), taking into account the influence of the horny layer and the measurement site.

Particularly, according to the present invention, the evaluation index is redefined by the Uvm of Equation (2) taking into account the subject-specific difference, the difference depending on the measurement site, the difference in cosmetic formulation applied to the skin, and the effect of the stratum corneum, Evaluation is made, and evaluation results that reflect the flexibility of the stratum corneum, among other things, can be obtained. Thus, accurate and quantitative evaluation of the stratum corneum as well as the skin including the stratum corneum (horny layer + dermal layer) is possible. At this time, it is evaluated that the higher the Uvm value calculated according to Equation (2), the better the flexibility. In addition, according to the present invention, it is possible to quantitatively evaluate the criterion of flexibility evaluation based on the Uvm value calculated according to Equation (2). For example, if the Uvm value is 0.09 mm or more, flexibility is good, and if the Uvm value is less than 0.09 mm, flexibility is poor, and a standard of flexibility evaluation can be prepared according to a certain range of the Uvm value.

On the other hand, the flexibility evaluation method of the present invention described above can be evaluated for the skin to which the cosmetic is applied.

Specifically, the cosmetic is first applied to the skin, and then pressure is applied to the skin to which the cosmetic is applied to obtain an average displacement value (Um) of the skin to be pulled, preferably an average displacement value (Um) The flexibility of the skin in a state in which the cosmetic is applied can be evaluated. More preferably, the Uvm value defined by the above-mentioned formula (2) can be used as an evaluation index to evaluate the flexibility of the skin on the skin in a state in which the cosmetic is applied.

According to a preferred embodiment, it is preferable to evaluate (measure) after 0.1 to 6 hours so that the evaluation of the correct flexibility of the skin in the state where the cosmetic is applied is made. Specifically, it is preferable that the cosmetic is applied to the skin, and the skin is allowed to stand for 0.1 to 6 hours, and then the skin is evaluated (measured) by applying pressure to the skin using a measuring instrument (such as a curtometer). At this time, if the standing time is less than 0.1 hour, the absorbency of the cosmetic material may be insignificant, and if the standing time exceeds 6 hours, the effect for improving the flexibility of the cosmetic material may be reduced (weakened)

In addition, the method for evaluating the degree of flexibility improvement (hereinafter referred to as " degree of improvement evaluation ") of the cosmetic according to the present invention applies the flexibility evaluation method of the present invention as described above.

Specifically, the improvement evaluation method according to the present invention is a method for improving the flexibility of a cosmetic based on the average displacement value (Um) of the skin pulled when pressure is applied to the skin to which the cosmetic is applied, The degree of improvement is evaluated. At this time, it is evaluated that the higher the average displacement value (Um) is, the better the flexibility of the cosmetic material is. Preferably, the improvement degree of flexibility of the cosmetic material is evaluated based on the average displacement value (Um) defined by Equation (1) as described above, and more preferably, the Uvm value defined by Equation (2) , And the flexibility improvement of cosmetics is evaluated. Based on the evaluation result of the flexibility improvement degree, the effectiveness of the cosmetic composition used in the evaluation can be evaluated. At this time, the degree of improvement in flexibility can be evaluated for raw materials, compositions, cosmetic formulations, and the like, which are effective for improving flexibility.

Further, in evaluating the degree of improvement of flexibility as described above, the cosmetic is applied to the skin as described above so as to evaluate the degree of improvement in the degree of flexibility of the skin when the cosmetic is applied, and then the skin is allowed to stand for 0.1 to 6 hours It is recommended to evaluate (measure) the pressure by applying pressure.

In the present invention, the above cosmetic material is not particularly limited, and any cosmetic material that is applied to the skin is included herein. The cosmetic may be, for example, a formulation containing a raw material (or a composition) for moisturizing, preventing wrinkles, whitening, cutting off wrinkles, etc. The formulation is not particularly limited, For example.

Hereinafter, embodiments of the present invention will be exemplified. The following examples are provided to illustrate the present invention in order to facilitate understanding of the present invention, and thus the technical scope of the present invention is not limited thereto. The following examples are illustrative examples of t-tests performed to verify the objectivity and accuracy of the evaluation method (skin flexibility evaluation according to Uvm values) according to the present invention.

[Example]

In order to confirm the improvement of the flexibility of the skin, it was experimented with the following moisturizer.

