FR3136154A1 - System and method for nail treatment - Google Patents

Abstract

System and method for the treatment of nails Set of patches (16; 16a, 16b) to be positioned on nails to be treated using a device for emitting light pulses, these patches being pre-cut with a shape of nail or part of a nail and made in a coating absorbing the light emitted by the device, resistant to a temperature of at least 60°C. Figure for abstract: Fig. 8

Description

System and method for nail treatment

The present invention relates to the treatment of fingernails or toenails.

Many people, especially elderly people, suffer from various nail conditions, including onychomycosis.

Conventional treatments which are based on the use of antifungal varnishes are relatively restrictive because they must be carried out over a long period of time, and also present the disadvantages inherent in the use of compounds presenting a certain toxicity.

Trials of pulsed light treatments have been carried out to try to improve the aesthetic appearance of the nail or its pathological condition. Preparing the nails for treatment is then limited to possible sanding of the exterior surface of the nail in order to remove excess thickness. The nail is then exposed for a few minutes to a sequence of repeated flashes, of sufficient fluence to raise the temperature of the nail.

In the case of a polychromatic flash lamp (IPL) source, the flashes of divergent light are sent from a sufficient distance not to burn the skin environment of the nail, and the temperature on the surface of the nail is below 50°C (45°C being considered the limit of the discomfort zone). In general, 4 to 6 sessions spaced 3 to 4 weeks apart are carried out.

In the case of using a laser light source, the YAG solution at 1054nm is used. The area treated by the laser is limited to a spot of a few mm ² , which requires numerous shots to treat the entire surface of the nail. In addition, the fluence is relatively high, of the order of 70J/cm ² , due to the low absorption of tissues. As with the polychromatic flash lamp treatment, the temperature does not exceed 50°C on the surface of the nail so as not to cause burns or discomfort.

The effectiveness of such treatments has not been demonstrated, due to the low temperature reached. In addition, the duration of the laser treatment is relatively long, of the order of several minutes per nail, which makes the treatment tedious.

Thus, light treatments of nails, as carried out today, remain relatively ineffective, as evidenced by various studies such as the one covered in the article “The effectiveness of lasers in the treatment of onychomychosis: a systematic review » Bristow Journal of Foot and Ankle Research 2014, 7:34.

There therefore remains a need to improve the effectiveness of light treatments for nails aimed at improving their aesthetic appearance and/or treating pathologies such as onychomycosis.

The invention aims to meet this need, and it achieves this according to a first of its aspects thanks to a method of preparing a nail with a view to subjecting it to a treatment by light pulses, this method comprising the step consisting of applying to the nail a coating absorbing the light emitted during the treatment, in particular a coating of dark color, in particular black, and positioning an exit window of a device for emitting light pulses relative to the nail of such that the light emitted by the device is directed towards the nail.

By “absorbent coating” we must understand that the coating absorbs a significant part of the light emitted by the light pulse emitting device, and improves the transformation of light into heat compared to the bare nail. Advantageously, the reflectivity R of the coating is less than 50%, better than 40%, 30% or 20%, and/or its transmissivity T is less than 50%, better than 40%, 30% or 20%.

Preferably, there is a reflectivity and/or transmissivity of the coating according to the invention lower than 50%, better still 40%, 30% or 20%, with respect to so-called SFL (Super Filtered) spectrum light. Light) that can be used for treatment, the spectral intensity distribution of which is shown in the . We see in this figure that the substantial intensity is emitted after approximately 675nm (partly full in the figure), the emission spectrum extending to around 1200nm. We have shown in light lines the spectrum emitted below 675nm by the lamp, a filter internal to the device blocking the outgoing light to give the emission spectrum corresponding to the full part. The SFL spectrum is for example emitted by a FLUENCE, ARIANE or ANTHELIA brand machine from the company EUROFEEDBACK.

The reflectivity R corresponds to the portion of light energy reflected Er at the surface of the coating, relative to the incident energy Eo, taking into account the latter's emission spectrum. It varies from 0 for black bodies to 1 for a perfect mirror.

The transmissivity T is defined as the ratio of the energy of the transmitted light Et to the energy of the incident light Eo. For a given reflectivity R, the less transmissive a body is, the more absorbent it is, with 1=R+T+A, where A is the absorptivity.

Preferably, the absorptivity A of the absorbent coating (expressed in %) is greater than or equal to 50%, better still 60%, even better 70%, even 80% or 90%, ideally more than 95% or 99% .

