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WO2013093381A2 - Method for the microscopic and macroscopic analysis of wound healing progress - Google Patents

Method for the microscopic and macroscopic analysis of wound healing progress Download PDF

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Publication number
WO2013093381A2
WO2013093381A2 PCT/FR2012/053069 FR2012053069W WO2013093381A2 WO 2013093381 A2 WO2013093381 A2 WO 2013093381A2 FR 2012053069 W FR2012053069 W FR 2012053069W WO 2013093381 A2 WO2013093381 A2 WO 2013093381A2
Authority
WO
WIPO (PCT)
Prior art keywords
wound
exudate
chamber
healing
inflammatory
Prior art date
Application number
PCT/FR2012/053069
Other languages
French (fr)
Other versions
WO2013093381A3 (en
WO2013093381A9 (en
Inventor
Christophe DARDENNE
Bernard Pipy
Agnès COSTE
Marielle BOUSCHBACHER
Christelle Laurensou
Original Assignee
Laboratoires Urgo
Societe De Developpement Et De Recherche Industrielle
Universite Paul Sabatier Toulouse Iii
INSERM (Institut National de la Santé et de la Recherche Médicale)
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from FR1162295A external-priority patent/FR2984722B1/en
Priority claimed from FR1162344A external-priority patent/FR2984719B1/en
Application filed by Laboratoires Urgo, Societe De Developpement Et De Recherche Industrielle, Universite Paul Sabatier Toulouse Iii, INSERM (Institut National de la Santé et de la Recherche Médicale) filed Critical Laboratoires Urgo
Publication of WO2013093381A2 publication Critical patent/WO2013093381A2/en
Publication of WO2013093381A9 publication Critical patent/WO2013093381A9/en
Publication of WO2013093381A3 publication Critical patent/WO2013093381A3/en

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Classifications

    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61FFILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
    • A61F13/00Bandages or dressings; Absorbent pads
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61FFILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
    • A61F13/00Bandages or dressings; Absorbent pads
    • A61F13/00051Accessories for dressings
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B10/00Other methods or instruments for diagnosis, e.g. instruments for taking a cell sample, for biopsy, for vaccination diagnosis; Sex determination; Ovulation-period determination; Throat striking implements
    • A61B10/0045Devices for taking samples of body liquids

Definitions

  • the present invention relates to a method of analyzing the progression of wound healing in real time by means of a medical device, non-invasive and adapted, which protects the wound and allows me to observe my croscopic progress healing of a wound as well as collecting wound exudates in order to carry out cell monitoring, but also biochemical and molecular analyzes of the metabolites and microorganisms contained in said exudates.
  • Wound healing is a natural pathophysiological process, with human and animal tissue capable of repairing localized lesions through their own repair and regeneration processes.
  • the speed and quality of wound healing depend on the general condition of the affected organism, the etiology of the wound, the condition and location of the wound, and whether or not it occurs. infection, as well as genetic factors that may or may not predispose to healing disorders.
  • the natural healing of a wound occurs mainly in three successive phases, each of these phases being characterized by specific cellular activities that advance the repair process according to precise chronological sequences: the inflammatory phase, the granulation phase (or phase proliferative), and the ripening phase, giving the final appearance of the scar.
  • the first phase begins with the rupture of the blood vessels which triggers the formation of a clot (blood coagulation) mainly composed of fibrin and fibronectin, and which will constitute a temporary matrix.
  • a clot blood coagulation
  • This matrix partially fills the lesion and will allow the migration within the injured area of the inflammatory cells recruited to ensure the debridement of the wound.
  • the platelets present are going also release factors (eg cytokines, growth factors) allowing the recruitment of cells involved in the scar process.
  • This phase is characterized by infiltration and activation on the site of the lesion, numerous inflammatory cells (such as neutrophils), but also cells ensuring the cleaning of the wound or debridement (such as macrophages).
  • the second phase corresponds to the development of the granulation tissue.
  • the fibroblasts are activated and will differentiate into myofibers with significant contractile properties, generated by the actin microfilaments, allowing contraction of the wound. These microfilaments are expressed by a protein: smooth muscle actin.
  • These myofibroblasts therefore play a major role in the formation and maturation of the granulation tissue that will lead to the healing of the lesion. There is then migration of keratinocytes and reconstruction of the epidermis.
  • This phase is initiated by a decrease in the inflammatory state of the lesion accompanied by an apoptosis of the inflammatory cells.
  • the third phase of the process is a mainly maturation stage aimed at reconstructing a functional tissue that is as identical as possible to the original tissue.
  • the previously formed granulation tissue is therefore remodeled.
  • Part of the extracellular matrix is digested with proteases (essentially matrix metalloproteases and elastases), and progressive reorganization of the extracellular matrix is observed.
  • type III collagen predominant in the granulation tissue, is replaced by type I collagen, the main matrix component of the dermis.
  • the fibroblasts, myofibroblasts and vascular cells see their proliferation and / or their activity reduced. Then, the excess cells die by apoptosis. Parallel to the remodeling of the extracellular matrix and to the apoptosis of the surplus cells.
  • the inflammatory phase is an essential phase of healing and must be transient. In some cases, it may be prolonged by the presence of certain infectious agents such as Staphylococcus aureus or Pseudomonas aeruginosa or by a pre-existing pathology such as diabetes, an immune deficiency or even venous insufficiency.
  • the resolution of inflammation is a critical point that conditions the initiation of tissue repair. Disturbance of this phase will result in an abnormal prolongation of the inflammatory phase and result in the chronicity of the lesion by delaying tissue repair.
  • the resolution of inflammation is a dynamic phenomenon that involves the apoptosis of inflammatory cells, their elimination and the appearance of anti-inflammatory, chemotactic and angiogenic mediators.
  • the resolution phase is to analyze exudates from the wound (cells, mediators and metabolites). Indeed, inflammatory chronicity results in a larger influx of inflammatory cells, an excessive production of many cytokines and inflammatory chemokines and proteases that degrade the cell matrix. Conversely, the resolution phase involves the appearance of a certain type of macrophages responsible for the phagocytosis of apoptotic inflammatory cells. These macrophages are also involved in the production of mediators favoring the granulation phase as well as the tissue repair. Analysis of the exudate will allow the physician to evaluate the inflammatory phase and its resolution, and thus allow to choose to treat the wound with a therapeutic agent adapted to promote better healing.
  • wounds are covered with a bandage or compress to prevent contamination by infectious agents in the environment, but also to keep the wound in a moist environment that promotes healing.
  • this protection system does not allow to analyze the exudates and to visualize the cicatrization in time real.
  • the exudate accumulates in the dressing and saturates the absorbent medium of the dressing.
  • the dressing must therefore be changed regularly to prevent maceration of the wound, which implies a risk of contamination of the wound that is temporarily exposed to the open air.
  • the dressings may also adhere, even weakly to the wound, and thus induce lesions to the wound during their removal. These new aggressions cause a continuation of the inflammation, which has the consequence of prolonging the inflammatory phase and thus substantially modifying the kinetics of healing.
  • Implantable chambers have been developed to study the healing of dermal wounds in laboratory animals such as mice and pigs. However, these implantable chambers are inserted partially under the skin of the animal and are held in place by stitches. This method is therefore invasive, ie it has the major disadvantage of requiring a surgical procedure for implantation of the chamber partly under the skin of the animal and may therefore cause an inflammatory reaction in the subject in question. question, by creating tissue aggression during implantation. These tissue attacks will have harmful consequences on the good progress of the healing of the animal. In addition, these implantable chambers have essentially been developed to model the healing mechanisms in animals such as, for example, a mouse or pig. Thus, with such invasive chambers, it is impossible to perform reliable visual, cellular, biochemical and molecular monitoring of wounds, especially during the first days following the implantation of these chambers.
