RU2618980C1 - Method of controlling changes in facial skin defects and devicre for its implementation - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: according to the proposed method, the height of the patient (4) located on a seat (3) opposite the digital single-lens reflex camera (1) and the distance between the tip of the nose and the horizontal bar (5) are measured by height metre (2) and the same values of these quantities are provided during all photoshoots with this patient (4), leaving other conditions of photoshoot unchanged. Front projection is chosen as the main one, and photoshoots are additionally performed in at least one of the two lateral projections of the face, which axes constitute an acute angle, preferably from 21° to 25°, relative to the axis of the front projection. At the same time, horizontal and vertical placement of the digital single-lens reflex camera (1) is left unchanged. As a result of the computer processing, at least one additional quantitative parameter based on calculation of the dark pixels is obtained. The device comprises the height metre (2) provided with the seat (3), a vertical bar (6) is fixed to the horizontal bar of the height metre. The height metre (2) and the seat (3) are arranged together with the stationary vertical support (7) with the digital single-lens reflex camera (1) on the common base (8). The digital single-lens reflex camera (1) is placed on shaped horizontal bar (9), formed preferably as a slider, so that it can be fixed in the middle of the shaped horizontal plate (9) for photoshooting in the front projection and in its two branches for photoshooting in the lateral projections of the patient's (4) face, which axes constitute an acute angle relative to the axis of the front projection.

EFFECT: increased objectivity of controlling changes in facial skin defects before and after performing procedures of defect correction.

14 cl, 7 dwg

Description

The invention relates to the field of medical technology and can be used to monitor facial skin defects of patients.

Various methods and devices for controlling skin defects are known. Known, for example, is a method and a device implementing it for controlling facial skin defects, comprising at least one light source, mainly based on a laser, configured to emit light onto the patient’s skin, at least one photosensor and a processing unit for the signal received from the photosensor (WO 2007144817 A1, 2007). At the same time, obtaining quantitative, i.e. the closest to objective indicators of changes in the condition of the skin, and the device is complex in design and expensive.

Also known, for example, is a method and device for its implementation, which allows controlling changes in skin defects by changing the area of a skin defect to be corrected, the device comprising a digital camera placed opposite a lit skin defect, the electronic output of which is connected to a computer to which a monitor and keyboard are connected (RU 2301626 C1, 2007). At the same time, a skin defect and a conditional area standard located nearby are photographed. Digital images are processed in a computer. The ratio of the number of points in the digital image of the skin defect to the number of points in the image of the conditional standard, multiplied by the area of the standard, is defined as the area of the skin defect. When you repeat the photo shoot, you can control the change in the area of the skin defect. However, such an indicator as the defect area is not sufficiently informative, including due to the lack of an assessment of the volumetric changes in the defect. In addition, the conditions for photographing the original and corrected defects are not regulated. Therefore, this method and device cannot provide high objectivity of control.

Also known, for example, is a method and a device that implements it, based on non-contact measurement of a three-dimensional image of skin topography and its digitization using a 3D camera to evaluate the effectiveness of cosmetics and aesthetic manipulations (Geraldine Bouvry. Clinical tests: images abound. "The global information on cosmetics @ fragrances. ”March / April 2015, No. 32, p. 69). This source describes the Aeva-HE system, which includes a patient seat located on a turntable and a 3D camera placed opposite it. This method and device also does not fully ensure the objectivity of control, since it does not provide a constant fixed position of the patient’s head relative to the camera, and it is also difficult to obtain a full relief image of the defect due to the small distance between the lenses of the 3D camera.

Other methods and devices for controlling skin defects and their changes are known (for example, RU 134776 U1, 2013; RU 2515963 C1, 2014; US 7349857 B2, 2008; US 8971609 B2, 2015; WO 2004091501 A3, 2004). However, all of them, to one degree or another, cannot provide high objectivity of control.

Of the known methods for monitoring changes in skin defects, the closest to the proposed method is a photo session with a patient by photographing with a digital SLR camera the illuminated skin defect of his face in the main projection under unchanged photography conditions before and after the procedure for correcting the skin defect of his face and subsequent computer processing the obtained color images by converting them to grayscale and pixel analysis of images in the selected area, as a result of which quantitatively skin defect parameter changes based on counting the dark pixel (RU 121 129 U1, 2012).