(B) glycerin-free formulation (0% by weight of glycerin), c) glycerin (glycerin), and (c) glycerin glycerin) (20 wt% of glycerin based on the total weight of the moisturizer). Glycerin is generally used as a raw material that has the greatest influence on the water content of the stratum corneum and glycerin is used as an indicator raw material for evaluating the flexibility of the stratum corneum because it is directly involved in flexibility.

20 ~ 30 healthy 3 male volunteers were soaked with soap and then adapted for 20 minutes or more in a constant temperature chamber (temperature 22 ± 2 ℃, relative humidity 40 ± 2%) to stabilize the skin before starting the test. The area (3 x 3 cm ² ) where the formulation was to be applied was indicated on the chest (5 cm inside the wrist and brachium) and the cutometer (MPA580 instrument) was measured 0.1 to 6 hours before application and after application under the following conditions. The applied formulations were applied to the skin at a rate of ² ul / cm ² in an o / w formulation containing 0% glycerin and 20% glycerin by weight.

The measurement mode of the cutometer is mode 1 (to remove and remove the sound pressure for a certain period of time), the pressure is 450 mbar, the probe diameter is 2 mm, the sound pressure application time is 3 seconds And the average value of each measurement value was used. At this time, in the measurement mode 1 of the cutometer, the Uvm value is determined according to Equation 2 (Uvm = Um - Uem), and Uem and Um are calculated as follows.

The shape of the graph is divided into a linearly increasing part and a curving increasing part. At this time, the Uem calculated the skin displacement value at the time when the measurement was started (0.03s) based on the change of the graph, instead of the fixed time of 0.1s, from when the linearity disappeared. The Uem values at the point where the linearity disappeared varied from one formulation to another and between 0.10 s and 0.15 s. Uem calculates the linear correlation coefficient R ² by using Equation 2 at the above time range (0.10 s to 0.15 s), and calculates an optimal value (skin displacement value with R ² value of 0.97, t = 0.13) Respectively. At this time, Uem is the value (R ² (T = 0.12, t = 0.13, and t = 0.14) were used as the mean values of the three values in the pre / post-time period including

Further, Um is the average of two values before the maximum skin displacement value Ufm and the maximum skin displacement value Ufm, and using the total three average values as Um, the above equation 2 (Uvm = Um - Uem) were calculated.

In order to verify the Uvm value calculated as above, it was confirmed whether the results before and after coating had statistical significance, and the influence of moisture was more clearly confirmed in comparison with the conventional evaluation method using moisture content. Specifically, the Uvm value after application (0 hours), after application (0.1 hours to 6 hours) in which a) undoped b) 0% by weight of glycerin, and c) 20% by weight of glycerin The results of the t-test were verified to be significant as shown in the table below. Table 1 below shows t-test results before application (0 hours / p-value), and Table 2 below shows t-test results after application (0.1 ~ 6 hours / p-value).

<Results of t-test before application (0 hours)> 0 hours / p-value b) 0% by weight of glycerin c) 20% by weight of glycerin Conventional a) Balloons 0.703344 0.765415 b) 0% by weight of glycerin - 0.753874 Invention
(Uvm) a) Balloons 0.778601 0.346723 b) 0% by weight of glycerin - 0.604752

<T-test result after application (0.1 to 6 hours)> 0.1 to 6 hours / p-value b) 0% by weight of glycerin c) 20% by weight of glycerin Conventional a) Balloons 0.212021 0.061778 b) 0% by weight of glycerin - 0.036338 Invention
(Uvm) a) Balloons 0.857585 0.009797 b) 0% by weight of glycerin - 0.000279

As shown in [Table 1] and [Table 2] above,

1) Statistically confirmed that there was no difference in the Uvm values between a) undiluted, b) 0% by weight of glycerin, and c) 20% by weight of glycerin,

2) In the results after the formulation application, there is no difference in the Uvm value between the a) undiluted capsule and b) 0% by weight of glycerin in the short term (0.1 to 6 hours), and a Uvm value between the a) undiluted capsule and c) There was a significant difference, and it was confirmed that there was a significant difference in the Uvm value between b) 0% by weight of glycerin and 20% by weight of c) glycerin.