  • a first object of the present invention is a non-invasive method of analyzing the progression of wound healing which implements a device as described in patent application No. FR 11 62295 filed December 22, 2011. said method comprising the following steps:
  • the device used in the method according to the invention comprises in particular: a chamber having a side wall, an open bottom end and an upper end, an access opening being disposed on the upper end and / or on the side wall of said chamber, said device being intended to be in contact with the skin and to circumscribe the wound during its use via an interface.
  • said device comprises a chamber having a side wall, an open bottom end and an upper end, an access opening being disposed on the upper end and / or on the side wall of said chamber, said device further comprising a removable closure means of the chamber which fits on the access opening of the chamber and a holding element, possibly of tubular shape, circumscribed or inscribed in said chamber, open to both ends, said device being intended to be in contact with the skin and circumscribing the wound during its use via an interface which is an adhesive disposed on a skirt of flexible material, said skirt being held between the side wall of the chamber and the holding member.
  • the device used in the method according to the invention can in particular be considered as a passive device for collecting exudates, as opposed to an active device.
  • active device means a device where the exudates are harvested by the application of an effect or external stress, physical and / or mechanical, such as a negative pressure, such as for example vacuum devices or therapy devices by negative pressure, also called TPN.
  • Active and passive devices can also be differentiated by the quality of exudates harvested. Indeed, by introducing a mechanical and / or physical stress in the active device, the exudates harvested are of a larger volume, and thus there is a dilution of the various cells, mediators, or cellular factors contained in said exudates.
  • the cells found in the exudates can be dead and / or activated.
  • activated cells cells extracted from their natural environment found in a situation of stress and which can then lose, among other things, their functional abilities, which is, for example, the case for macrophages and neutrophils.
  • the advantage of the device used in the method of the present invention is therefore to allow the integrity and the functionalities of the different cell populations contained in the exudates resulting from the wound to be preserved. This gives a true "picture" of the wound.
  • the device used in the method of the present invention is a device for direct collection of exudates at the scar site.
  • Direct harvesting device means a device in which the exudates are directly taken from their source of emission, in this case in the vicinity of the wound, the exudate therefore not having to pass through a chamber. or related reservoir and / or absorbent material prior to removal of the device. Direct harvesting thus preserves the integrity and physiology of the wound and its environment, all without disrupting wound healing.
  • the device used in the method according to the invention is centered on the macroscopic and microscopic analysis of the exudates from the wound, but also the wound itself.
  • the device used in the method according to the invention is devoid of any absorbing means coming into contact with the exudate and the wound. This avoids maceration of the wound due to the saturation of said absorbent means by the exudate as may be the case with a dressing.
  • the absence of absorbent means prevents any entrapment or degradation of proteins, metabolites and cells present in the exudate, all with the objective of recovering pure exudates and without loss of cells and metabolites.
  • the device used in the method according to the invention is sealed at the level of the device / skin interaction zone of the subject. Thus, the exudate collected in the chamber can not escape through the edges of said device.
  • the sealing of said device is preferably provided by the juxtaposition of the tubular chamber and the holding member, the components between which is found inserted the skirt of flexible material.
  • the latter conferring in addition to the entire device conformability properties of good quality. Conformability of good quality means that the skirt of flexible material fits on the surface to which it is attached, taking a suitable form.
  • the device once fixed on a flat surface or a non-flat surface makes it possible to retain the entire volume of the exudates collected at the wound level. It is the same for the volume of a solution which is injected into said device through a septum found on the closure means or on the chamber of the device.
  • a lip made of a conformable semi-rigid material possibly with shape memory, such as in particular PMMA (polymethyl methacrylate), POM-C (polyacetal copolymer), PEKK (polyether ketone ketone), silicone, polyurethane or polyamide, on the lower part of the holding member, which lip can be useful when the surface of the skin on which the device is attached is not flat , thus making it possible to ensure even further the sealing of said device.
  • shape memory such as in particular PMMA (polymethyl methacrylate), POM-C (polyacetal copolymer), PEKK (polyether ketone ketone), silicone, polyurethane or polyamide
  • the device used in the method of the present invention combines sealing and conformability by means of the juxtaposition of the tubular chamber, the holding element and the skirt of flexible material.
  • the sampling device is positioned in such a way as to circumscribe the wound without coming into contact with the wound, so that said device is fixed on the healthy skin around the wound, for example by virtue of an interface that is adhesive.
  • the adhesive interface may consist of an adhesive which is applied either directly to the device just before positioning it around the wound, or on a skirt of conformable compliant material, or the device or skirt may be pre-coated by a adhesive during their manufacture. In this case, the adhesive interface is advantageously protected by a protective barrier which must be removed before positioning the device around the wound.
  • the positioning step and in order to improve the behavior of the device around the wound, it is possible to coat the periphery of the interface of the device as well as the skin in the vicinity of the wound and close to the device by the adhesive.
  • the sampling device used in the method according to the invention comprises a closure means which allows easy access to the wound without removing the device.
  • Said closing means is fixed on the upper part of the chamber of the device or on the side wall of the chamber of the device, in particular by a screw thread, a clip, a pin, a crimping means and / or a bayonet system .
  • the closing means of the device is placed back on the chamber of said device, for example by screwing it or by means of a pin inserted into adapted orifices placed on the closure means and on the chamber of the device.
  • the visualization of the wound allowing a good positioning of the device can also be performed without opening the device, looking through the closure means of said device, in particular when the closure means is made of transparent material and / or is provided with a transparent lens, possibly magnifying.
  • This positioning step of the device makes it possible to fix it around the wound temporarily and non-invasively.
  • the device must be attached to the skin sufficiently for the duration of the healing.
  • the second step of the method according to the invention is the macroscopic observation of the wound and / or the exudate.
  • the Applicant hears any analysis performed externally, that is to say non-invasively or without intervention on the site in question, the wound and / or exudate.
  • the macroscopic observation of the wound and / or the exudate comprises the determination of the physico-chemical parameters of said wound and / or said exudate.
  • physico-chemical parameters is meant, in the sense of the present invention, different sensory characteristics of the wound and / or exudate, such as in particular the appearance of the wound (color, texture, depth, area, odor) and / or the appearance of the exudate (color, odor, clarity, viscosity).
  • the macroscopic observation of the wound can thus consist of a visual or even olfactory follow-up of the state and progress of the healing of the wound.
  • a simple observation of the wound can be performed using a camera, a video camera, or simply thanks to the human eye.
  • a magnified observation can be performed using a magnifying glass, a dermoscope or in another register, via an application for "smartphone” as for example the application MOWA ("Mobile Wound Analyzer") .
  • an observation offering even better visual resolutions can be implemented using a two-photon microscopy, a Raman scattering, a confocal microscopy, an MRI, a high-frequency ultrasound, or by capillaroscopy.
  • This last type of technology allows a deep observation of the wound, of the order of a few hundred micrometers, which is impossible to the naked eye. It should be noted that standard monitoring means will be considered for each type of macroscopic visualization technique used.
  • One of the preferred embodiments of the present invention resides in a photograph that can in particular be made without opening the device when it is made of transparent material and / or is provided with a transparent lens, possibly magnifying. This embodiment is particularly easy to implement.
  • the photographing is carried out after removing the closure means of the device, said closing means being returned to the closed position on the device once the photograph is taken.
  • the frequency of taking photographs can be one photograph per day, which makes it possible to visualize the kinetics of the progression of the healing of the wound.
  • the different photographs are preferably taken with the same settings in order to be able to compare the photographs with each other.