In this method, photographing is carried out using a stationary digital SLR camera opposite the defect in the skin of the patient’s face, once before and once after the procedures in the same projection. When calculating dark pixels, a quantitative parameter of the defect to be corrected is obtained before and after the correction. However, the objectivity of such control is insufficient. This is due to the fact that with direct illumination of a skin defect, the illuminated surface looks smooth, neckless and the surface texture is not fully detected, which complicates the assessment of changes in the skin defect with a high degree of certainty when photographing in one such projection. In addition, there are no techniques to ensure the exact same position of the patient’s head and its placement relative to the digital SLR camera before and after the procedures.

From the same patent source, a device closest to the proposed one is known - a device for monitoring changes in facial skin defects, comprising a digital SLR camera mounted on a height-adjustable main stationary vertical support opposite the patient's face, with the possibility of unchanged photography conditions, connected to a keyboard and a computer monitor, the software unit of which is configured to convert a color image into grayscale and pixel Nogo image analysis.

This device provides a condition for ensuring the possibility of unchanged photography conditions before and after the procedures. However, its practical implementation is difficult, since there are no structural elements and nodes that provide an exact, unchanged position of the patient’s head and its placement relative to the digital SLR camera before and after the procedures for correcting a skin defect. In addition, as indicated above, photographing an area with a defect in the patient’s skin in only one projection does not make it possible to evaluate changes in skin defects with complete objectivity. Therefore, such a device does not allow for high objectivity of control.

The objectives of the invention are to provide a method for controlling changes in facial skin defects and a device for monitoring changes in facial skin defects that are devoid of the disadvantages of the prototype. The technical result provided by the inventions is to increase the objectivity of control.

This is achieved by the fact that in the method of controlling changes in facial skin defects, including photo shoots with the patient by photographing with a digital SLR camera, the illuminated skin defect of his face in the main projection under unchanged photography conditions before and after the procedure for correcting the skin defect of his face and subsequent computer processing the obtained color images by converting them to grayscale and pixel analysis of images in the selected area, as a result of which a quantitative parameter is obtained from the skin defect, based on the calculation of dark pixels, before the first photo shoot, use a height meter to measure the height of the height meter located on the seat of the height opposite the digital SLR camera of the patient and the distance between the tip of his nose and the horizontal height of the height meter and provide the same values for these values for all subsequent photo shoots with this patient , in each photo shoot, the frontal projection of the patient’s face is selected as the main projection and photographs are taken additionally in at least one of the two x lateral projections of the patient's face, the axes of which are an acute angle relative to the axis of the frontal projection, while when photographing in the side projection, the digital SLR camera is placed in the same plane and at the same height relative to its location when photographing in frontal projection and as a result of computer processing, at least one additional quantitative parameter is obtained based on the calculation of dark pixels when photographing in the corresponding lateral projection. The acute angle between the axis of the frontal projection and the axis of the side projections can be selected in the range from 21 ° to 25 °. When photographing, they can use the grid displayed on the digital SLR camera, while frontal projection is carried out under the condition that the central horizontal grid line passes through the mid-pupil line of the patient’s face, and the central vertical grid line passes through the center of the patient’s face, and photographing lateral projections are carried out under the condition that the central vertical line of the grid passes through the inner corner of the patient’s eye.

The above technical result in terms of the method of controlling changes in skin defects is provided by the totality of the above essential features characterizing the proposed method.

In the part of the device for implementing the method for monitoring changes in facial skin defects, the specified technical result is achieved in that the device for monitoring changes in facial skin defects containing a digital SLR camera mounted on a height-adjustable stationary vertical support opposite the patient's face with the possibility of unchanged photography conditions connected with a computer equipped with a keyboard and a monitor, the program unit of which is designed to provide color translation The image in the grayscale and pixel analysis of the image in the selected area contains a height meter equipped with a seat, a vertical ruler is attached to the horizontal bar, while the height meter with the seat and the stationary vertical support are mounted on a common base at a fixed distance between them, and the digital SLR camera is placed on mounted on a stationary vertical support curly horizontal bar with the possibility of fixing the digital SLR on the surface shaped horizontal bar in the middle thereof for photographing in the frontal projection of the patient and fixing face at its two branches for photographing lateral projections in the patient's face, the axes of which make an acute angle with respect to the front projection axis. The angular distance between the fixation point of the digital SLR camera in the middle of the curly horizontal bar and the fixation point in each of the branches of the curly horizontal bar can be selected in the range from 21 ° to 25 °. A height meter with a seat and a stationary vertical support mounted on a common base can be rigidly fixed to it.