Also, it was confirmed that the flexibility of the stratum corneum was increased by the c) glycerin 20% by weight formulation, and the Uvm index according to the present invention was more clearly affected by the moisture as compared with the conventional method. In other words, as shown in [Table 2], in the analysis through the t-test, it was found that the Uvm index according to the present invention is significantly different from the conventional method.

As a result of statistical analysis by t-test, Uvm used as an evaluation index in the present invention was found to be statistically in agreement with the flexibility measurement result through glycerin.

Claims (22)

delete delete delete delete delete A skin flexibility evaluation method for evaluating skin flexibility based on an average displacement value of a skin when a pressure is applied to the skin, the skin flexibility evaluation method comprising the steps of: calculating a Uvm value The method of evaluating skin flexibility according to claim 1,
&Quot; (2) &quot;
Uvm = Um - Uem
In the above equation (2), Um is a value defined by the following equation (1)
[Equation 1]
Um = (Ufm +? Utm) / (n + 1)
In the above equation (1)
Ufm is the maximum displacement value of the skin when applied to the skin,
Utm is a displacement value in a range of time (t) excluding the maximum displacement value (Ufm)
t is the time from the time point after the pressure application (0 second) to the point when the pressure is removed,
n is the number of times applied to the Utm and is a natural number of 1 or more,
In Equation (2), Uem is a skin displacement value at the time when the R ² value obtained through the following equation starts to become less than 0.98

In the above equation,
X: measurement time (t)
Y: skin displacement value according to measurement time (t)
n: number of measurement times t (number of skin displacement values).
The method according to claim 6,
Wherein Utm in Equation (1) is at least two skin displacement values existing between a displacement value of 2.0 seconds and a displacement value of 10.0 seconds after applying pressure to the skin.
The method according to claim 6,
Wherein Utm in Equation (1) is at least two skin displacement values existing between Uem and Ufm.
The method according to claim 6,
The skin flexibility evaluation method is characterized by using a cutometer for measuring a degree of pulling of the skin when pressure is applied to the skin and a degree of restoration when the pressure is removed.
The method according to claim 6,
Wherein said skin flexibility evaluation method is a method for assessing the flexibility of a stratum corneum.
The method according to claim 6,
Wherein the skin is coated with a cosmetic material.
The method according to claim 6,
The skin flexibility evaluation method is characterized by applying a cosmetic composition to the skin and then applying pressure after 0.1 to 6 hours to evaluate the skin flexibility.
delete delete delete delete delete 1. A method for evaluating the degree of flexibility improvement of a cosmetic material for evaluating the degree of improvement in flexibility of a cosmetic material to a skin based on an average displacement value of the skin when applying pressure to the skin to which the cosmetic material is applied after applying the cosmetic material to the skin, Wherein the degree of flexibility improvement of the cosmetic composition is evaluated by a Uvm value defined by the following formula (2): &lt; EMI ID =
&Quot; (2) &quot;
Uvm = Um - Uem
In the above equation (2), Um is a value defined by the following equation (1)
[Equation 1]
Um = (Ufm +? Utm) / (n + 1)
In the above equation (1)
Ufm is the maximum displacement value of the skin when applied to the skin,
Utm is a displacement value in a range of time (t) excluding the maximum displacement value (Ufm)
t is the time from the time point after the pressure application (0 second) to the point when the pressure is removed,
n is the number of times applied to the Utm and is a natural number of 1 or more,
In Equation (2), Uem is the skin displacement value at the time when the R ² value obtained through the following equation starts to become less than 0.98,

In the above equation,
X: measurement time (t)
Y: skin displacement value according to measurement time (t)
n: number of measurement times t (number of skin displacement values).
19. The method of claim 18,
Wherein Utm in Equation (1) is at least two skin displacement values existing between a displacement value of 2.0 seconds and a displacement value of 10.0 seconds after pressure is applied to the skin.
19. The method of claim 18,
Wherein the Utm in Equation (1) is at least two skin displacement values existing between Uem and Ufm.
19. The method of claim 18,
The flexibility improvement degree evaluation method of the above-mentioned cosmetics is characterized by using a cutometer which measures the degree of pulling of the skin when the pressure is applied to the skin and the degree of restoration when the pressure is removed, Assessment Methods.
19. The method of claim 18,
The method for evaluating the degree of flexibility improvement of a cosmetic composition according to claim 1, wherein the cosmetic is applied to the skin after 0.1 to 6 hours.

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