  • the camera is positioned at the same distance from the wound and with the same angle for each photograph, for example using a photography bench.
  • the taking of the photograph can be followed or simultaneous with a comparison with one or more standard macroscopic tracking means.
  • the device calibration means such as in particular an object comprising graduations, and / or a color chart of well-defined hues.
  • the method that is the subject of the present invention makes it possible, through the use of said non-invasive device, to observe the wound as a whole, an aspect that can not be found in methods of use. a device negative pressure therapy or vacuum creation. Indeed, these are methods in which the use of an occlusive dressing or an interface that is also occlusive is recurrent, and therefore the total visualization of the wound is impossible. The wound is best visualized only partially using these methods.
  • biological analyzes are performed on the exudate to characterize and / or quantify the different cell populations contained. It is also possible to determine the presence but also to quantify the metabolites and / or microorganisms contained in said exudate.
  • the exudate contained in the device can be taken and said exudate can be analyzed.
  • the analysis may in particular be a more specific evaluation of the physicochemical parameters of the exudate taken with respect to the same parameters observed without removal of the exudate.
  • the parameters relating to the eigenvalues of said exudate pH, T ° C, color, odor, clarity, viscosity.
  • Said removal of the exudate may in particular be carried out by means of a pipette, provided with a suction means such as a cone, and / or a syringe, either after opening of the closure means of the device, or through a septum positioned on the side wall of the device chamber or on the closure means of the device.
  • the removal of the exudate is carried out through a septum.
  • the removal of the exudate through the septum makes it possible to preserve the sterility of the internal medium of the device vis-à-vis the external environment of said device.
  • the exudate is not absorbed by an absorbent material prior to sampling.
  • the exudate is not taken by a device applying a negative pressure to the wound, such as a vacuum pump.
  • the exudate contained in the device is too viscous to be easily removed by syringe, it can be advantageously make the exudate less viscous by injecting into the device a physiological solution, such as for example physiological saline or a dilute solution of sodium chloride.
  • a physiological solution such as for example physiological saline or a dilute solution of sodium chloride.
  • the Applicant hears all organic compounds likely to be found in a wound, such as for example, proteins (inflammatory or anti-inflammatory proteins, growth factors, extracellular matrix proteins such as collagen or fibrin). lipids (such as fatty acids, leukotrienes), amino acids, hormones, albumin, urea.
  • proteins inflammatory or anti-inflammatory proteins, growth factors, extracellular matrix proteins such as collagen or fibrin.
  • lipids such as fatty acids, leukotrienes), amino acids, hormones, albumin, urea.
  • microorganisms By microorganisms, the applicant hears all the microorganisms likely to be found on a wound, infected or not, such as, for example, bacteria (such as those composed of the genus Staphylococcus, for example, S.aureus, S. epidermidis, S.pyogenes, by the genus Enterococcus, for example E. faecalis, by the genus Pseudomonas, for example P. aeruginosa, by the Enterobacteriaceae family, of the E.coli type, Enterobacter sp., Proteus sp., Serratia sp., or by anaerobic bacteria such as Clostrium sp. or Bacteroides sp.), yeasts (Candida albicans), viruses (retroviruses, adenovirus), or parasites (ectoparasites, endoparasites, mesoparasites),
  • the Applicant hears all the cells likely to be found on a wound, such as in particular inflammatory cells (granulocytes), fibroblasts, or even keratinocytes.
  • inflammatory cells granulocytes
  • fibroblasts or even keratinocytes.
  • the removed exudate is then transferred to a suitable container, such as in particular a test tube or a septum-filled bottle.
  • a suitable container such as in particular a test tube or a septum-filled bottle.
  • the exudate is not in contact with the open air which prevents its contamination by external pathogens.
  • closure means If the closure means has been removed to take the exudate sample, said closure means is returned to the closed position on the device after sampling.
  • the biological analyzes that can be performed on the exudate are multiple and varied. Thus, from the first day of the implementation of the method according to the invention, it is possible to carry out a phenotypic and functional monitoring of cell populations, such as, in particular, inflammatory cells or cutaneous cells.
  • cell populations such as, in particular, inflammatory cells or cutaneous cells.
  • These analyzes carried out in particular using flow cytometry, make it possible to follow the various stages of the cicatrization, particularly the inflammatory phase, although the follow-up of the second phase, called the granulation or epidermization phase (called also proliferation phase) can also be realized.
  • These analyzes make it possible to verify that the granulation phase begins and that the inflammatory phase does not persist over time, which could hinder good healing.
  • Exudate analyzes can also be used to track mediators produced during the scarring, such as inflammatory cytokines (TNF- ⁇ , IL12, IL1- ⁇ , IL6, etc.) and anti-inflammatory cytokines (TGF- ⁇ and IL-10), lipid mediators such as leukotrienes, prostaglandins or even growth factors (VEGF, PDGF). These mediators can in particular be quantified by an ELISA assay. The analysis of metabolites, and more particularly of mediators contained in the exudate also makes it possible to follow the progress of the cicatrization.
  • mediators produced during the scarring such as inflammatory cytokines (TNF- ⁇ , IL12, IL1- ⁇ , IL6, etc.) and anti-inflammatory cytokines (TGF- ⁇ and IL-10), lipid mediators such as leukotrienes, prostaglandins or even growth factors (VEGF, PDGF).
  • TGF- ⁇ and IL-10 lipid mediators
  • the exudate contains an abnormally high level of inflammatory cytokine content
  • the prolonged presence of inflammatory cytokines in the wound can cause degradation of the cell matrix and induce chronicity of the wound.
  • the method according to the invention may also comprise an additional step of introducing an aqueous solution or not into the device.
  • solutions may in particular make it possible to perform a washing of the wound, for example a physiological saline-type standard solution, sodium chloride, sterile water, soapy water or a solution of Ringer's lactate.
  • a solution comprising an antibacterial agent and / or a therapeutic agent in order to treat the wound, in which case the bringing into contact of these solutions on the scar site will be prolonged, in comparison with the contacting a wash solution at the scar site without using a device.
  • a conventional physiological solution may be brought into contact with the wound, for example after the step of positioning the device.
  • the solution is allowed to act for a few minutes and removed from the device.
  • a solution containing a therapeutically active agent may be brought into contact with the wound, for example every day after the macroscopic wound observation step and / or exudate or possibly after the exudate analysis step.
  • the solution is left to act for several minutes to hours or days and then removed from the device if and only if the solution has not been fully absorbed into the wound.
  • the method comprises an additional step in which a solution comprising therapeutically active agents is brought into contact with the wound using said device.
  • the assets are chosen from:
  • antibacterials such as polymyxin B, penicillins, clavulanic acid, tetracyclines, minocycline, chlorotetracycline, aminoglycosides, amikacin, gentamicin, neomycin, silver and its salts (sulfadi azi silver).
  • antiseptics such as sodium mercurothiolate, eosin, chlorhexidine, phenylmercury borate, hydrogen peroxide, Dakin liquor, triclosan, biguanide, hexamidine, thymol, lugol, povidone iodine, merbromine, benzalkonium and benzethonium chloride, ethanol and isopropanol.
  • antivirals such as acyclovir, famciclovir, ritonavir.
  • antifungals such as polyenes, nystatin,
  • amphotericin B natamycin, imidazoles (miconazole, ketoconazole, clotrimazole, econazole, bifonazole, butoconazole, fenticonazole, isoconazole, oxiconazole, sertoconazole, sulconazole, thiabendazole, tioconazole), triazoles, allylamines, terbinafine, 1 amorolfine, naftifine, butenafine. pain-relievers such as paracetamol, codeine, dextropropoxyphene, tramadol, morphine and its derivatives, corticosteroids and its derivatives.