Transmissivity T can be measured with a precision Joule meter, by measuring the ratio between the energy of the incident light and that of the light exiting through the coating.

For an example of a black polyimide (Kapton) coating, we have for example a transmissivity T of less than 20%, for example of the order of 15%, and for another example of a coating, in black PTFE, we have a transmissivity less than 10%, for example of the order of 5%. In the first case, for an incoming energy of 30J, we have approximately 4J output, and in the second case, for an incoming energy of 30J we have approximately 2J output.

For comparison, the natural reflectivity of healthy nails is around 50% (for a wavelength of 800nm) for a nail thickness of 1mm; for example, bare nails absorb only about 8% of the incident light, so the energy absorbed by the nails is limited to about 4% of the incident energy.

The coating placed on the nail makes it possible to artificially absorb the light emitted by the device and its temperature can increase very quickly and propagate in the form of a “thermal wave” through the nail to the underlying tissue. underlying. The resulting rise in temperature makes it possible to effectively destroy fungi or other pathogens which affect the nail, without however causing burns due to its short duration. Moreover, as the opaque coating only extends over the nail, the skin environment around the nail does not undergo the same rise in temperature, and can be preserved.

The invention makes it possible to improve the effectiveness of nail treatment at lower power and lower fluency.

The invention allows simultaneous treatment of several nails at the same time, if desired, because the lower light power required can allow the light to be spread out more.

The invention allows selective and safe treatment, because it does not overheat the skin around the nail, and allows work on black skin, if necessary, while protecting the skin, as explained below.

The temperature on the surface of the coating is, for example, at the end of the burst of pulses received between 180 and 250°C, for a fraction of a second. For example, the temperature on the surface of the coating is of the order of 200°C or more for approximately 0.2s after the end of the flash burst. Despite this high temperature, which drops quickly at the end of the last flash, the user only feels a feeling of discomfort or a slight burning sensation, but which disappears quickly. The temperature under the nail reaches for example 70°C for approximately 1 s, because the nail is a thermal insulator and also has a thermal time constant TRT (thermal relaxation time) of more than one second. Thus, all the molds that have colonized the nail material and feed on it are, for example, subjected to temperatures ranging from 100°C to 200°C for a fraction of a second, but sufficient to destroy them.

The coating makes it possible to transform a large fraction of the energy of the incident light into heat, for example more than 20 times the energy that would be absorbed by the nail in the absence of the coating.

Preferably, a reflective coating, in particular white, is applied to the periphery of the nail, preferably a water-dispersible coating. Such a coating allows light to be reflected and thus further limits the rise in temperature of the skin at the periphery of the nail. This makes it possible to subject the absorbent coating placed on the nail to a burst of light pulses without fear of burning the skin extending in the immediate vicinity of the nail.

Preferably, the opaque coating consists of a preformed film, preferably a film resistant to a temperature greater than or equal to 60°C, better still 80°C, even better 100°C, 150°C or 200°C. C, even better at 250°C, better at 300°C, preferably polyimide or PTFE. We will choose the temperature to which the coating resists depending on the power density on the coating; Higher temperature resistance makes it possible to achieve a higher temperature, which tends to improve the treatment efficiency and shorten it.

By “resistant to a temperature T”, it must be understood that the coating does not decompose under the effect of heat at this temperature T, in particular does not burn, and that it is sold as being usable at this temperature.

By “preformed” we must understand that the film is already cohesive before being applied to the nail. The opaque coating may be a film, preferably self-adhesive, temperature resistant, preferably resistant to a temperature of at least 60°C, better still at least 80°C, even better still at least 100°C, preferably at least 150°C, and very preferably at least 200°C, better still at least 250°C, even better at least 300°C, for example a black adhesive Kapton film. This film may initially be present on a non-stick support sheet. The thickness of the film is preferably greater than or equal to 50 microns, better still 100 microns. The thickness of the film is for example less than 1mm, preferably being between 100 and 150 microns. Preferably, plastic materials of class H or above are used (according to the IEC 60085 standard on the thermal class of insulators) which can withstand, for example, 327°C for PTFE and 400°C for Kapton. Certain heat-resistant polyamides can also be used, among other usable materials.

The absorbent nature of the coating may be due to the presence of black or dark pigments or dyes, for example mineral pigments. The coating may include graphite or carbon nanotubes, the invention not being limited to a particular coating.

