FR2658713A1 - Method for analysis of the cutaneous relief, particularly in the case of abnormalities or variations thereof - Google Patents

Abstract

The present invention relates to a method for analysis of the cutaneous relief, using profile measurement and roughness measurement 2D, 3D and image analysis. The object of the invention is to provide a method by means of which it is possible to define, with precision, the cutaneous relief of certain areas of the human body, particularly in the case of abnormality or variation thereof, which method does not require any complementary clinical or paraclinical examinations and permits a diagnosis to be established on the efficacy of a cosmetic treatment to be evaluated. This object is achieved by means of a non-invasive method, characterised in that it consists in taking an impression of the cutaneous relief in a chosen zone, studying the latter by profile measurement, roughness measurement and image analysis, processing the information obtained, and determining the parameters which define the condition of the cutaneous relief in the said chosen zone. The invention applies more particularly to the analysis of the phenomenon called "orange skin".

Description

PROCESS FOR ANALYZING CUTANE RELIEF, IN PARTICULAR
IN CASE OF ANOMALIES OR VARIATIONS THEREOF.

 The present invention relates to the analysis of cutaneous relief using physical measurements and more particularly the analysis of the phenomenon of "orange peel" related to cellulite. It also relates to the aesthetic diagnosis of skin surface abnormalities and the evaluation of the effectiveness of an aesthetic treatment.

 The skin has been studied for many years for a variety of purposes. At the same time, the importance of aesthetics has increased considerably in recent years as a social phenomenon. Thus, all that relates to aesthetics is no longer considered secondary, but on the contrary is a kind of necessary element to the balance of the human being in society or at least a large proportion individuals. Consequently, in order to be able to restore or improve the esthetics of certain regions of the human body, it is interesting to be able to analyze the skin coating, in particular in the case of localized lipodystrophies such as "orange peel".

 Until now, the skin condition of a person was apprehended mainly by complementary clinical and paraclinical examinations. The clinical examination is carried out by the esthetician doctor by the only use of his senses (sight, touch). Para-clinical examinations consist of invasive biological and histological examinations as well as conventional radiological examinations such as echotomography or xerography.

 Unfortunately, the clinical examination is quite subjective and not enough on its own. The paraclinical exams, meanwhile, give us only the hidden face of the iceberg. Indeed, they allow us to analyze the skin only from an internal point of view to the organism but in no case the external appearance of this one, which one also denominates cutaneous relief, can not be defined and analyzed in a rigorous and certain way.

 Moreover, when an aesthetic treatment is performed on particular regions of the body of a subject, only the clinic currently allows to control the effectiveness of this treatment. However, this simple review is not enough. In addition, statistical studies can be used to evaluate the effectiveness of a given aesthetic treatment.

Unfortunately, these studies must cover many subjects (at least a hundred) to be reliable and are thus very long to obtain especially given the duration of this type of treatment. An objective measure is missing which allows to quickly observe the result acquired or not acquired at the surface of the skin. Thus, if we consider the phenomenon of "orange peel", the esthetician doctor does not have sufficient means to measure and appreciate the evolution of this phenomenon over time.

 The present invention overcomes the aforementioned drawbacks and shortcomings by proposing a method of non-invasive analysis of the cutaneous relief.

 The objective of the present invention is to provide reliable measurements for accurately defining the cutaneous relief of certain regions of the human body, in particular in the case of localized lipodystrophies.

 A second objective is to provide a method of analysis that is sufficient on its own, that is to say that does not require additional clinical or paraclinical examinations.

 A third objective is to provide a method for objectivizing the acquired or un-acquired results as a result of an aesthetic treatment and thus to verify its effectiveness without the need for a statistical study.

 A last objective is to provide a particularly useful method of analysis for the "orange peel" phenomenon, making it possible to monitor and compare the evolution of this phenomenon.

These objectives as well as others which will appear later are achieved by means of a non-invasive surface relief analysis method using two or three dimensional profilometry and image analysis, characterized in that 'it consists of
a) to identify the impression of the cutaneous relief in a chosen zone of the cutaneous coating,
b) performing physical measurements from said fingerprint by profilometry and 2D roughness, 3D and image analysis,
c) process the information obtained
d) determining the parameters defining the condition of the cutaneous relief in said chosen zone.

 According to other characteristics of the invention, the impression is raised using a material advantageously belonging to the family of silicones.

 The molding is carried out by introducing said material into a small frame applied to the area of the skin coating that is to be analyzed.

 The relief of this area is then defined by processing measurements by profilometry and 2D and 3D rugosimetry as well as by image analysis performed on the footprint obtained previously, normalized quantization parameters having been determined. It is thus possible to produce three-dimensional representations of the cutaneous relief.

 The method according to the invention makes it possible to establish an aesthetic diagnosis as to the existence of an abnormality of the skin coating such as localized lipodystrophy and the extent to which it manifests itself. It also makes it possible to evaluate the effectiveness of an aesthetic treatment during application or after application.

The features and advantages of the invention will emerge more clearly on reading the following description of a preferred embodiment of the invention given by way of non-limiting example and the appended drawings in which:
FIG. 1 is a three-dimensional representation of a normal skin coating,
FIGS. 2a and 2b are three-dimensional representations of the cutaneous relief at the level of the region of the gluteal fold of the right thigh of a woman, presenting the phenomenon of "orange peel", respectively before and after treatment,
FIGS. 3a and 3b are three-dimensional representations of the cutaneous relief at the level of the trochanteric region of the left thigh of a woman, exhibiting the phenomenon of "orange peel", respectively before and after treatment.