  • imidazoles miconazole, ketoconazole, clotrimazole, econazole, bifonazole, butoconazole, fenticonazole, isoconazole, oxiconazole, sertoconazole, sulcon
  • KSOS KSOS
  • sucralfate allantoin
  • collagen collagen or hyaluronic acid
  • Another object of the invention is a method for analyzing wound healing in an animal comprising the following steps:
  • animal is meant, in the sense of the present invention, an animal or the human being.
  • the animal in which it is desired to study the progression of cicatrization may especially be a mouse, a pig and / or a rat. It may also be the human being, in particular people suffering from a metabolic disorder or pathology (such as diabetes, immunodeficiency, malnutrition, or venous insufficiency) which influences the phenomenon of healing.
  • a metabolic disorder or pathology such as diabetes, immunodeficiency, malnutrition, or venous insufficiency
  • anesthesia can be performed by injecting an anesthetic solution that can be a mixture of ketamine and xylazine. After anesthesia of the animal, we wait for the time necessary for the anesthesia to take effect. If necessary, the animal is then mowed on the area where it is desired to create the wound. This step is a step that can be overcome in the case of the human being. Nevertheless, depending on the case, it can be adapted, and this by means of local anesthesia of the wound creation zone. We then proceed to the creation of a wound on the animal. In particular, the wound can be superficial or deep, that is to say it goes as far as the hypodermis or to the muscle tissue.
  • wounds can be of different natures according to the fields of study which are privileged.
  • the wound is created mechanically, chemically, thermally and / or by radiation.
  • the wound can be created mechanically using tools such as scissors, a cookie cutter or "biopsy punch".
  • tools such as scissors, a cookie cutter or "biopsy punch”.
  • the skin of the animal can then be pinched to be cut with a chisel or with a scalpel, following the line delimiting the cutaneous lesion or the skin can be stretched to exert a pressure on the skin. using a cookie cutter or "biopsy punch”.
  • Superficial wounds can also be created mechanically. In particular, a "stripping" can be done by affixing an adhesive and then removing it from the future area of creation of the wound.
  • a caustic solution sodium hydroxide, nitric acid (7) can be deposited on the part of the skin to be damaged. The concentration of the agent used and the duration of exposure will determine the depth of the wounds. This type of injury is similar to burns (hot and / or cold, electrical, radiation %) that can also be reproduced.
  • the depth and extent of the burn will depend essentially on the duration and physicochemical properties of the tools or solutions used.
  • depression systems may be employed to produce detachments (suction bubbles) or phlyctenes.
  • Crushing procedures can also be considered skin, but also ligation or vascular section procedures, to obtain ischemic wounds. It will also be possible to create a wound with a device emitting radiation, such as LASER or ⁇ or gamma ionizing rays.
  • the sampling device is then attached to the healthy skin around the wound by means of its adhesive interface as described above.
  • Macroscopic observation of the wound is preferentially performed by taking photographs of the wound as previously described.
  • the biological monitoring of the wound by sampling the exudate contained in the device and its analysis is performed as described above.
  • the method according to the invention implements a non-invasive device, it is possible to reliably monitor the mediators and metabolites produced as soon as the wound is created in the animal, which was not possible with invasive devices implanted under the skin of the prior art.
  • the method according to the invention may also comprise an additional step of washing the wound with a physiological solution comprising an antibacterial agent and / or a therapeutic agent, as described above.
  • a solution comprising an antibacterial agent may be placed in contact with the wound, for example after the step of positioning the device. The solution is allowed to act for a few minutes and removed from the device.
  • a solution containing a therapeutically active agent may be placed in contact with the wound, for example several minutes or even hours or days and this every day after the photographing step and / or after the stage of analysis of the exudate.
  • the solution is allowed to act on the site and removed from the device if and only if it has not been fully absorbed into the wound. This additional step can in particular make it possible to study the influence and the effectiveness of a therapeutically active agent on the healing of the wound of the animal.
  • Figure 1 is a cross sectional view of a device for implementing the invention.
  • Figure 2 is a photograph of a mouse on which a dorsal wound has been created.
  • Figure 3 is a photograph of the mouse of Figure 2 on which the chamber of a sampling device was placed on the healthy skin around the wound by an adhesive.
  • Figure 4 is a photograph of the mouse of Figure 3 on which the closure means was fixed to the device chamber by means of a pin.
  • Figure 5 shows different photographs of a wound on a healthy mouse, the photographs being taken at different time intervals from the day of wound creation (D0) to 14 days after wound creation (D14).
  • FIG. 6 represents the different results of the flow cytometric analysis of the cell populations contained in the exudate resulting from a wound on a healthy mouse, the analyzes being carried out at different time intervals starting from the first day after the creation. from the wound (J1) until the 7th day after the creation of the wound (J7).
  • FIG. 7 is a graph showing the amount of an anti-inflammatory cytokine (TGF- ⁇ ), measured by ELISA, contained in exudates from dorsal wounds in healthy mice.
  • TGF- ⁇ an anti-inflammatory cytokine
  • Example 1 Creation of a wound and placement of the device on the back wound of the mouse.
  • the mouse In order to create a wound on a mouse as photographed in FIG. 2, the mouse is first anesthetized by injecting a mixture of ketamine and xylazine intraperitoneally. Then, cut the skin of the mouse with a chisel, on its dorsal part.
  • the device (1) of FIG. 1 is placed on the mouse.
  • the device (1) consists of a tubular chamber (2) comprising a lateral wall (3), and two extremities, lower (4) and upper ( 5), open.
  • Said lower end (4) of the tubular chamber (2) has an outer collar (6) of flexible material.
  • the interface (7) of the device (1) consists of a thin layer of surgical glue applied to the lower surface of the collar (6) of the tubular chamber (2).
  • a closing means (8) of the device (1) is fixed to the upper part of the tubular chamber (2) by means of a pin (9).
  • the closure means is removed from the device by unhooking it.
  • the pin (9) is removed in order to remove the means of closure (8) of the device (1).
  • the lower surface of the flange (6) of the tubular chamber (2) is coated with a thin layer of surgical glue to form the interface (7) of the device.
  • the device (1) is positioned above the wound so as to circumscribe it. Sufficient pressure is applied on the upper part of the device (1) until the adhesive is completely taken on the skin of the mouse according to FIG. 2.
  • the outer surface and the periphery of the collar (6) are coated. device (1) as well as the skin near the surgical glue device until the adhesive is fully set as shown in FIG. 3.
  • the closure means (8) are placed on the device by inserting a pin (9). ) and inserting it into orifices placed on the chamber (2) of the device (1) and on the closing means (8) in order to hold these two elements together.
  • the device (1) is then fixed on the back of the mouse as photographed in FIG.
  • the analysis of the progression of the cicatrization of a wound is carried out in a healthy mouse on which a wound has been created according to example 1 and positioned a device (1) still according to example 1.
  • the mouse is anesthetized with a gas and arranged on a photography bench with regular graduations to perform a calibration.
  • the pin (9) is removed in order to remove the closure means (8) from the device (1).
  • the closure means (8) is replaced on the device by heating a pin (9) and inserting it into orifices placed on the chamber (2) of the device (1) and on the closing means (8) in order to maintain these two elements together.
  • One photograph per day is taken, from the day of the creation of the wound and for 14 days.
  • Example 3 Cellular monitoring of the advanced healing of a dorsal wound in a healthy mouse.
  • the analysis of the progression of the healing of a wound is carried out on a healthy mouse on which a wound has been created according to example 1 and positioned a sampling device according to example 1.