Stationary vertical support can be made in the form of a tripod or telescopic rod. Fastening on a stationary vertical support of a curly horizontal bar can be performed in its middle. The control device can be equipped with an additional stationary vertical support, while fixing the curly horizontal bar on both stationary vertical supports is made at the ends of its corresponding branch. Curly horizontal bar can be made in the form of part of a circle or part of an ellipse. It can be made in the form of a slider, while the slider is equipped with a carriage for linear movement of the digital SLR camera on its surface, and a stopper is installed at the end of each of the branches of the slider. The digital SLR camera can be equipped with a panoramic head.

The above technical result in terms of a device for monitoring changes in facial skin defects is provided by the entire combination of the above essential features characterizing the proposed device. They are in constructive unity and functionally interconnected, and the connection of the corresponding elements, nodes and blocks in the device is carried out by assembly operations.

In FIG. 1 schematically shows a structural diagram of a device for monitoring changes in facial skin defects (top view), FIG. 2 is the same side view. In FIG. Figure 3 schematically shows an image of a patient's face with a video marker and a grid on the display of a digital SLR camera when cropping a photograph. FIG. 4-fig. 7 in the form of screenshots (screenshots from a computer monitor) illustrate examples of monitoring changes in the middle lower third of the face, including nasolabial folds of the patient before and after correction (correction) of defects, photographs of the patient's face and dark pixel zone with a quantitative indicator of changes are shown. FIG. 4 is a frontal view during control from the right nasolabial fold, FIG. 5 - the same with the control from the side of the left nasolabial fold, FIG. 6 is a shot in lateral projection under control from the right nasolabial fold, FIG. 7 - shooting in another lateral projection during control from the left nasolabial fold. In FIG. 4 - FIG. 7 the image on the left shows the patient's face before the procedures, the right image after the procedures.

A device that implements a method for monitoring changes in facial skin defects includes a digital SLR camera 1 connected to a computer equipped with a keyboard and monitor (not shown in the drawings) and a height meter 2 with a seat 3 for a patient 4. The computer program unit is capable of transferring a color image to halftone and pixel analysis of the image in the selected area. The height meter 2 is equipped with a horizontal bar 5, to which a vertical ruler is attached 6. The digital SLR camera 1 is installed by means of a stationary vertical support 7 opposite the patient's face 4, with the possibility of unchanged photography conditions. The stationary vertical support 7 can be made, for example, in the form of a tripod (for example, a tripod) or a telescopic rod. The height meter 2 with the seat 3 and the stationary vertical support 7 are installed, for example, rigidly fixed, on a common base 8, made, for example, in the form of a platform of metal, wood or plastic, at a fixed distance between them. The distance between the nose of the patient 4 and the lens of the digital SLR camera is predominantly 110 cm. The floor of the room in which the device is located can be used as a common base 8. The digital SLR camera 1 is predominantly equipped with a panoramic head with its position and flash (not shown in the drawings) and is placed on a curly horizontal bar 9 mounted on a stationary vertical support 7 with the possibility of its fixation in the middle of the curly horizontal bar 9 for taking pictures in frontal view and in lateral branches of a curly horizontal bar 9 for photographing in side projections. The curly horizontal bar 9 is made primarily of metal and has the form, for example, of a circle or ellipse. The angular distance between the fixation point of the digital SLR camera 1 in the middle of the curly horizontal bar 9 and its fixation point in each of the branches of the curly horizontal bar 9 is chosen mainly in the range from 21 ° to 25 °. Other angular distances within an acute angle may be selected. The curly horizontal bar 9 is made, for example, in the form of a slider, which is equipped with a carriage 10 for linear movement of the digital SLR camera 1 on its surface, with a stopper at the end of each of the branches of the slider (not shown in the drawings). The curly horizontal bar 9 is mounted on a stationary vertical support 7 mainly in its middle (middle of the lower surface) with one-piece or detachable connection. An additional stationary vertical support 7 can be used, with a curly horizontal bar 9 fixed by the end of one of its branches on one of the stationary vertical supports 7, and by the end of its other branch on another stationary vertical support 7. The number of stationary vertical supports 7 can be from one to three.