 The preferred embodiment given below is described in the case of a subject exhibiting the phenomenon of "orange peel".

It is recalled here that "cellulites" are defined by two clinical symptoms
- a visual objective symptom: orange peel phenomenon,
- a subjective tactile symptom: sensitivity to the "pinching of the skin fold" at the so-called cellulite area.

 This is the phenomenon of orange peel that is vulgarly called cellulite.

 The method for analyzing the cutaneous relief according to the invention consists, first of all, in identifying the impression of the cutaneous relief of a particular region of the human body.

 To do this, we apply a frame in the chosen area in which we introduce a fluid material capable of accurately reproducing the cutaneous relief. This frame preferably has a self-adhesive face to facilitate application. Its dimensions are chosen by those skilled in the art so as to obtain a print suitable and sufficient to be able to perform the following physical measurements necessary for the definition of the cutaneous relief.

Thus, the frame can be square in shape and have internal and external dimensions respectively 5 x 5 cm and 6 x 6 cm and a thickness of 3 mm.

 The fluid material used may be any precision molding material. A silicone material mixed with an activator is preferably employed. Mention may be made, for example, of low viscosity xantoprene, a dental paste marketed under the name "ADA Ne19, type II" by the BAYER Company.

 When it is desired to objectify the evolution of the "orange peel" phenomenon for example, and to evaluate the effectiveness of an aesthetic treatment, it suffices to make impressions before and after treatment or at predetermined intervals in progress. treatment.

 In the presence of the "orange peel" phenomenon, the skin coating reveals a turbulent relief that consists of a sort of succession of folds oriented in various directions. It is therefore interesting, in order to be able to analyze this relief, to establish three-dimensional representations characteristic of the state of the skin coating.

 The analysis of the impression obtained previously and consequently of the cutaneous relief, is done by processing the information coming from two methods essentially: profilometry and image analysis; these physical measurement methods have not been used in this area so far.

 For profilometry, measurements are made using a non-contact optical sensor whose laser detector follows local altitude variations by translation at constant speed. It translates these variations into an analog signal which is then digitized. Thus, the two-dimensional profilometry (2D) represents the cut of the cutaneous coating by a plane perpendicular to it.

However, given the anisotropic nature of the skin coating, it is interesting to be able to move to a three-dimensional analysis (3D: Rugosimetry).

For this, simply move the laser detector in the plane but also vertically. For the analysis of the "orange peel" phenomenon, the operating conditions can be as follows:
- scanned area: 5.12 x 5.12 mm (256 x 256 measuring points 20 micrometers apart),
- analyzed surface: negative replica of xantoprene,
measurement time of each of the replicas 10 to 11 minutes,
- exploitation spot area: 6 to 10 micrometers; wavelength of the near infrared laser beam.

For image analysis, the sensing element is a television camera working in a closed circuit. The resulting image is digitized by a converter to form a 256 x 256 x 64-level matrix that can be used as an input signal to an IBM PC or AT type computer. Thus, the detection system used makes it possible to obtain, in a very short time, of the order of 25 seconds, an image that can be processed quickly by software. For this purpose, all the operators have been written in machine language of the 8086 (or 80286) processor and perform the following operations
- Image filtering and pleat reinforcement
- compaction of the image
- skeletonization of shapes
- statistical treatment.

 The operating conditions for physical measurements depend on the type of anomaly or variation studied on a given individual.

The most interesting quantification parameters for defining the cutaneous relief are as follows
- Ra or arithmetic mean: this parameter is insensitive to the shape of the surface defects but takes into account any variation with respect to the average line of the surface taken as a reference.

- Rpm: This parameter represents the average of the "peaks" farthest from the mean line, the average over a number of "base lengths"
- Rtm: This parameter represents the average of the greatest peak / valley distances measured on each of the base lengths.

 - Rv: This parameter represents the largest valley detected below the mean line.

 - Rt: This parameter represents the largest difference in altitude between the highest peak and the deepest fold background.

 - Rmax almost the same definition as Rt, can be ignored.

 - Rp: This parameter gives the distance farthest from the mean line and is therefore quite close to Rpm. This value can therefore not be exploited.

 All of these parameters characterize the distribution in height of the points of the skin coating.

A statistical study of the distribution of the points of the surface makes it possible to obtain another series of parameters
- Rq: This parameter is the standard deviation of the height distribution.

 - Rsk or Sk: this parameter qualifies the shape of the distribution of the points of the surface. In the case of the skin coating, Rsk is negative and the surface is therefore in the form of trays furrowed by valleys.

 - Rek or Ek: this parameter quantifies the symmetry of the release function.

In addition to the two sets of parameters mentioned above, two other parameters are interesting
- long% or developed length: this parameter represents the actual length of a surface profile expressed as a percentage of its projected length on the mean plane of the surface.

 - Sm or spacing parameter: this parameter gives the average value of the distance separating two successive bumps or hollows of the profile, counted at the level of the average line of the profile.

 The value of these parameters varies from one type of skin to another and therefore from one individual to another.

They make it possible to produce three-dimensional representations such as those appended in FIGS. 1, 2 and 3 corresponding to the examples given below.

The analysis method according to the invention makes it possible to characterize the cutaneous relief of a subject at most by five parameters, namely Ra, Rt or Rtm, long% and
Sm. It leads to a measurable and exploitable physical result.