  • the mouse Before taking the exudate , the mouse is anesthetized with a gas. A physiological solution is injected into the syringe through a septum placed on the closure means of the device. The exudate diluted with physiological saline is aspirated and reinjected three times with the syringe so as to thoroughly wash the site of the wound and recover the maximum number of cells for analysis.
  • the diluted exudate is pipetted and transferred to a septum vial.
  • the cells are incubated for 15 minutes with Ly6g and 7/4 anti-mouse antibodies each coupled to fluorochromes. . Finally the cells of the exudate are washed again. The cell populations of the exudate are analyzed by flow cytometry. The data is acquired by a FACScalibur (BD Biosciences) cytometer using CellQuest Pro software.
  • Exudate sampling and flow cytometry analysis were performed 24 hours after wound creation and repeated daily for one week. The results, showing the different fluorescence intensities for each antibody, are grouped together in FIG. 6.
  • an exudate composed essentially of granulocytes, represented by a strong Ly6G and 7/4 marking is observed. From D2 post-lesion, a gradual decrease in Ly6G labeling is observed until its total disappearance, while the 7/4 labeling is preserved.
  • This analysis of The cell populations composing the exudate can be used to monitor the progression of the inflammatory phase, characterized by the infiltration of the granulocytes, then by their disappearance at the start of the proliferative phase.
  • EXAMPLE 4 Comparison of the number of anti-inflammatory cytokines contained in the exudate resulting from a dorsal wound of a healthy mouse
  • Example 2 The progress of wound healing is monitored on a group of 2 healthy mice. On each of the two mice, a wound was created according to Example 1 and a sampling device was always positioned according to Example 1. Before taking the exudate, each mouse was anesthetized with a gas. A physiological solution of known volume is injected into the syringe through a septum placed on the chamber of the device. The exudate diluted with physiological saline is aspirated and reinjected three times with the syringe so as to wash the site of the wound well, to homogenize the exudate. The diluted exudate is taken by syringe and transferred to a septum vial and centrifuged to recover only the supernatant containing the cytokines.
  • Inflammatory and anti-inflammatory cytokines contained in the exudate are analyzed by ELISA and are performed 48 hours after the creation of the wound and repeated daily for one week.
  • the cytokine TGF- ⁇ assay is shown in FIG. 6.
  • a strong progression of the level of anti-inflammatory cytokines of the TGF- ⁇ type is observed as early as D2 post-lesion. This overproduction of this anti-inflammatory cytokine reaches its peak at 5 days after the end of the inflammatory phase, before returning to a normal stage at the end of the healing process.

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Description

METHODE D ' ANALYSE DE LA PROGRESSION DE LA CICATRISATION D ' UNE PLAIE A DES NIVEAUX MICROSCOPIQUES ET MACROSCOPIQUES .  METHOD OF ANALYZING THE PROGRESSION OF WOUND HEALING AT MICROSCOPIC AND MACROSCOPIC LEVELS.
Domaine d'application : Application domain :
La présente invention concerne une méthode d'analyse de la progression de la cicatrisation d'une plaie en temps réel grâce à un dispositif médical, non invasif et adapté, qui protège la plaie et permet d'observer ma c r o s c o p i qu e me n t la progression de la cicatrisation d'une plaie ainsi que de recueillir les exsudats de la plaie afin de réaliser un suivi cellulaire, mais aussi des analyses biochimiques et moléculaires des métabolites et des microorganismes contenus dans lesdits exsudats.  The present invention relates to a method of analyzing the progression of wound healing in real time by means of a medical device, non-invasive and adapted, which protects the wound and allows me to observe my croscopic progress healing of a wound as well as collecting wound exudates in order to carry out cell monitoring, but also biochemical and molecular analyzes of the metabolites and microorganisms contained in said exudates.
Art Antérieur : Previous Art:
La cicatrisation d'une plaie est un processus physiopathologique naturel, les tissus humains et animaux étant capables de réparer des lésions localisées par des processus de réparation et de régénération qui leur sont propres.  Wound healing is a natural pathophysiological process, with human and animal tissue capable of repairing localized lesions through their own repair and regeneration processes.
La rapidité et la qualité de la cicatrisation d'une plaie dépendent de l'état général de l'organisme atteint, de l'étiologie de la plaie, de l'état et de la localisation de la plaie, et de la survenue ou non d'une infection, ainsi que des facteurs génétiques prédisposant ou non à des troubles de la cicatrisation.  The speed and quality of wound healing depend on the general condition of the affected organism, the etiology of the wound, the condition and location of the wound, and whether or not it occurs. infection, as well as genetic factors that may or may not predispose to healing disorders.
La cicatrisation naturelle d'une plaie se déroule principalement selon trois phases successives, chacune de ces phases étant caractérisée par des activités cellulaires spécifiques qui font progresser le processus de réparation selon des séquences chronologiques précises : la phase inflammatoire, la phase de granulation (ou phase proliférative) , et la phase de maturation, donnant l'aspect définitif de la cicatrice.  The natural healing of a wound occurs mainly in three successive phases, each of these phases being characterized by specific cellular activities that advance the repair process according to precise chronological sequences: the inflammatory phase, the granulation phase (or phase proliferative), and the ripening phase, giving the final appearance of the scar.
La première phase, la phase inflammatoire, débute dès la rupture des vaisseaux sanguins qui déclenche la formation d'un caillot (coagulation du sang) principalement composé de fibrine et de fibronectine , et qui va constituer une matrice provisoire. Cette matrice comble en partie la lésion et va permettre la migration au sein de la zone lésée des cellules inflammatoires recrutées pour assurer la détersion de la plaie. Les plaquettes présentes vont également libérer des facteurs (par exemple des cytokines, des facteurs de croissance) permettant le recrutement de cellules impliquées dans le processus cicatriciel. Cette phase se caractérise par l'infiltration et l'activation sur le site de la lésion, de nombreuses cellules inflammatoires (tels les polynucléaires neutrophiles ) , mais aussi des cellules assurant le nettoyage de la plaie ou détersion (tels les macrophages) . The first phase, the inflammatory phase, begins with the rupture of the blood vessels which triggers the formation of a clot (blood coagulation) mainly composed of fibrin and fibronectin, and which will constitute a temporary matrix. This matrix partially fills the lesion and will allow the migration within the injured area of the inflammatory cells recruited to ensure the debridement of the wound. The platelets present are going also release factors (eg cytokines, growth factors) allowing the recruitment of cells involved in the scar process. This phase is characterized by infiltration and activation on the site of the lesion, numerous inflammatory cells (such as neutrophils), but also cells ensuring the cleaning of the wound or debridement (such as macrophages).
La seconde phase correspond au développement du tissu de granulation. On observe d'abord une colonisation de la blessure par prolifération des fibroblastes . Puis, la migration des cellules e ndo t hé 1 i a 1 e s à partir des vaisseaux sains va permettre la néovascularisation, ou angiogenèse, du tissu lésé. Dans le tissu de granulation, les fibroblastes sont activés et vont se différencier en my o f i b r o b 1 a s t e s présentant des propriétés contractiles importantes, générées par les microfilaments d'actine, permettant la contraction de la plaie. Ces microfilaments sont exprimés par une protéine : l'actine -musculaire lisse. Ces myofibroblastes jouent donc un rôle majeur dans la formation et la maturation du tissu de granulation qui va conduire à la cicatrisation de la lésion. Il y a ensuite migration des kératinocytes et reconstruction de l'épiderme.  The second phase corresponds to the development of the granulation tissue. We first observe a colonization of the wound by proliferation of fibroblasts. Then, cell migration from healthy vessels will allow neovascularization, or angiogenesis, of the injured tissue. In the granulation tissue, the fibroblasts are activated and will differentiate into myofibers with significant contractile properties, generated by the actin microfilaments, allowing contraction of the wound. These microfilaments are expressed by a protein: smooth muscle actin. These myofibroblasts therefore play a major role in the formation and maturation of the granulation tissue that will lead to the healing of the lesion. There is then migration of keratinocytes and reconstruction of the epidermis.