Control of facial skin defects is as follows. Before carrying out procedures to correct a defect in the skin of the patient’s face 4, it is placed on the seat 3 of the height meter 2. As a rule, the hands of the patient 4 are on their knees, the back and back of the head are firmly pressed against the height meter 2, the horizontal bar 5 is lowered and pressed against the parietal region of the patient’s head 4. In this position, the value of the indicator is fixed in height when the patient is seated 4. Using a mobile vertical ruler 6, measure the distance from the tip of the nose of the patient 4 to the horizontal bar 5. These values are used to place the patient 4 and the position of his head in subsequent photo shoots after procedures to correct the defect in the skin of his face. In the initial and subsequent photography, the constancy of other photography conditions, including lighting, is ensured. Before shooting, set up the camera using a video marker (Fig. 3). At each photo shoot, the front projection is first taken in front of the patient’s face 4. “Aiming” of the digital SLR 1 is carried out using a grid displayed on the digital SLR 1 mainly so that the central horizontal line of the grid passes through the mid-pupil line of the patient’s face 4 (Fig. 2), and the central vertical line of the grid passed through the center of the patient's face, i.e. through the center of the glabella (the area between the eyebrows) in the center of the back of the nose. Then, the digital SLR camera 1 is moved along the curly horizontal bar 9, mainly up to the stop installed therein, by an acute angle relative to the axis of the frontal projection, mainly by an angle from 21 ° to 25 °, and photographing is carried out in one of the side projections. When taking photographs in the lateral projection, the digital SLR camera 1 should be located in the same plane and at the same height with respect to its location when photographing in the frontal projection, which is ensured by the design of the proposed device. In this case, the “aiming” of the digital SLR camera 1 is carried out using the grid displayed on its display so that the central vertical line of the grid passes through the inner corner of the patient’s eye 4. Then, the digital SLR camera 1 can be moved to the other side, mainly at the same angle and take a photo in another side view. The choice of a specific value of the angle of movement within the specified limits is due to the anatomical features of the patient's face 4. The limits of the values of this angle are established empirically and are optimal in terms of the most acceptable angles and the height of the direction of light for visualizing a skin defect. Photographs in the lateral projections make it possible to identify even slight bulges on the surface of the skin of the face of the patient 4 due to the fact that they cast falling shadows. In this case, light detection of the texture of defects in the form of bulges and depressions is fully ensured. The resulting color digital images from the digital SLR camera 1 are transferred to a computer, where, through a specialized program, for example, Medic Test, they are processed to obtain quantitative characteristics of the defect changes, while the color digital images are converted to grayscale and pixel analysis is performed. Any skin defect in halftone can be represented by a darker colored area, i.e. containing more dark pixels than in the area surrounding the defect. Since the image consists of dark and light pixels, a comparison of the number of dark pixels before and after the procedures (medical procedures in the corrected area of the patient’s face 4) gives a quantitative parameter (in percent) of changes in the area of interest. By taking photographs in the main (frontal) and one of the side projections or in two side projections, in addition to the main value of such a parameter, one or two additional parameters are obtained, which makes it possible to more accurately evaluate the aesthetic result obtained. Especially informative are the results of photographing in lateral projections. Thus, objective quantitative parameters of changes in the skin defect are obtained that characterize the state of the defect before and after the procedures for correcting it. Improving the objectivity of monitoring changes in the skin defect is provided by combining the requirements for the invariability of photography conditions and obtaining additional quantitative parameters.

Implementation example. Patient A. Turned to correct age-related changes in the lower third of the face, including nasolabial folds. The correction procedure consisted of introducing a 4 ml filler based on hyaluronic acid into the area of nasolabial folds, wrinkles of “puppets” and into the submintal regions. Before and after the procedure, photographs were taken using a curly horizontal bar 9 mounted on the carriage 10, made in the form of a slider, a digital SLR 1. We used a Canon digital SLR 1 with a lens diameter of 8.45 cm, a Sevenoak SK-CS02 slider, two tripod tripods Manfrotto with a panoramic 3D head, height meter 2 medical RM-2 with a chair. The digital SLR camera 1 is located at a distance of 110 cm from its lens to the tip of the patient’s nose 4, the distance from the common base 8 to the lower edge of the lens is 117 cm. Photographs were taken in the frontal projection (Fig. 4, Fig. 5) and in two side projections (Fig. 6, Fig. 7) at an angle of 25 °. The performed procedure had a positive effect - correction of the lack of volume in the area of nasolabial folds, wrinkles of the "puppets" was achieved, the oval of the face and the position of the corners of the mouth were aligned. Using the Medic Test program, the following quantitative parameters of the achieved aesthetic result were obtained. When processing photographs obtained from the frontal projection, it was revealed that the nasolabial fold on the right was reduced by 10.15% (Fig. 4), the nasolabial fold on the left was reduced by 38.9% (Fig. 5). When processing photographs taken with lateral projections, the total value of reducing the nasolabial folds and wrinkles of the "puppets" in the right side of the face by 9.56% (Fig. 6) and 10.17% in the left side of the face (Fig. 7) was revealed The presence of several parameter values obtained under identical conditions of photo shoots made it possible to evaluate the obtained aesthetic result with a high degree of objectivity.