 Thus, we can highlight in a subject, if there is a phenomenon of "orange peel" or not and to what degree it manifests itself. For this purpose, it suffices to define the values of the five parameters for the normal skin coating of a given person at a time t = 0, that is to say by analyzing an impression taken in a reference zone not affected by lipodystrophy. The values obtained in an affected area of the same person are then compared at a time t = 1 with respect to this reference: an increase in these values (t = 1) reveals an accentuation of the cutaneous relief and therefore the existence of the phenomenon of "orange peel". Values close to those corresponding to a normal skin coating taken as reference (t = 0) makes it possible to note the non-existence of the phenomenon or its disappearance as a result of a treatment. It is the observation of the difference between obtained values and reference values that allows the aesthetic diagnosis.

 The analysis method according to the invention also makes it possible to evaluate the effectiveness of an aesthetic treatment. For this purpose, the values of the five parameters are determined for a reference, that is to say a part of the skin surface considered as normal, then for a zone reached before treatment at a time t = 1, and finally for the same zone, after treatment at a time t = 2. By comparison, we can see the results acquired or not acquired by the treatment applied, for example the regression or not the phenomenon of "orange peel". If the values obtained after treatment (t = 2) become close to the values for the reference (t = 0), the treatment can be judged effective. In the opposite case, the values obtained after treatment (t = 2) are rather close to the values before treatment (t = 1). In other words, the treatment tested is all the more effective as the difference between the values obtained before treatment (t = 1) and after treatment (t = 2) is reduced and that the difference between the values obtained after treatment (t = 2) and for the reference (t = 0) is small.

 It is also possible to observe the evolution of this phenomenon during treatment by performing and analyzing fingerprints at different stages, for example regularly spaced in time.

 The method for analyzing the cutaneous relief according to the invention has many advantages; indeed, it is non-invasive, perfectly painless, fast and simple.

 It is a safe and reliable means of investigation. In addition, the physical parameters of study of this process are standardized. Therefore, this method is particularly interesting for its high fidelity of reproduction.

 Moreover, the method according to the invention is sufficient on its own to accurately assess the condition of the cutaneous relief of a subject. It thus makes it possible to avoid the invasive paraclinical examinations practiced so far, which are much less reliable and precise and moreover, unjustified in terms of aesthetics.

 Finally, the physical methods used are part of the arsenal of "medical imaging" and do not suffer from any criticism, being based on the objectification of the clinic.

 In addition, they are interpretable by anyone not necessarily belonging to the medical profession such as a beautician. This point is very advantageous because the beautician represents a determining personality in the care of abnormalities or variations of the skin coating such as localized lipodystrophies.

 The method according to the invention makes it possible to evaluate the effectiveness of any aesthetic treatment including the skin, by a study on a single case. There is no need for a long and tedious statistical study of many cases, as before.

EXAMPLE
We analyze the cutaneous relief of a middle-aged woman with localized lipodystrophy with the syndrome "cellulitic", namely the phenomenon of "orange peel", at the level of the lower limbs which are commonly known as "panties of horse".

 More specifically, a so-called normal skin coating area is first analyzed for reference. The cutaneous relief is then analyzed in areas presenting the "orange peel" phenomenon before and after treatment.

REFERENCE
A frame of internal dimensions 5 x 5 cm and external dimensions 6 x 6 cm with a thickness of 3 mm is applied to an area of the forearm. Xantoprene "ADA N019 type II" is introduced. This gives the impression of the cutaneous relief in this zone.

 This impression is subjected to a 2D and 3D profilometry and rougosimetry study and image analysis from which are extracted the various parameters (time t = 0).

Table 1 below gives the values obtained from different angles and corresponds to the three-dimensional representation given in Figure 1. TABLE I

prafil <SEP> n <SEP> I <SEP> Ra <SEP> (m) <SEP> I <SEP> Rt <SEP> (m) <SEP> I <SEP> Rmax <SEP> (m) <SEP> I <SEP> Rtm <SEP> (m) <SEP> I <SEP> Rv <SEP> (m) <SEP> I <SEP> Rpm <SEP> (
<tb><SEP> 1 <SEP> I <SEP> 7.99 <SEP> I <SEP> 46.15 <SEP> I <SEP> 43.53 <SEP> I <SEP> 34.13 <SEP> I <SEP> 23.69 <SEP> I <SEP> 16.67
<tb><SEP> 2 <SEP> I <SEP> 7.67 <SEP> I <SEP> 49.34 <SEP> I <SEP> 49.34 <SEP> I <SEP> 34.69 <SEP> I <SEP> 26.44 <SEP> I <SEP> 16.05
<tb><SEP> 3 <SEP> I <SEP> 7.83 <SEP> I <SEP> 56.65 <SEP> I <SEP> 56.65 <SEP> I <SEP> 34.76 <SEP> I <SEP> 31.44 <SEP> I <SEP> 15.58
<tb><SEP> 4 <SEP> I <SEP> 8.59 <SEP> I <SEP> 59.22 <SEP> I <SEP> 59.22 <SEP> I <SEP> 37.07 <SEP> I <SEP> 31.57 <SEP> I <SEP> 17.22
<tb><SEP> 5 <SEP> I <SEP> 9.32 <SEP> I <SEP> 56.51 <SEP> I <SEP> 56.51 <SEP> I <SEP> 39.05 <SEP> I <SEP> 30.42 <SEP> I <SEP> 17.69
<Tb>

average <SEP> I <SEP> 0.20 <SEP> I <SEP> 53.57 <SEP> I <SEP> 53.05 <SEP> I <SEP> 35.94 <SEP> I <SEP> 28.65 <SEP> I <SEP> 16.64
<tb><SEP> I <SEP> I <SEP> I <SEP> I <SEP> I <SEP> I
<tb><SEP> I <SEP> .6 <SEP> I <SEP> 5.78 <SEP> I <SEP> 5.78 <SEP> I <SEP> 1.85 <SEP> I <SEP> 3.67 <SEP> I <SEP > .75
<Tb>