Cette phase est initiée par une diminution de l'état inflammatoire de la lésion s ' accompagnant d'une apoptose des cellules inflammatoires.  This phase is initiated by a decrease in the inflammatory state of the lesion accompanied by an apoptosis of the inflammatory cells.
La troisième phase du processus est une étape principalement de maturation visant à reconstruire un tissu fonctionnel le plus identique possible au tissu d'origine. Le tissu de granulation précédemment formé subit donc un remodelage. Une partie de la matrice e x t r a c e 11 u 1 a i r e est digérée par des protéases (essentiellement des métallo-protéases matricielles et des élastases) , et on observe une réorganisation progressive de la matrice extracellulaire. Progressivement, le collagène de type III, majoritaire dans le tissu de granulation, est remplacé par le collagène de type I, principal composant matriciel du derme. A la fin de la phase de maturation, les fibroblastes, myofibroblastes et cellules vasculaires voient leur prolifération et/ou leur activité réduites. Puis, les cellules excédentaires meurent par apoptose. Parallèlement au remodelage de la matrice extracellulaire et à l'apoptose des cellules excédentaires. The third phase of the process is a mainly maturation stage aimed at reconstructing a functional tissue that is as identical as possible to the original tissue. The previously formed granulation tissue is therefore remodeled. Part of the extracellular matrix is digested with proteases (essentially matrix metalloproteases and elastases), and progressive reorganization of the extracellular matrix is observed. Gradually, type III collagen, predominant in the granulation tissue, is replaced by type I collagen, the main matrix component of the dermis. At the end of the maturation phase, the fibroblasts, myofibroblasts and vascular cells see their proliferation and / or their activity reduced. Then, the excess cells die by apoptosis. Parallel to the remodeling of the extracellular matrix and to the apoptosis of the surplus cells.
La phase inflammatoire est une phase essentielle de la cicatrisation et doit être transitoire. Dans certains cas, elle peut être prolongée par la présence de certains agents infectieux comme Staphylococcus aureus ou Pseudomonas aeruginosa ou par une pathologie préexistante comme le diabète, une déficience immunitaire ou encore une insuffisance veineuse. La résolution de l'inflammation est un point critique qui conditionne l'amorçage de la réparation tissulaire. Une perturbation de cette phase va engendrer un prolongement anormal de la phase inflammatoire et aboutir à la chronicité de la lésion en retardant la réparation tissulaire. La résolution de l'inflammation est un phénomène dynamique qui implique l'apoptose des cellules inflammatoires, leur élimination et l'apparition de médiateurs anti-inflammatoires, chimiotactiques et angiogéniques . Une manière d'évaluer le bon déroulement de cette période critique, qu'est la phase de résolution, est d'analyser les exsudats provenant de la plaie (cellules, médiateurs et métabolites) . En effet, la chronicité inflammatoire se traduit par un afflux plus important de cellules inflammatoires, une production excessive de nombreuses cytokines et chimiokines inflammatoires et de protéases qui dégradent la matrice cellulaire. Inversement, la phase de résolution implique l'apparition d'un certain type de macrophages responsables de la phagocytose des cellules inflammatoires apoptotiques . Ces macrophages sont aussi impliqués dans la production de médiateurs favorisant la phase de granulation ainsi que la réparation tissulaire. L'analyse de l' exsudât permettra au médecin d'évaluer la phase inflammatoire et sa résolution, et permettra ainsi de choisir de traiter la plaie par un agent thérapeutique adapté de manière à favoriser une meilleure cicatrisation .  The inflammatory phase is an essential phase of healing and must be transient. In some cases, it may be prolonged by the presence of certain infectious agents such as Staphylococcus aureus or Pseudomonas aeruginosa or by a pre-existing pathology such as diabetes, an immune deficiency or even venous insufficiency. The resolution of inflammation is a critical point that conditions the initiation of tissue repair. Disturbance of this phase will result in an abnormal prolongation of the inflammatory phase and result in the chronicity of the lesion by delaying tissue repair. The resolution of inflammation is a dynamic phenomenon that involves the apoptosis of inflammatory cells, their elimination and the appearance of anti-inflammatory, chemotactic and angiogenic mediators. One way to evaluate the success of this critical period, the resolution phase, is to analyze exudates from the wound (cells, mediators and metabolites). Indeed, inflammatory chronicity results in a larger influx of inflammatory cells, an excessive production of many cytokines and inflammatory chemokines and proteases that degrade the cell matrix. Conversely, the resolution phase involves the appearance of a certain type of macrophages responsible for the phagocytosis of apoptotic inflammatory cells. These macrophages are also involved in the production of mediators favoring the granulation phase as well as the tissue repair. Analysis of the exudate will allow the physician to evaluate the inflammatory phase and its resolution, and thus allow to choose to treat the wound with a therapeutic agent adapted to promote better healing.
Traditionnellement, les plaies sont recouvertes par un pansement ou une compresse pour empêcher une contamination par des agents infectieux présents dans l'environnement, mais également pour maintenir la plaie dans un milieu humide favorisant la cicatrisation. Cependant, ce système de protection ne permet pas d'analyser les exsudats et de visualiser la cicatrisation en temps réel. De plus, l' exsudât s'accumule dans le pansement et sature le milieu absorbant du pansement. Le pansement doit donc être changé régulièrement pour éviter la macération de la plaie, ce qui implique un risque de contamination de la plaie qui est exposée momentanément à l'air libre. De plus, les pansements peuvent également adhérer, même faiblement à la plaie, et induire ainsi des lésions à la plaie lors de leur retrait. Ces nouvelles agressions engendrent une poursuite de l'inflammation, qui a pour conséquence de prolonger la phase inflammatoire et donc de modifier de façon substantielle la cinétique de cicatrisation. Traditionally, wounds are covered with a bandage or compress to prevent contamination by infectious agents in the environment, but also to keep the wound in a moist environment that promotes healing. However, this protection system does not allow to analyze the exudates and to visualize the cicatrization in time real. In addition, the exudate accumulates in the dressing and saturates the absorbent medium of the dressing. The dressing must therefore be changed regularly to prevent maceration of the wound, which implies a risk of contamination of the wound that is temporarily exposed to the open air. In addition, the dressings may also adhere, even weakly to the wound, and thus induce lesions to the wound during their removal. These new aggressions cause a continuation of the inflammation, which has the consequence of prolonging the inflammatory phase and thus substantially modifying the kinetics of healing.
Des chambres implantables ont été mises au point pour étudier la cicatrisation de plaies du derme sur des animaux de laboratoires tels que la souris ou le porc. Cependant, ces chambres implantables sont insérées en partie sous la peau de l'animal et sont maintenues en place par des points de suture. Cette méthode est donc invasive, c'est à dire qu'elle présente comme inconvénient majeur de nécessiter un acte chirurgical d'implantation de la chambre en partie sous la peau de l'animal et risque donc de provoquer une réaction inflammatoire chez le sujet en question, en créant des agressions tissulaires lors de son implantation. Ces agressions tissulaires auront des conséquences néfastes sur le bon déroulement de la cicatrisation de l'animal. De plus, ces chambres implantables ont essentiellement été mises au point pour modéliser les mécanismes de cicatrisation chez l'animal comme par exemple, une souris ou le porc. Ainsi, avec de telles chambres invasives, il est impossible de réaliser un suivi visuel, cellulaire, biochimique et moléculaire fiable des plaies, notamment durant les premiers jours qui suivent l'implantation de ces chambres.  Implantable chambers have been developed to study the healing of dermal wounds in laboratory animals such as mice and pigs. However, these implantable chambers are inserted partially under the skin of the animal and are held in place by stitches. This method is therefore invasive, ie it has the major disadvantage of requiring a surgical procedure for implantation of the chamber partly under the skin of the animal and may therefore cause an inflammatory reaction in the subject in question. question, by creating tissue aggression during implantation. These tissue attacks will have harmful consequences on the good progress of the healing of the animal. In addition, these implantable chambers have essentially been developed to model the healing mechanisms in animals such as, for example, a mouse or pig. Thus, with such invasive chambers, it is impossible to perform reliable visual, cellular, biochemical and molecular monitoring of wounds, especially during the first days following the implantation of these chambers.