The method for monitoring changes in facial skin defects and a device for its implementation, made in accordance with the invention, provide an increase in the objectivity of control compared to similar known ones by obtaining additional quantitative parameters characterizing changes in the skin defect, which, together with the main quantitative parameter, are more informative for assessing these changes, and at the same time the fullest fulfillment of the requirement of invariance of all conditions of photography, including position and placement the patient’s head 4 relative to the lens of the digital SLR camera 1, before and after the skin defect correction procedures.

Claims (14)

1. A method for monitoring changes in facial skin defects, including photo sessions with the patient by using a digital SLR camera to illuminate the illuminated skin defect of his face in the main projection under unchanged photography conditions before and after the procedure for correcting the skin defect of his face and subsequent computer processing of the obtained color images by translating them into halftone and pixel analysis of images in the selected area, as a result of which a quantitative parameter of changes in the skin defect is obtained, based based on the calculation of dark pixels, characterized in that, before the first photo session, using a height meter, measure the height of the patient’s height meter located on the seat opposite the digital SLR camera of the patient and the distance between the tip of his nose and the horizontal level of the height meter and provide the same values for these values for all subsequent photo shoots with this patient , in each photo shoot, the frontal projection of the patient’s face is selected as the main projection and photographs are taken additionally in at least one of two projections of the patient’s face, the axes of which are an acute angle relative to the axis of the frontal projection, while when photographing in the side projection, the digital SLR camera is placed in the same plane and at the same height relative to its location when photographing in the frontal projection, and as a result of computer processing, at least one additional quantitative parameter is obtained based on the calculation of dark pixels when photographing in the corresponding lateral projection. 2. The control method according to p. 1, characterized in that the sharp angle between the axis of the frontal projection and the axis of the side projections is selected in the range from 21 ° to 25 °. 3. The control method according to claim 1, characterized in that when photographing, the grid displayed on the digital SLR camera is used, while frontal projection is carried out under the condition that the central horizontal line of the grid passes through the mid-pupil line of the patient’s face and the central the vertical line of the grid passes through the center of the patient’s face, and photographing in lateral projections is carried out under the condition that the central vertical line of the grid passes through the inner corner of the patient’s eye. 4. A device for monitoring changes in facial skin defects, comprising a digital SLR camera mounted on a stationary vertical height-adjustable support opposite the patient's face, providing unchanged photography conditions, connected to a computer equipped with a keyboard and monitor, the program unit of which is capable of rendering color image in grayscale and pixel analysis of the image in the selected area, characterized in that it contains equipped with a height meter with a vertical ruler attached to its horizontal bar, while the height meter with a seat and a stationary vertical support are mounted on a common base at a fixed distance between them, and the digital SLR camera is placed on a curly horizontal bracket fixed to a stationary vertical support with the possibility of fixing a digital mirror cameras on the surface of a curly horizontal bar in its middle for photographing in the frontal projection of the patient's face and fixing in yx its branches for photographing lateral projections in the patient's face, the axes of which make an acute angle with respect to the front projection axis. 5. The control device according to claim 4, characterized in that the angular distance between the fixation point of the digital SLR camera in the middle of the curly horizontal bar and the fixation point in each of the branches of the curly horizontal bar is selected in the range from 21 ° to 25 °. 6. The control device according to claim 4, characterized in that the height meter with a seat and a stationary vertical support mounted on a common base are rigidly fixed to it. 7. The control device according to claim 4, characterized in that the stationary vertical support is made in the form of a tripod. 8. The control device according to claim 4, characterized in that the stationary vertical support is made in the form of a telescopic rod. 9. The control device according to claim 4, characterized in that the fastening on a stationary vertical support of a curly horizontal bar is made in its middle. 10. The control device according to claim 4, characterized in that it is provided with an additional stationary vertical support, while fixing the curly horizontal bar on both stationary vertical supports is made at the ends of its corresponding branch. 11. The control device according to claim 4, characterized in that the curly horizontal bar is made in the form of a part of a circle. 12. The control device according to claim 4, characterized in that the curly horizontal bar is made in the form of a part of the ellipse. 13. The control device according to claim 4, characterized in that the curly horizontal bar is made in the form of a slider, while the slider is equipped with a carriage for linear movement of the digital SLR camera on its surface, and a stopper is installed at the end of each of the branches of the slider. 14. The control device according to claim 4, characterized in that the digital SLR camera is equipped with a panoramic head.

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