profile <SEP> n <SEP> I <SEP> Rq <SEP> (m) <SEP> I <SE> SM <SEP> (m) <SEP> I <SEP> long <SEP> (Z) <SEP> I <SEP> Rp <SEP> (m) <SEP> I <SEP> EX <SEP> I <SEP> SK
<tb><SEP> 1 <SEP> I <SEP> 10.11 <SEP> I <SEP> 334.54 <SEP> I <SEP> 102.12 <SEP> I <SEP> 24.7 <SEP> I <SEW> 2.76 <SEP> I <SEP> -.22
<tb><SEP> 2 <SEP> I <SEP> 9.93 <SEP> I <SEP> 334.54 <SEP> I <SEP> 102.06 <SEP> I <SEP> 22.89 <SEP> I <SEP> 3.07 <SEP> I <SEP> -.34
<tb><SEP> 3 <SEP> I <SEP> 9.83 <SEP> I <SEP> 386.25 <SEP> I <SEP> 101.86 <SEP> I <SEP> 25.51 <SEP> I <SEP> 3.18 <SEP> I <SEP> -.11
<tb><SEP> 4 <SEP> I <SEP> 10.6 <SEP> I <SEP> 438.57 <SEP> I <SEP> 101.91 <SEP> I <SEP> 27.65 <SEP> I <SEP> 3.01 <SEP> I <SEP> -.01
<tb><SEP> 5 <SEP> I <SEP> 11.47 <SEP> I <SEP> 378.75 <SEP> I <SEP> 102.02 <SEP> I <SEP> 26.08 <SEP> I <SEP> 2.7 <SEP> I <SEP> -.14
<tb> average <SEP> I <SEP> 10.39 <SEP> I <SEP> 374.53 <SEP> I <SEP> 102 <SEP> I <SEP> 25.37 <SEP> I <SEP> 2.94 <SEP> I <SEP > -.16
<tb><SEP> I <SEP> I <SEP> I <SEP> I <SEP> I <SEP> I
<tb> range <SEP> type <SEP> I <SEP> .6 <SEP> I <SEP> 8.26 <SEP> I <SEP> .1 <SEP> I <SEP> 14.98 <SEP> I <SEP>. 18 <SEP> I <SEP> .11
<Tb>
EXAMPLE I
The cutaneous relief is analyzed at the region of the gluteal sulcus of the right thigh from impressions made as described above before treatment (time t = 1) and after treatment (time t = 2).

Tables IIa and IIb respectively give the values of the parameters before and after aesthetic treatment and correspond to the three-dimensional representations given in FIGS.
IIa and IIb.

TABLE IIa

profile <SEP> n <SEP> I <SEP> Ra <SEP> (m) <SEP> I <SEP> Rt <SEP> (m) <SEP> I <SEP> Rmax <SEP> (m) <SEP> I <SEP> Rtm <SEP> (m) <SEP> I <SEP> Rv <SEP> (m) <SEP> I <SEP> Rpm <SEP> (1
<tb><SEP> 1 <SEP> I <SEP> 12.61 <SEP> I <SEP> 68.37 <SEP> I <SEP> 57.89 <SEP> I <SEP> 49.91 <SEP> I <SEP> 35.85 <SEP> I <SEP> 21.64
<tb><SEP> 2 <SEP> I <SEP> 13.23 <SEP> I <SEP> 75.27 <SEP> I <SEP> 61.88 <SEP> I <SEP> 53.57 <SEP> I <SEP> 38.04 <SEP> I <SEP> 23.31
<tb><SEP> 3 <SEP> I <SEP> 13.84 <SEP> I <SEP> 02.2 <SEP> I <SEP> 68.05 <SEP> I <SEP> 58.43 <SEP> I <SEP> 41.79 <SEP> I <SEP> 25.6
<tb><SEP> 4 <SEP> I <SEP> 14.34 <SEP> I <SEP> 86.59 <SEP> I <SEP> 72.33 <SEP> I <SEP> 61.39 <SEP> I <SEP> 43.84 <SEP> I <SEP> 28.25
<tb><SEP> 5 <SEP> I <SEP> 14.61 <SEP> I <SEP> 84.12 <SEP> I <SEP> 71.63 <SEP> I <SEP> 61.85 <SEP> I <SEP> 42.27 <SEP> I <SEP> 29.38
<tb> median <SEP> I <SEP> 13.72 <SEP> I <SEP> 79.31 <SEP> I <SEP> 66.35 <SEP> I <SEP> 57.03 <SEP> I <SEP> 40.36 <SEP> I <SEP > 25.64
<tb><SEP> I <SEP> I <SEP> I <SEP> I <SEP> I <SEP> I
<tb> deviation <SEP> type <SEP> I <SEP> .73 <SEP> I <SEP> 6.64 <SEP> I <SEP> 5.62 <SEP> I <SEP> 4.62 <SEP> I <SEP> 2.95 <SEP> I <SEP> 2.9
<tb> time t = 1