Preferably, the film is precut substantially in the format of the nail to be treated, or in the format of a part of the nail, thus forming a patch in one or more parts to be applied to the nail. In particular, it is possible to position on the nail at least two pre-cut parts, each having a rounded edge which can be adjusted at the time of gluing on the nail to best match the shape of the edge thereof, the two patches being covering each other on the nail. This overlap, for example in the middle of the nail, allows the edges of the nails to be well covered. Patches can be cut manually or using any suitable instrument or device.

Although the use of a preformed film constitutes a particularly rapid and effective means of preparing the nail, it is still possible, without departing from the scope of the invention, to apply the coating in the fluid state to the nail, using using an applicator. For example, the coating is formed by drying a composition applied in the fluid state to the nail, for example an absorbent varnish resistant to temperature and comprising a dispersion of an opaque pigment in a binder, the pigment being of preferably dark in color, in particular black, for example a metal oxide, in particular iron, or carbon. This varnish can be film-forming, so that it can be removed by peeling. It may still be dispersible in water, to facilitate its removal. The binder of the varnish is preferably chosen to have the necessary temperature resistance, in particular to resist a temperature greater than or equal to 60°C, better at 80°C, even better at 100°C, better at 150°C, preferably at 200°C, better at 250°C, even better at 250°C.

It is also possible to apply an opaque coating to the nail in the form of an ink or a powder, for example using a felt-tip pen with absorbent ink, preferably of a dark color, better still black, for example black indelible ink. A disadvantage of using such an ink may then be the need to use a solvent for its removal, so the use of a coating in the form of a preformed film is preferred.

The absorbent coating can, if necessary, be deposited on a previously applied varnish, in order to be more easily removable by peeling or cleaning. This other varnish can be transparent. This other varnish is temperature resistant, and preferably withstands a temperature of 60°C, better still 80°C, even better 100°C, better 150°C, preferably 200°C and more preferably 250°C. vs.

Preferably, the method of preparing the nail comprises the step of abrading the surface of the nail to be treated prior to applying the absorbent coating. This smoothes the surface of the nail and reduces the thickness of the nail. Smoothing makes it possible to improve the quality of thermal contact of the coating with the nail, particularly when the coating is in the form of a preformed film. Sanding the nail can be carried out so as to have a remaining nail thickness of between 1 and 2mm, better around 1mm, over substantially the entire surface of the nail, which will be covered by the absorbent coating.

Particularly in the case where the light emitted is generated by at least one flash lamp, the nail is preferably positioned at a certain distance from the light exit window, in order to illuminate the entire area relatively uniformly. coating present on the nail. The method can thus include the step of positioning a support such that the nail is located at a distance of between 1 and 6 cm, in particular 2 and 5 cm, from the light exit window. Preferably, in the case of a laser source, the light output window can be positioned and the divergence of the beam chosen such that each laser pulse irradiates the entire surface of the absorbent coating present on the nail. The exit window can be placed at a distance of 0 to 20cm, for example, from the surface of the covering.

Preferably, the entire skin surface exposed to light is best protected, and it is thus possible to place a protective screen above the skin of the finger, in particular a sheet of a flexible and reflective material, in particular a sheet of white paper or textile. There may remain areas of skin unprotected from light, but preferably not located in the immediate vicinity of the nail. For dark skin, it is best to mask the skin completely.

When only one nail is to be treated, the finger wearing this nail can be isolated from the other fingers by a protective screen, in particular a sheet of a flexible and reflective material, in particular a sheet of white paper or textile.

When we prepare several nails with a view to treating them simultaneously, in particular two or three, or even all those of the foot, we can position the exit window so as to be able to simultaneously expose these nails to the emitted light.

Interdigital separators can be placed between the fingers, if necessary.

Once the treatment has been carried out, the absorbent coating can be removed, for example by simply peeling in the case of a preformed adhesive or electrostatically adhering film.

The invention also relates, according to another of its aspects, to a method for improving the appearance of at least one nail, comprising the step consisting of preparing the nail by implementing the method according to the invention as defined above, and to subject the nail thus coated to at least one pulse, and better still at least one burst of light pulses.

Each pulse can have a fluence, measured on the coating, between 0.1 and 10 J/cm ² , better between 0.5 and 5J/cm ² , even better between 0.5 and 2 J/cm ² , for example example of the order of 1J/cm ² . For example, the coating on the nail is subjected to an energy per cm ² of between 5 and 30J for the total duration of the burst, this duration being for example between 1 and 10s, better still between 2 and 10s, for example between 3 and 6s.