Il existe donc un réel besoin en une méthode non-invasive de prélèvement d' exsudats purs à des fins d'analyse en temps réel utilisant un dispositif non invasif et permettant de visualiser la progression de la cicatrisation sans être nécessairement obligé d'ouvrir ledit dispositif, ni de le retirer. Invention There is therefore a real need for a non-invasive method for taking pure exudates for real-time analysis using a non-invasive device that can visualize the progression of healing without necessarily having to open the device. or remove it. Invention
Un premier objet de la présente invention est une méthode non- invasive d'analyse de la progression de la cicatrisation d'une plaie qui met en œuvre un dispositif tel que décrit dans la demande de brevet n° FR 11 62295 déposée le 22 décembre 2011, ladite méthode comprenant les étapes suivantes:  A first object of the present invention is a non-invasive method of analyzing the progression of wound healing which implements a device as described in patent application No. FR 11 62295 filed December 22, 2011. said method comprising the following steps:
fixer le dispositif non invasif sur le pourtour de la plaie ;  fix the non-invasive device around the wound;
faire une observation macroscopique de la plaie et/ou de l' exsudât ; et/ou  make a macroscopic observation of the wound and / or exudate; and or
prélever l' exsudât contenu dans ledit dispositif et analyser ledit exsudât.  withdrawing the exudate contained in said device and analyzing said exudate.
Le dispositif utilisé dans la méthode selon l'invention comprend notamment: une chambre ayant une paroi latérale, une extrémité inférieure ouverte et une extrémité supérieure, une ouverture d'accès étant disposée sur l'extrémité supérieure et/ou sur la paroi latérale de ladite chambre, ledit dispositif étant destiné à être en contact avec la peau et à circonscrire la plaie lors de son utilisation par l'intermédiaire d'une interface. The device used in the method according to the invention comprises in particular: a chamber having a side wall, an open bottom end and an upper end, an access opening being disposed on the upper end and / or on the side wall of said chamber, said device being intended to be in contact with the skin and to circumscribe the wound during its use via an interface.
Selon un mode de réalisation particulier de l'invention, ledit dispositif comprend une chambre ayant une paroi latérale, une extrémité inférieure ouverte et une extrémité supérieure, une ouverture d'accès étant disposée sur l'extrémité supérieure et/ou sur la paroi latérale de ladite chambre, ledit dispositif comprenant en outre un moyen de fermeture amovible de la chambre qui s'adapte sur l'ouverture d'accès de la chambre et un élément de maintien, éventuellement de forme tubulaire, circonscrit ou inscrit à ladite chambre, ouvert à ses deux extrémités, ledit dispositif étant destiné à être en contact avec la peau et à circonscrire la plaie lors de son utilisation par l'intermédiaire d'une interface qui est un adhésif disposé sur une jupe en matériau souple, ladite jupe étant maintenue entre la paroi latérale de la chambre et l'élément de maintien.  According to a particular embodiment of the invention, said device comprises a chamber having a side wall, an open bottom end and an upper end, an access opening being disposed on the upper end and / or on the side wall of said chamber, said device further comprising a removable closure means of the chamber which fits on the access opening of the chamber and a holding element, possibly of tubular shape, circumscribed or inscribed in said chamber, open to both ends, said device being intended to be in contact with the skin and circumscribing the wound during its use via an interface which is an adhesive disposed on a skirt of flexible material, said skirt being held between the side wall of the chamber and the holding member.
Le dispositif utilisé dans la méthode selon l'invention peut notamment être considéré comme un dispositif passif de récolte des exsudats, en opposition à un dispositif actif. Par dispositif actif, on entend un dispositif où les exsudats sont récoltés grâce à l'application d'un effet ou d'une contrainte externe, physique et/ou mécanique, telle qu'une pression négative, comme par exemple les dispositifs sous vide ou les dispositifs de thérapie par pression négative, également appelée TPN. Les dispositifs actifs et passifs peuvent également se différencier par la qualité des exsudats récoltés. En effet, en instaurant une contrainte mécanique et/ou physique dans le dispositif actif, les exsudats récoltés sont d'un volume plus important, et on assiste ainsi à une dilution des différentes cellules, médiateurs, ou facteurs cellulaires contenus dans lesdits exsudats. De plus, avec les dispositifs actifs, les cellules retrouvées dans les exsudats peuvent être mortes et/ou activées. Par cellules activées on entend des cellules extraites de leur milieu naturel se retrouvant en situation de stress et qui peuvent alors perdre, entre autres, leurs capacités fonctionnelles, ce qui est, par exemple, le cas pour des macrophages et des polynucléaires neutrophiles . L'avantage du dispositif utilisé dans la méthode de la présente invention est donc de permettre de conserver l'intégrité et les fonctionnalités des différentes populations cellulaires contenues dans les exsudats issus de la plaie. On obtient ainsi une vraie « image » de la plaie. The device used in the method according to the invention can in particular be considered as a passive device for collecting exudates, as opposed to an active device. By active device, means a device where the exudates are harvested by the application of an effect or external stress, physical and / or mechanical, such as a negative pressure, such as for example vacuum devices or therapy devices by negative pressure, also called TPN. Active and passive devices can also be differentiated by the quality of exudates harvested. Indeed, by introducing a mechanical and / or physical stress in the active device, the exudates harvested are of a larger volume, and thus there is a dilution of the various cells, mediators, or cellular factors contained in said exudates. In addition, with the active devices, the cells found in the exudates can be dead and / or activated. By activated cells is meant cells extracted from their natural environment found in a situation of stress and which can then lose, among other things, their functional abilities, which is, for example, the case for macrophages and neutrophils. The advantage of the device used in the method of the present invention is therefore to allow the integrity and the functionalities of the different cell populations contained in the exudates resulting from the wound to be preserved. This gives a true "picture" of the wound.
De plus, le dispositif utilisé dans la méthode de la présente invention est un dispositif de récolte directe des exsudats sur le site cicatriciel. Par « dispositif de récolte directe », on entend un dispositif dans lequel les exsudats sont directement prélevés à leur source d'émission, dans le cas présent au voisinage de la plaie, l' exsudât n'ayant donc pas besoin de transiter par une chambre ou réservoir connexe et/ou par un matériau absorbant avant son extraction du dispositif. La récolte directe permet ainsi de conserver l'intégrité et la physiologie de la plaie et de son environnement, le tout sans perturber la cicatrisation de la plaie. Ainsi, le dispositif utilisé dans la méthode selon l'invention est centré sur l'analyse macroscopique et microscopique des exsudats issus de la plaie, mais aussi de la plaie elle-même.  In addition, the device used in the method of the present invention is a device for direct collection of exudates at the scar site. "Direct harvesting device" means a device in which the exudates are directly taken from their source of emission, in this case in the vicinity of the wound, the exudate therefore not having to pass through a chamber. or related reservoir and / or absorbent material prior to removal of the device. Direct harvesting thus preserves the integrity and physiology of the wound and its environment, all without disrupting wound healing. Thus, the device used in the method according to the invention is centered on the macroscopic and microscopic analysis of the exudates from the wound, but also the wound itself.