profile <SEP> n <SEP> I <SEP> Rq <SEP> (m) <SEP> I <SE> SM <SEP> (m) <SEP> I <SEP> long <SEP> (%) <SEP> I <SEP> EK <SEP> I <SEP> SK
<tb><SEP> 1 <SEP> I <SEP> 15.11 <SEP> I <SEP> 349.09 <SEP> I <SEP> 104.48 <SEP> I <SEK> 2.41 <SEP> I <SEP> -.41
<tb><SEP> 2 <SEP> I <SEP> 15.87 <SEP> I <SEP> 412.22 <SEP> I <SEP> 104.51 <SEP> I <SEP> 2.54 <SEP> I <SEP> -.33
<tb><SEP> 3 <SEP> I <SEP> 16.7 <SEP> I <SEP> 412.22 <SEP> I <SE> 104.66 <SEP> I <SEP> 2.61 <SEP> I <SEP> -.24
<tb><SEP> 4 <SEP> I <SEP> 17.4 <SEP> I <SEP> 414.44 <SEP> I <SEP> 104.73 <SEP> I <SEP> 2.59 <SEP> I <SEP> -.12
<tb><SEP> 5 <SEP> I <SEP> 17.85 <SEP> I <SEP> 377 <SEP> I <SEP> 104.94 <SEP> I <SEP> 2.57 <SEP> I <SEP> -.08
<tb> average <SEP> I <SEP> 16.58 <SEP> I <SEP> 39.299 <SEP> I <SE> 104.66 <SEP> I <SEP> 2.54 <SEP> I <SEP> -.24
<tb> deviation <SEP> type <SEP> I <SEP> I <SEP> I <SEP> I <SEP> I
<tb><SEP> I <SEP> .99 <SEP> I <SEP> 5.56 <SEP> I <SEP> .16 <SEP> I <SEP> 0.7 <SEP> I <SEP> .12
<tb> TABLE IIb

profile <SEP> n <SEP> I <SEP> Ra <SEP> (m) <SEP> I <SEP> Rt <SEP> (m) <SEP> I <SEP> Rmax <SEP> (m) <SEP> I <SEP> Rtm <SEP> (m) <SEP> I <SEP> Rv <SEP> (m) <SEP> I <SEP> Rpm <SEP> (
<tb><SEP> 1 <SEP> I <SEP> 18.81 <SEP> I <SEP> 79.12 <SEP> I <SEP> 77.35 <SEP> I <SEP> 63.21 <SEP> I <SEP> 51.02 <SEP> I <SEP> 24.55
<tb><SEP> 2 <SEP> I <SEP> 13.51 <SEP> I <SEP> 78.17 <SEP> I <SEP> 73.79 <SEP> I <SEP> 63.75 <SEP> I <SE> 53.48 <SEP> I <SEP> 22.22
<tb><SEP> 3 <SEP> I <SEP> 13.6 <SEP> I <SE> 77.29 <SEP> I <SEP> 73.48 <SEP> I <SEP> 64.46 <SEP> I <SEP> 51.97 <SEP> I <SEP> 23.02
<tb><SEP> 4 <SEP> I <SEP> 13.83 <SEP> I <SEP> 79.1 <SEP> I <SEP> 74.87 <SEP> I <SEP> 64.55 <SEP> I <SEP> 49.48 <SEP> I <SEP> 24.31
<tb><SEP> 5 <SEP> I <SEP> 14.09 <SEP> I <SE> 76.78 <SEP> I <SEP> 76.2 <SEP> I <SEP> 64.72 <SEP> I <SEP> 48.59 <SEP> I <SEP> 24.8
<tb> average <SEP> I <SEP> 13.70 <SEP> I <SEP> 78.09 <SEP> I <SEP> 75.14 <SEP> I <SEP> 64.14 <SEP> I <SEP> 50.91 <SEP> I <SEP > 23.78
<tb><SEP> I <SEP> I <SEP> I <SEP> I <SEP> I <SEP> I
<tb> deviation <SEP> type <SEP> I <SEP> .21 <SEP> I <SEP> .94 <SEP> I <SE> 1.45 <SEP> I <SEP> .56 <SEP> I <SEP> 1.74 <SEP> I <SEP> .99
<tb> time t = 2

profile <SEP> n <SEP> I <SEP> Rq <SEP> (m) <SEP> I <SE> SM <SEP> (m) <SEP> I <SEP> long <SEP> (%) <SEP> I <SEP> Rp <SEP> (m) <SEP> I <SEP> EK
<tb><SEP> 1 <SEP> I <SEP> 16.75 <SEP> I <SEP> 410 <SEP> I <SEP> 105.33 <SEP> I <SEP> 28.76 <SEP> I <SEK> 2.78
<tb><SEP> 2 <SEP> I <SEP> 16.46 <SEP> I <SEP> 335.45 <SEP> I <SEP> 105.41 <SEP> I <SEP> 25.74 <SEP> I <SEP> 2.98
<tb><SEP> 3 <SEP> I <SEP> 16.52 <SEP> I <SEP> 371 <SEP> I <SEP> 105.5 <SEP> I <SEP> 24.56 <SEP> I <SEP> 3.06
<tb><SEP> 4 <SEP> I <SEP> 16.91 <SEP> I <SEP> 371 <SEP> I <SEP> 105.60 <SEP> I <SEP> 29.36 <SEP> I <SEP> 2.8
<tb><SEP> 5 <SEP> I <SEP> 17.11 <SEP> I <SEP> 391.11 <SEP> I <SEP> 105.37 <SEP> I <SEP> 28.34 <SEP> I <SEP> 2.78
<tb> average <SEP> I <SEP> 16.75 <SEP> I <SEP> 375.71 <SEP> I <SEP> 105.46 <SEP> I <SEP> 27.35 <SEP> I <SEP> 2.88
<tb><SEP> I <SEP> I <SEP> I <SEP> I <SEP> I
<tb> range <SEP> type <SEP> I <SEP> .24 <SEP> I <SE> 5.31 <SEP> I <SEP> .12 <SEP> I <SEP> 10.6 <SEP> I <SEP>. 11
<Tb>
EXAMPLE II
The cutaneous relief is analyzed at the level of the trochanteric region of the left thigh from impressions made as previously described, before treatment (t = 1) and after treatment (t = 2).