To obtain 1J/cm ² in the case of an IPL generating divergent polychromatic light, the fluence at the output of the IPL head can be of the order of 4 times greater, for example of the order of 4J /cm ² . Due to the distance between the IPL head and the coating and the divergence of the beam, the fluence measured on the coating is less, for example approximately 4 times lower.

The surface power density, measured on the coating, is for example on average during the burst between 0.5 and 10 W/cm ² , better between 1 and 10 W/cm ² , even better between 1 and 5 W /cm ² . For example, at 3Hz three flashes of 4J/cm ² each are emitted per second at the output of the device, which corresponds to 12J/cm ² per second, but if taking into account the distance from the nail the latter in receives for example approximately 4 times less, we have a surface power density of 3W/cm ² .

It is possible to treat only one nail at a time. We can also simultaneously expose at least two nails to the light pulse, as mentioned above.

Preferably, the nail is subjected to a number of light pulses of between 2 and 100, better still between 2 and 50, in particular between 5 and 20.

The frequency of emission of the light pulses can range from 1 to 10 Hz, preferably from 1 to 5 Hz, in particular 2 to 4 Hz. There can be approximately 1/f in s between each flash, the duration of a flash being very short (of the order of ten milliseconds). For a relatively fast frequency, the temperature of the nail does not have time to decrease appreciably between two successive flashes, and thus tends to increase progressively during the flashes of the burst, to become maximum at the end of the last flash of the burst. the blast.

After the emission of a burst, the nail is preferably allowed to cool for a period of at least 30 seconds, better still for at least 1 minute, even better for a period of between 1 and 5 minutes, before subjecting it to a new burst.

The nail may only be subjected to two successive bursts during a treatment session. Two treatment sessions can be spaced at least one week apart. The nail can be subjected to a greater number of bursts if necessary.

The light can be emitted by at least one polychromatic flash lamp (IPL) or by a laser. Using an IPL treatment device with a flash lamp is convenient because it allows you to easily treat several nails simultaneously.

During treatment, the maximum temperature measured on the surface of the coating can exceed 60°C, better still 80°C, even better 100°C, better 150°C, better 200°C, preferably being between 150°C and 300°C. °C. A temperature greater than 150°C, better still 180°C, even better 200°C, is preferably reached for a duration of at least 0.1s, better still for a duration of between 0.1 and 0.5s, even better for a duration of between 0.1 and 0.3s. A temperature above 150°C is preferred, because it allows the treatment to be shortened while still being effective. A lower temperature, associated with a longer treatment time, can be used when the power of the light source is lower, while ensuring that it remains below the burn threshold.

• Un dispositif d’émission de lumière pulsée permettant d’exposer au moins un ongle à traiter à au moins une impulsion lumineuse, mieux à au moins une rafale d’impulsions lumineuses,
• au moins un revêtement à absorbant la lumière émise par le dispositif, à appliquer sur le ou les ongles, de préférence un revêtement de réflectivité inférieure à 50% et/ou de transmissivité inférieure à 50%, notamment un revêtement de couleur sombre, ou un applicateur d’un tel revêtement, et dont la température de surface est apte à dépasser 60°C, mieux 80°C, encore mieux 100°C ou 150°C, mieux 200°C, sous l’effet de la lumière émise par le dispositif.

The invention also relates, according to another of its aspects, to a system for the treatment of nails, in particular for the implementation of the treatment process as defined above, comprising:

• A pulsed light emitting device making it possible to expose at least one nail to be treated to at least one light pulse, better still to at least one burst of light pulses,
• at least one coating absorbing the light emitted by the device, to be applied to the nail(s), preferably a coating with reflectivity less than 50% and/or transmissivity less than 50%, in particular a dark colored coating, or a applicator of such a coating, and whose surface temperature is capable of exceeding 60°C, better still 80°C, even better 100°C or 150°C, better still 200°C, under the effect of the light emitted by the device.

Each light pulse may exhibit all or part of the characteristics mentioned above.

The absorbent covering may have all or part of the characteristics already mentioned above. The coating may in particular have a transmissivity less than or equal to 20% and/or an absorptivity greater than or equal to 50%. The system may thus comprise an opaque film absorbing the light emitted by the device, preferably dark in color, in particular black, resistant to a temperature of at least 60°C, better still at least 80°C, even better at least 100°C or 150°C, preferably at least 200°C, better still at least 250°C, even better 300°C, or even 350°C or 400°C, in particular in PTFE or polyimide, particularly in Kapton.

This film is preferably covered on its inner side to be applied to the nail with a pressure-sensitive adhesive. Alternatively, it has no adhesive and adheres electrostatically.