the values obtained are collated in the following Tables IIIa and IIIb TABLE IIIa

profile <SEP> n <SEP> I <SEP> Ra <SEP> (m) <SEP> I <SEP> Rt <SEP> () <SEP> I <SEP> Rmax <SEP> () <SEP> I <SEP> Rtm <SEP> (m) <SEP> I <SEP> Rv <SEP> (m) <SEP> I <SEP> Rpm <SEP> (1
<tb><SEP> 1 <SEP> I <SEP> 12.51 <SEP> I <SEP> 76.25 <SEP> I <SEP> 60.15 <SEP> I <SEP> 56.56 <SEP> I <SEP> 41.49 <SEP> I <SEP> 23.03
<tb><SEP> 2 <SEP> I <SEP> 11.84 <SEP> I <SEP> 68.05 <SEP> I <SEP> 64.51 <SEP> I <SEP> 53.32 <SEP> I <SEP> 44.42 <SEP> I <SEP> 18.91
<tb><SEP> 3 <SEP> I <SEP> 10.87 <SEP> I <SEP> 63.48 <SEP> I <SEP> 61.79 <SEP> I <SEP> 47.56 <SEP> I <SEP> 39.93 <SEP> I <SEP> 17.37
<tb><SEP> 4 <SEP> I <SEP> 11.01 <SEP> I <SEP> 62.47 <SEP> I <SEP> 56.2 <SEP> I <SEP> 45.71 <SEP> I <SEP> 35.6 <SEP> I <SEP> 18.46
<tb><SEP> 5 <SEP> I <SEP> 10.72 <SEP> I <SEP> 57.13 <SEP> I <SEP> 52.02 <SEP> I <SEP> 44.12 <SEP> I <SEP> 33.38 <SEP> I <SEP> 18.04
<tb> average <SEP> I <SEP> 11.39 <SEP> I <SEP> 65.48 <SEP> I <SEP> 60.55 <SEP> I <SEP> 49.45 <SEP> I <SEP> 38.96 <SEP> I <SEP > 19.16
<tb><SEP> I <SEP> I <SEP> I <SEP> I <SEP> I <SEP> I
<tb> difference <SEP> type <SEP> I <SEP> .68 <SEP> I <SEP> 6.4 <SEP> I <SE> 5.77 <SEP> I <SEP> 4.72 <SEP> I <SEP> 3.98 <SEP> I <SEP> 1.99
<tb> time t = 1

profile <SEP> n <SEP> I <SEP> Rq <SEP> (m) <SEP> I <SE> SM <SEP> (m) <SEP> I <SEP> long <SEP> (Z) <SEP> I <SEP> Rp <SEP> (m) <SEP> I <SEP> EK <SEP> I <SEP> SK
<tb><SEP> 1 <SEP> I <SEP> 16.31 <SEP> I <SE> 528.57 <SEP> I <SEP> 102.52 <SEP> I <SEP> 26.92 <SEP> I <SEP> 3.31 <SEP> I <SEP> -.82
<tb><SEP> 2 <SEP> I <SEP> 15.47 <SEP> I <SEP> 460 <SEP> I <SEP> 102.5 <SEP> I <SEP> 23 <SEP> I <SEP> 3.66 <SEP> I <SEP> -1.09
<tb><SEP> 3 <SEP> I <SEP> 14.23 <SEP> I <SEP> 534.28 <SEP> I <SEP> 102.25 <SEP> I <SEP> 21.06 <SEP> I <SEP> 3.52 <SEP> I <SEP> -1.01
<tb><SEP> 4 <SEP> I <SEP> 13.78 <SEP> I <SE> 532.85 <SEP> I <SEP> 102.23 <SEP> I <SEP> 24.35 <SEP> I <SEP> 2.93 <SEP> I <SEP> -.76
<tb><SEP> 5 <SEP> I <SEP> 13.08 <SEP> I <SEP> 512.85 <SEP> I <SEP> 102.19 <SEP> I <SEP> 21.96 <SEP> I <SEW> 2.74 <SEP> I <SEP> -.66
<tb> average <SEP> I <SEP> 14.57 <SEP> I <SEP> 517.71 <SEP> I <SEP> 102.34 <SEP> I <SEP> 23.62 <SEP> I <SEP> 3.23 <SEP> I <SEP > -.87
<tb><SEP> I <SEP> I <SEP> I <SEP> I <SEP> I <SEP> I
<tb> difference <SEP> type <SEP> I <SEP> 1.16 <SEP> I <SEP> 6.19 <SEP> I <SEP> .14 <SEP> I <SEP> 9.11 <SEP> I <SEP> .34 <SEP> I <SEP> .15
<tb> TABLE IIIb

profile <SEP> n <SEP> I <SEP> Ra <SEP> (m) <SEP> I <SEP> Rt <SEP> (m) <SEP> I <SEP> Rmax <SEP> (m) <SEP> I <SEP> Rtm <SEP> (m) <SEP> I <SEP> Rv <SEP> (m) <SEP> I <SEP> Rpm <SEP> (m)
<tb><SEP> 1 <SEP> I <SEP> 7.58 <SEP> I <SEP> 36.41 <SEP> I <SEP> 35.16 <SEP> I <SEP> 31.76 <SEP> I <SEP> 18.73 <SEP> I <SEP> 15.74
<tb><SEP> 2 <SEP> I <SEP> 8.01 <SEP> I <SEP> 40.73 <SEP> I <SEP> 40.73 <SEP> I <SEP> 32.78 <SEP> I <SEP> 19.61 <SEP> I <SEP> 15.96
<tb><SEP> 3 <SEP> I <SEP> 8.49 <SEP> I <SEP> 42.95 <SEP> I <SEP> 42.95 <SEP> I <SEP> 35.69 <SEP> I <SEP> 22.49 <SEP> I <SEP> 17.04
<tb><SEP> 4 <SEP> I <SEP> 8.78 <SEP> I <SE> 45.00 <SEP> I <SEP> 43.53 <SEP> I <SEP> 38.61 <SEP> I <SEP> 23.92 <SEP> I <SEP> 18.2
<tb><SEP> 5 <SEP> I <SEP> 8.89 <SEP> I <SEP> 45.88 <SEP> I <SEP> 43.17 <SEP> I <SEP> 39.11 <SEP> I <SEP> 24.27 <SEP> I <SEP> 18.9
<tb> average <SEP> I <SEP> 8.35 <SEP> I <SEP> 42.21 <SEP> I <SEP> 41.11 <SEP> I <SEP> 35.59 <SEP> I <SEP> 21.8 <SEP> I <SEP > 17.17
<tb><SEP> I <SEP> I <SEP> I <SEP> I <SEP> I <SEP> I
<tb> deviation <SEP> type <SEP> I <SEP> .49 <SEP> I <SEP> 3.4 <SEP> I <SEP> 3.13 <SEP> I <SEP> 2.97 <SEP> I <SEP> 2.24 <SEP> I <SEP> 1.22
<tb> time t = 2

profile <SEP> n <SEP> I <SEP> Rq <SEP> (m) <SEP> I <SE> SM <SEP> (m) <SEP> I <SEP> long <SEP> (%) <SEP> I <SEP> Rp <SEP> (m) <SEP> I <SEP> EK <SEP> I <SEP> SK
<tb><SEP> 1 <SEP> I <SEP> 8.91 <SEP> I <SEP> 293.84 <SEP> I <SEP> 103.13 <SEP> I <SEP> 18.85 <SEP> I <SEP> 2.01 <SEP> I <SEP> -.02
<tb><SEP> 2 <SEP> I <SEP> 9.24 <SEP> I <SEP> 278.46 <SEP> I <SEP> 103.12 <SEP> I <SEP> 21.12 <SEP> I <SEP> 2.01 <SEP> I <SEP> .01
<tb><SEP> 3 <SEP> I <SEP> 9.83 <SEP> I <SEP> 307.09 <SEP> I <SEP> 103.12 <SEP> I <SEP> 20.45 <SEP> I <SEP> 2.07 <SEP> I <SEP> -.04
<tb><SEP> 4 <SEP> I <SEP> 10.27 <SEP> I <SEP> 290.76 <SEP> I <SEP> 103.10 <SEP> I <SEP> 20.45 <SEP> I <SEP> 2.13 <SEP> I <SEP> -.09
<tb><SEP> 5 <SEP> I <SEP> 10.41 <SEP> I <SEP> 315 <SEP> I <SEP> 103.05 <SEP> I <SEP> 21.69 <SEP> I <SEP> 2.07 <SEP> I <SEP> -.07
<tb> average <SEP> I <SEP> 9.73 <SEP> I <SEP> 297.43 <SEP> I <SEP> 103.12 <SEP> I <SEP> 20.51 <SEP> I <SEP> 2.06 <SEP> I <SEP > -.04
<tb><SEP> I <SEP> I <SEP> I <SEP> I <SEP> I <SEP> I
<tb> deviation <SEP> type <SEP> I <SEP> .58 <SEP> I <SEP> 2.0 <SEP> I <SEP> .03 <SEP> I <SEP> 10.79 <SEP> I <SEP>. 04 <SEP> I <SEP> .03
<Tb>
COMPARATIVE ANALYSIS
The following Table IV gathers the values of the five characteristic parameters defined according to the invention obtained for the given examples.
TABLE IV

<tb> Parameters <SEP> Ra <SEP> (m) <SEP> Rt <SEP> (m) <SEP> Rtm <SEP> (m) <SEP> long <SEP> (%) <SE> Sm <SEP > (m)
<tb> Reference <SEP> 8.28 <SEP> + <SEP> 0.6 <SEP> 53.6 <SEP> t <SEP> 5 <SEP> 35.9 <SEP> + <SEP> 1.8 <SEP><<SEP> 103.1 <SEP> 374.5 <SEP> + <SEP> 8
<tb> example <SEP> 1 <SEP> ti <SEP> 13.72 <SEP> + <SEP> G, 7 <SEP> 59.6 <SEP> + <SEP> 6.6 <SEQ> 57.0 <SEP> + <SEP> 4,6 <SEP> 393 <SEP> + <SEP> 6
<tb>#<SEP> t = 2 <SEP> 13.78 <SEP><SEP> + <SEP> 0.2 <SE> 78.1 <SEP> + <SEP> 0.9 <SEP> 64, 1 <SEP> r <SEP> 0.6 <SEP>> 104-105 <SEP> 375.7 <SEP> + <SEP> 5
<tb> Example <SEP> 2 <SEP> t = 1 <SEP> 11.39 <SEP> + <SEP> 0.7 <SEP> 65.5 <SEP> + <SEP> 6 <SEP> 49.5 <SEP> +4.7 <SEP> 517.7 <SEP> + <SEP> 6
<tb><SEP> t = 2 <SEP> 8.35 <SEP> + <SEP> 0.5 <SEP> 42.2 <SEP> + <SEP> 3.4 <SEP> 35.6 <SEP> + <SEP> 3 <SEP><SEP> 103.1 <SEQ> 297.4 <SEP> + <SEP> 3
<Tb>
Thus, by simple comparison of the values obtained, one can observe the existence or not of the phenomenon of "orange peel" and the effectiveness of the treatment applied.