The film is preferably pre-cut to form a patch in the shape of a nail or part of the nail, or a set of patches each pre-cut in the shape of a nail or part of the nail , especially with parts intended to overlap on the nail. The film can be precut to form at least one patch having a D-shaped contour for example.

It is thus possible to have on a support, in particular non-stick, a set of patches in particular self-adhesive or electrostatically adhering to the nail, resistant to heat, each in the shape of a D, grouped in pairs on the support, two patches of a pair being intended to be placed on the same nail with an overlap between them.

Where appropriate, the system may include an applicator for applying the coating in a fluid state to the nail, for example a brush or felt tip type applicator.

The system may include an applicator of a reflective coating, in particular white, to form a reflective screen on the skin at the periphery of the nail.

The system may include a device for mechanically abrading the surface of the nail, in particular a nail or pedicure grinder.

The device may have emission characteristics such that the light makes it possible to raise the temperature of the absorbent coating present on the nail during the burst and/or at the end thereof to a temperature greater than 60°C, better at 80°C, even better at 100°C, preferably at 150°C, better at 180°C, even better at 200°C.

Preferably, the pulsed light emitting device makes it possible to emit a burst of light pulses at a frequency of between 0.5 and 20 Hz, better still between 1 and 5 Hz, each pulse having such a fluence, taking into account the distance separating an exit window of the device from the coating during use, whether it is between 0.5 and 5 J/cm ² at the surface of the coating, better still 0.5 and 2 J/cm ² , the number of pulses being preferably between 2 and 20, better still between 5 and 20, in particular between 10 and 20.

Advantageously, the emission device emits substantially between wavelengths 650nm and 1200nm, with for example a peak around 875nm, the system comprising a pair of protective glasses or a protective mask for the operator, comprising a filter absorbing the light emitted by the emission device, this filter having a transmission factor less than or equal to 1% beyond approximately 650nm. Preferably, the absorbent filter of the glasses is blue in color.

This allows the operator using the device not to be dazzled by the light emitted, and thus to be able to easily control the application of light during the implementation of the treatment.

The system advantageously comprises a support for maintaining an exit window, through which the light exits the device, at a predefined distance from a receiving surface of the nail to be treated. The nail can be positioned on this receiving surface, under the light exit window.

This distance is for example between 1 and 6 cm. The surface of the absorbent covering can thus be at a distance of between 0 and 5 cm from the exit window, for example. The distance can be chosen depending on the divergence of the light, to completely cover one nail, or even two, or even more. In the case of a laser, whose divergence is adjustable, we can have a more distant output window, if necessary.

The support may comprise a sole defining the aforementioned receiving surface, and a raised part under which the foot can be engaged, provided with at least one opening under which at least one of the nails can be arranged, the optical head being placed in the opening or above. In an example of implementation, the optical head has an optical conduit whose dimension allows it to be engaged in the opening, the optical head also remaining abutting on the support. The opening may be kidney-shaped, and extend over all of the toenails, such that the operator can move the conduit into the opening during treatment to treat several toenails in succession.

The support may include at least one interdigital separator arranged so as to engage between two fingers when the nail to be treated is placed under the exit window. Such a separator can help to correctly position the nails in relation to the light exit window. The pulsed light emitting device may include at least one flash lamp or a laser.

The emitting device may include a control panel making it possible to adjust the characteristics of the light emitted as a function of the pathology and/or at least one characteristic of the nail, such as its thickness, this control panel allowing by example of selecting a “nail treatment” preset when other applications are possible (e.g. hair removal). For a thicker nail, the surface power can be increased and/or the number of flashes greater.

• une fenêtre de sortie de la lumière,
• un support pour maintenir une distance prédéfinie entre la fenêtre de sortie et une surface de réception du doigt portant l’ongle à traiter.

The invention also relates, according to another of its aspects, to a device for treating nails by emitting light pulses, comprising:

• a light exit window,
• a support for maintaining a predefined distance between the exit window and a receiving surface of the finger carrying the nail to be treated.

This distance can be adjustable, if necessary, so as to adjust it for example to the size of the finger to be treated (big toe or other toe for example). This distance can be such that the gap between the exit window and the covering is between 0 and 6 cm, for example between 2 and 6cm.

The support can be made of metal or any other material, for example a thermoplastic material. The support can be made, where appropriate, from a transparent thermoplastic material, or include at least one transparent part, making it possible, for example, to monitor the correct positioning of the nail during treatment.

The support can be made with a kidney-shaped opening, arranged so as to overlap all the nails of a foot, making it possible to slide an optical conduit from the treatment head inside, this optical conduit defining the exit window , to successively treat more nails of the same foot.

The invention also relates to a range of supports thus defined, of different sizes, allowing the operator to choose the support adapted to the size of the foot to be treated.

The invention also relates to a support intended to allow the treatment of nails by a treatment device by emission of light pulses, comprising a part configured to receive an optical head of the device, the support providing a reception zone of at least one finger such that the nail of this finger is positioned to receive the light emitted by an exit window of the light emitted by the optical head, this positioning preferably being such that the exit window is located at a distance between 1 and 6 cm, better between 3 and 6 cm from a surface on which the finger is positioned. This support advantageously comprises at least one interdigital separator.

The invention also relates to a support intended to allow the treatment of nails by an optical head of a treatment device by emission of light pulses, in particular for the implementation of the treatment method according to the invention, comprising a sole defining the receiving surface, and a raised part under which the foot can be engaged, provided with at least one opening under which at least one of the nails can be placed, the optical head of the device being able to be placed in the opening or above so as to emit towards the nails. The opening may be kidney-shaped, and extend above all the toenails. The opening can be of dimensions chosen to guide an optical conduit of the optical head, in a sweeping movement of the different nails located under the opening.

The invention also relates, according to another of its aspects, to a set of patches to be positioned on nails to be treated using a device for emitting light pulses, these patches being preferably self-adhesive, pre-cut with the shape of a nail or part of a nail, and made from an absorbent film within the meaning of the invention, preferably dark in color, preferably black, resistant to a temperature of at least 60°C, better still at least 80°C, better still at least 100°C or 150°C, preferably at least 200°C, better still at least 300°C, preferably in polyimide or PTFE. The set of patches may include one-part patches and two-part patches, in particular D-shaped each, as mentioned above, intended to overlap on the nail, of different sizes. All the patches can be placed on a support, preferably non-stick treated, in a sufficient number to treat all the nails of a hand or foot. The absorbent film preferably has a reflectivity of less than 50%, better than 20%, and/or a transmissivity of less than 50%, better than 20%, with respect to the light emitted by the pulse emitting device. luminous. This film appears preferably opaque to the naked eye, when observed in daylight.

The invention also relates to a nail preparation kit, comprising a set of patches as defined above and an applicator of a reflective coating, in particular white, preferably water-dispersible.

Such a kit may also include a set of single-use abrasives, in particular in the form of abrasive cylinders, arranged to be mounted on a sander to abrade the nail before applying the film.

The kit may also include the support according to the invention, as defined above.

The kit may also include a vacuum cleaner to suck up the dust emitted when sanding the nail.

The kit may also include a solution for cleaning the sanded nail before applying the coating, in particular an aqueous-alcoholic solution.

The invention can be better understood on reading the detailed description which follows, non-limiting examples of its implementation, and on examining the appended drawing, in which:

There schematically represents an example of a processing device according to the invention,

there represents in schematic and partial section a nail provided with a coating according to the invention,

there illustrates the positioning of the nail under the light exit window,

there is a block diagram illustrating different stages of the treatment method according to the invention,

there illustrates the sanding of the nail,

there illustrates the protection of the skin environment of the nail,

there illustrates finger protection,

there represents a set of masks for making the coating on the nail,

there illustrates the possibility of superimposing several pieces of film on the nail,

there represents an example of support that can be fitted to the treatment head,

there illustrates the propagation of heat within the nail, at different distances from the surface, as a function of time,

there represents a support variant,

there represents a so-called SFL emission spectrum of a treatment device by pulsed polychromatic light emission, and

there represents an example of transmission spectrum of blue glasses adapted to an IPL treatment device having the SFL spectrum of the .

detailed description

We represented at the a device 1 for treatment by emission of light pulses, comprising a base station 2, provided with a user interface 3, and a treatment head 4 (also called a handpiece) connected by a flexible 5 to the base station.

The device 1 is for example an IPL type pulsed light machine, the treatment head 4 comprising at least one flash lamp. The machine can be specific to nail treatment, or configurable and have other applications, for example hair removal.

Glasses 6 can be used in conjunction with the machine, in accordance with the teaching of application EP15738647.5 in the name of the applicant.

The emitted light may have the spectrum illustrated in , and the glasses 6 the spectral transmittance of the .

This allows the operator using the device not to be dazzled by the light emitted, and thus to be able to easily control the application of light during the implementation of the treatment.