 Indeed, values higher than those of reference for Ra, Rt, Rtm, long% and Sm mean the existence of the phenomenon of orange peel; this is the case of Example I at t = 1 and t = 2 and Example II at t = 1.

 The values of Example II at t = 2 reveal a normal skin coating.

 Thus, it can be seen that the aesthetic treatment applied in Example I was totally ineffective. On the other hand, the treatment applied to Example II has proved very effective since the values obtained are close to those of the reference example.

 The method according to the invention can be used for the analysis of cutaneous relief in other cases of abnormalities and / or variations of the cutaneous skin surface or in relief such as wrinkles and fingerprints. Under the operating conditions defined, it is sufficient to determine reference values, for each individual, corresponding to an unaffected area, for the parameters Ra, Rt, Rtm, long% and Sm and to compare the values obtained in an affected area.

 This method may constitute an efficacy evaluation test for any action on the skin coating to improve it or to modify it.

 Thus, the invention is not limited to the embodiment described above for which we can provide variants without departing from the scope of the invention.

Claims (15)

 1 - Non-invasive method of analysis of the cutaneous relief, in particular in the case of abnormalities or variations of the skin coating, using profilometry and 2D roughness, 3D and image analysis characterized in that it consists of  a) to identify the impression of the cutaneous relief in a chosen zone of the cutaneous coating,  b) perform physical measurements from said fingerprint by 2D profilometry and roughness, 3D, and image analysis,  c) process the information obtained  d) determining the parameters defining the condition of the cutaneous relief in said chosen zone.  2 - Process according to claim 1, characterized in that it further consists in producing a three-dimensional representation from the values of said parameters defining the condition of the cutaneous relief obtained for a selected area.  3 - Process according to claim 1, characterized in that one obtains the impression of the cutaneous relief using a precision molding material.  4 - Process according to claim 3, characterized in that said material belongs to the family of silicones.  5 - Process according to claim 4, characterized in that said material is xantoprene.  6 - Process according to any one of claims 3 to 5, characterized in that the precision molding material is introduced into a frame applied to the chosen skin coating area.  7 - Process according to claim 6, characterized in that the frame has a self-adhesive face to facilitate its application to the skin coating.  8 - Process according to any one of the preceding claims, characterized in that the physical measurements are performed using a non-contact optical sensor with laser detector.  9 - Process according to claim 8, characterized in that the wavelength of the laser beam used is in the near infrared.  10 - Process according to any one of claims 1 to 7, characterized in that the physical measurements are performed using a television camera working in a closed circuit.  11 - Process according to any one of the preceding claims, characterized in that the cutaneous relief is defined by the parameters  - Ra or arithmetic mean taking into account any variation with respect to the average line of the surface taken as a reference,  - Rt representing the greatest difference in altitude between the highest peak and the deepest fold bottom,  - Rtm representing the average of the greatest fold / valley distances measured on each of the base lengths.  12 - Process according to any one of the preceding claims, characterized in that the cutaneous relief is further defined by the parameters  - long% or developed length representing the actual length of a surface profile expressed as a percentage of the projected length in the mean plane of the surface,  - Sm or spacing parameter giving the average value of the distance separating two successive bumps or two recesses of the profile, counted at the level of the average line of the profile.  13 - Method according to any one of the preceding claims, for establishing an aesthetic diagnosis, characterized in that it consists in  a) determining the values of the parameters defining the state of the cutaneous relief specific to a subject in a normal reference zone,  b) determining the values of the parameters defining the condition of the cutaneous relief of said subject in the zone to be examined,  c) comparing said values with the values obtained for the normal reference zone,  d) determine the difference between the values obtained for the zone to be examined and the values obtained for the normal reference zone, making it possible to make an aesthetic diagnosis as to the existence of an anomaly or a variation of the relief skin and the extent to which it manifests itself.  14 - Method according to any one of claims 1 to 12, for evaluating the effectiveness of an aesthetic treatment including the skin coating, characterized in that it consists of  a) determining the values of the parameters defining the state of the cutaneous relief specific to a subject in a normal reference zone,  b) determining the values of the parameters defining the state of the cutaneous relief of said subject in an area suffering from an abnormality or a variation of the cutaneous relief before the application of any aesthetic treatment on said affected area,  c) determining the values of the parameters defining the state of the cutaneous relief of said subject in said affected area after the application of an aesthetic treatment on said zone,  d) compare the values obtained after treatment and before treatment,  e) determining the difference between said values after treatment and before treatment making it possible to evaluate the effectiveness of said aesthetic treatment applied in said zone affected by an abnormality or a variation of the cutaneous relief,  f) comparing the values obtained after treatment and for the normal reference zone,  g) determining the difference between said values obtained after treatment and those obtained for the normal reference zone making it possible to evaluate the overall efficiency of said aesthetic treatment applied in said zone affected by an abnormality or a variation of the cutaneous relief.  15 - Method according to claim 14, characterized in that the values of the parameters defining the condition of the cutaneous relief of a subject are determined in said area affected by an anomaly or a variation of the cutaneous relief at intervals of time in the course of applying an aesthetic treatment in said affected area.