The treatment head 4 can contain the flash lamp(s), as is conventionally the case for an IPL type machine.

The treatment head 4 has an optical guide 7, one end of which defines a light exit window 8, as illustrated in Fig. . The nail O to be treated is placed under this exit window 8, with a distance d between the nail and the exit window, for example between 3 and 6 cm.

In accordance with the invention, a coating 16 significantly absorbing the light emitted by the exit window 8 covers the nail. This coating preferably has a reflectivity of less than 50% and/or a transmissivity of less than 50%, so as to heat up significantly under the effect of flashes of light.

This coating 16 is preferably constituted by a film of an opaque heat-resistant plastic material, for example a polyimide (Kapton) or PTFE, black in color. This film can be adhesive or adhere to the nail electrostatically. The transmissivity measured with the Joule meter is for example 13% for polyimide and 6% for PTFE, for given black colored films, suitable for the implementation of the invention.

The nail treatment process includes, as illustrated in , a first step in preparing the nail to reduce its thickness and smooth its surface. This operation is for example carried out using a grinding wheel 15 of portable tools, as illustrated in .

Then, in step 22, coating 16 is applied to the nail.

For example, a coating 16 is used in the form of a patch pre-cut in the shape of the nail, supplied on a non-stick support 18, as illustrated in .

The support 18 can carry patches 16 of different formats, to adapt to the size of the nail. Some patches may only correspond to part of the surface of the nail, which is the case for example for patches 16a and 16b. It is possible to position two patches on the nail with an overlap between them, as shown in the . In this case, we can start by positioning a patch starting from one edge of the nail, then the other patch is positioned starting from the opposite edge, and stuck on the first in the overlapping area.

Once the nail O to be treated is provided with the absorbent coating 16, it is possible in step 23 to protect the skin in its region in contact with the nail around it, by depositing on the skin a reflective coating 17, as illustrated in . This coating 17 is for example a water-dispersible white ink, applied by means of an applicator 18, for example of the applicator tip type.

It is also possible to protect part of the skin of the finger using a white sheet 19 of a flexible material, as illustrated in .

The light treatment takes place in step 24, and consists of exposing the coating to one or more bursts of flashes in the example considered. At the end of each burst, the user can feel the heat brought to the nail. Step 24 can be repeated as indicated above. During treatment, the nail is preferably kept at a predefined distance from the light exit window of the treatment head 4, for example using a wedge interposed between the finger and the handpiece, or better, dedicated support, as detailed below.

Then, a final step 25 may consist of removing the coating 16, by peeling for example, as well as the white coating, by washing the finger.

This last step can take place on site or at the home of the person being treated, if applicable.

We represented at the an example of support 30 intended to maintain the light exit window at a predefined distance from the toenails. It has a sole 34 defining a receiving surface of the foot, and a raised part 35 connected to the sole 34 and under which the foot is engaged, provided with an opening 31 positioned above the nail(s) to be treated, for the passage of the light emitted by the head 4 of the device towards the nail(s). The opening 31 can have a shape allowing the optical guide 7 of the head to be engaged there, while maintaining the latter at a predefined distance from the sole 34. In the example illustrated, the opening 31 is kidney-shaped, and can guide the optical conduit of the head 4 of the device in a sweeping movement of the toenails. For example, the operator begins the treatment near one end of the opening 31, treats a nail or two, then moves the conduit in the guide to treat the next nail or nails.

One or more interdigital separators 32 can be used, where appropriate, by being arranged between the toes.

The support can, if necessary, be arranged to be fixed removably on the treatment head 4, for example by a connection by snap, slide or other, for example by screwing.

As an example, we represented in the an example of such a support 40. We see that this support 40 can include interdigital separators 32.

We prepare a nail affected by mycosis by sanding it to reduce the thickness of the nail to 1-2mm; sanding can be done with a nail grinder, equipped with a single-use abrasive cylinder. The nail can be cleaned with alcohol. Then, a coating consisting of a black self-adhesive Kapton film is applied to the nail, and the skin around the nail is protected as described above. The coating may be formed from two D-shaped patches, arranged so as to overlap on the nail at their straight edges.

The machine used in this example is of the IPL type and emits polychromatic light with the SFL spectrum of the . The operator and the person being treated wear blue glasses, the latter blocking almost all of the radiation emitted by the machine by having the spectral transmission factor of the .

The nail is subjected to two successive bursts of flashes at a frequency of 3 Hz. Each burst has 14 flashes of 4J/cm ² each at the exit of the head, which is located at a distance of 3cm from the nail. The total duration of each burst is approximately 5s. The two bursts are spaced approximately 2 minutes apart. The fluence on the coating is approximately 4 times lower than at the exit from the head, or approximately 1J/cm ² . The average power density on the coating is approximately 3 W/cm ² . The surface temperature of the coating, measured with a thermal camera, exceeds 200°C for approximately 0.2s, at the end of the burst.

The photo-thermal effect has three phases. There is first conversion of light into heat on the surface of the coating, then transfer of this towards the interior of the tissues, and finally a biological and cellular reaction. The spectral absorption coefficient of the irradiated surface, associated with the emission spectrum of the source, determines the percentage of photons absorbed and converted into heat. Heat transfer occurs by thermal conduction.

Heat travels from the surface of the coating in a wave, as shown in Figure . In this figure, the temperature is shown as a function of time, for different depths from the surface of the nail.

We see that on the surface of the nail, in contact with the coating, the temperature increases very quickly after the flashes to reach nearly 180°C, then decreases due to the diffusion of heat in the material of the nail. (curve A). As we move away from the surface of the nail, the curve becomes wider and the maximum temperature decreases (curve B). At the interface between the nail and the underlying tissue (curve C), the maximum temperature is approximately 70°C, which is insufficient to cause a burn given the duration during which this temperature is reached, but sufficient to destroy the germs responsible for mycosis, located in the thickness of the nail and below the nail.

The invention, with the preparation of the nails that it involves, makes it possible to considerably improve nail treatments using light, by making it possible to work in temperature/time couple zones never before reached, in particular higher temperatures for shorter times.

However, the invention also makes it possible to treat nails with lower maximum surface temperatures of the coating and longer times, the disadvantage of the longer treatment time being compensated by the possibility of using a treatment device having lower light output and fluence.

Of course, the invention is not limited to the use of an IPL machine with a flash lamp and a laser or any other suitable source can also be used as a light source.

Other types of coatings that absorb the light emitted during processing can also be used, for example applied in the form of an opaque heat-resistant varnish.

Claims (12)

Set of patches (16; 16a, 16b) to be positioned on nails to be treated using a device for emitting light pulses, these patches being pre-cut with the shape of a nail or part of a nail and made in a coating absorbing the light emitted by the device, resistant to a temperature of at least 60°C. Set of patches (16; 16a, 16b) according to the preceding claim, the patches being pre-cut in a D shape. Set of patches (16; 16a, 16b) according to any one of the preceding claims, the coating being resistant to a temperature of at least 80°C, even better at least 100°C or 150°C, even better at least 200°C, better still at least 250°C, even better at least 300°C. Set of patches (16; 16a, 16b) according to any one of the preceding claims, the patches being self-adhesive. Set of patches (16; 16a, 16b) according to any one of the preceding claims, the coating (16) consisting of a preformed film, preferably opaque. Set of patches (16; 16a, 16b) according to the preceding claim, the film being a dark colored film, in particular black, in particular made of PTFE or polyimide. Set of patches (16; 16a, 16b) according to any one of the preceding claims, the coating (16) having a reflectivity less than 50%, better still less than 20%, and/or a transmissivity less than 50%. Set of patches (16; 16a, 16b) according to any one of the preceding claims, the coating (16) having a transmissivity less than or equal to 20%, in particular with respect to an SFL spectrum. Nail preparation kit, comprising a set of patches (16; 16a, 16b) according to any one of the preceding claims and an applicator (18) of a reflective coating (17), in particular white, preferably dispersible with water. Kit according to the preceding claim, further comprising single-use abrasives, in particular in the form of abrasive cylinders for sanders (15), for abrading the nail before applying the coating. Kit according to one of the two preceding claims, further comprising a support (40), the support comprising a part configured to receive an optical head (4) of the light pulse emitting device, the support providing a zone of reception of at least one finger such that the nail of this finger is positioned to receive the light emitted by an exit window of the light emitted by the optical head, this positioning preferably being such that the exit window is located at a distance between 1 and 6 cm, better 3 and 6 cm, from a surface on which the finger is positioned. Kit according to claim 9 or 10, further comprising a support (30), the support comprising a sole (34) defining the receiving surface, and a raised part (35) under which the foot can be engaged, provided with at at least one opening (31), preferably kidney-shaped, under which at least one of the nails can be arranged, an optical head of the light pulse emitting device being able to be arranged in the opening (31) or above so as to emit towards the nails.