Le dispositif entrant dans la méthode selon l'invention est dépourvu de tout moyen absorbant entrant en contact avec 1' exsudât et la plaie. Cela permet d'éviter une macération de la plaie due à la saturation dudit moyen absorbant par l' exsudât comme cela peut être le cas avec un pansement. De plus, l'absence de moyen absorbant permet d'éviter tout piégeage ou dégradation des protéines, métabolites et cellules présentes dans l' exsudât, tout ceci dans l'objectif de récupérer des exsudats purs et sans perte de cellules et de métabolites. Selon un mode de réalisation particulier, le dispositif utilisé dans la méthode selon l'invention est étanche au niveau de la zone d'interaction dispositif/peau du sujet. Ainsi, l' exsudât recueilli dans la chambre ne peut pas s'échapper par les bords dudit dispositif. L'étanchéité dudit dispositif est assurée préférentiellement par la juxtaposition de la chambre tubulaire et de l'élément de maintien, constituants entre lesquels on retrouve intercalée la jupe en matériau souple. Cette dernière conférant en plus à l'ensemble du dispositif des propriétés de conformabilité de bonne facture. Par conformabilité de bonne facture on entend que la jupe en matériau souple s'adapte sur la surface à laquelle elle est fixée, en prenant une forme adéquate. Le dispositif une fois fixé sur une surface plane ou une surface non plane permet de conserver la totalité du volume des exsudats récoltés au niveau de la plaie. Il en est de même pour le volume d'une solution qui est injectée dans ledit dispositif au travers d'un septum retrouvé sur le moyen de fermeture ou sur la chambre du dispositif. Selon un mode de réalisation préféré, il est également possible de rajouter une lèvre en matériau semi rigide conformable, éventuellement à mémoire de forme, tel que notamment le PMMA (polyméthacrylate de méthyle), le POM-C (copolymère de polyacétal), le PEKK (polyéther kétone kétone) , le silicone, le polyuréthane ou encore le polyamide, sur la partie inférieure de l'élément de maintien, lèvre qui peut se révéler utile lorsque la surface de la peau sur laquelle le dispositif est fixé n'est pas plane, permettant ainsi d'assurer encore d'avantage, l'étanchéité dudit dispositif. Il est à noter que quelque soit le type de surface, par exemple une surface plane ou non plane, sur laquelle le dispositif est fixé, l'étanchéité dudit dispositif est démontrée. Ainsi, le dispositif utilisé dans la méthode de la présente invention allie étanchéité et conformabilité au moyen de la juxtaposition de la chambre tubulaire, de l'élément de maintien et de la jupe en matériau souple. Dans la première étape de mise en œuvre de cette méthode, le dispositif de prélèvement est positionné de manière à circonscrire la plaie sans entrer en contact avec ladite plaie, ainsi ledit dispositif est fixé sur la peau saine autour de la plaie, par exemple grâce à une interface qui est adhésive. L'interface adhésive peut consister en un adhésif qui est appliqué soit directement sur le dispositif juste avant de le positionner autour de la plaie, soit sur une jupe en matériau souple conformable, ou bien le dispositif ou la jupe peuvent être pré-enduits par un adhésif lors de leur fabrication. Dans ce cas, l'interface adhésive est avantageusement protégée par une barrière protectrice qui devra être enlevée avant de positionner le dispositif autour de la plaie. The device used in the method according to the invention is devoid of any absorbing means coming into contact with the exudate and the wound. This avoids maceration of the wound due to the saturation of said absorbent means by the exudate as may be the case with a dressing. In addition, the absence of absorbent means prevents any entrapment or degradation of proteins, metabolites and cells present in the exudate, all with the objective of recovering pure exudates and without loss of cells and metabolites. According to a particular embodiment, the device used in the method according to the invention is sealed at the level of the device / skin interaction zone of the subject. Thus, the exudate collected in the chamber can not escape through the edges of said device. The sealing of said device is preferably provided by the juxtaposition of the tubular chamber and the holding member, the components between which is found inserted the skirt of flexible material. The latter conferring in addition to the entire device conformability properties of good quality. Conformability of good quality means that the skirt of flexible material fits on the surface to which it is attached, taking a suitable form. The device once fixed on a flat surface or a non-flat surface makes it possible to retain the entire volume of the exudates collected at the wound level. It is the same for the volume of a solution which is injected into said device through a septum found on the closure means or on the chamber of the device. According to a preferred embodiment, it is also possible to add a lip made of a conformable semi-rigid material, possibly with shape memory, such as in particular PMMA (polymethyl methacrylate), POM-C (polyacetal copolymer), PEKK (polyether ketone ketone), silicone, polyurethane or polyamide, on the lower part of the holding member, which lip can be useful when the surface of the skin on which the device is attached is not flat , thus making it possible to ensure even further the sealing of said device. It should be noted that whatever the type of surface, for example a flat or non-planar surface, on which the device is fixed, the sealing of said device is demonstrated. Thus, the device used in the method of the present invention combines sealing and conformability by means of the juxtaposition of the tubular chamber, the holding element and the skirt of flexible material. In the first step of implementing this method, the sampling device is positioned in such a way as to circumscribe the wound without coming into contact with the wound, so that said device is fixed on the healthy skin around the wound, for example by virtue of an interface that is adhesive. The adhesive interface may consist of an adhesive which is applied either directly to the device just before positioning it around the wound, or on a skirt of conformable compliant material, or the device or skirt may be pre-coated by a adhesive during their manufacture. In this case, the adhesive interface is advantageously protected by a protective barrier which must be removed before positioning the device around the wound.
Une fois le dispositif positionné au-dessus de la plaie, il convient d'exercer une pression suffisante sur la partie supérieure du dispositif jusqu'à la prise complète de l'adhésif et à la fixation totale du dispositif autour de la plaie.  Once the device is positioned above the wound, sufficient pressure should be exerted on the upper part of the device until the adhesive is fully set and the device is completely fixed around the wound.
Lors de l'étape de positionnement, et afin d'améliorer la tenue du dispositif autour de la plaie, on peut éventuellement enduire le pourtour de l'interface du dispositif ainsi que la peau au voisinage de la plaie et à proximité du dispositif par de l'adhésif.  During the positioning step, and in order to improve the behavior of the device around the wound, it is possible to coat the periphery of the interface of the device as well as the skin in the vicinity of the wound and close to the device by the adhesive.
Afin de faciliter l'étape de positionnement, il est préférable de visualiser la plaie afin de placer le dispositif sur la peau saine autour de la plaie. Pour cela, on peut notamment retirer le moyen de fermeture du dispositif avant de positionner ce dernier. En effet, le dispositif de prélèvement utilisé dans la méthode selon l'invention comprend un moyen de fermeture qui permet d'accéder facilement à la plaie sans avoir à retirer le dispositif. Ledit moyen de fermeture est fixé sur la partie supérieure de la chambre du dispositif ou sur la paroi latérale de la chambre du dispositif, notamment par un pas de vis, un clip, une goupille, un moyen de sertissage et/ou un système de baïonnette. Une fois que le dispositif est fixé sur la peau autour de la plaie par son interface adhésive, le moyen de fermeture du dispositif est replacé sur la chambre dudit dispositif, par exemple en le vissant ou à l'aide d'une goupille insérée dans des orifices adaptés placés sur le moyen de fermeture et sur la chambre du dispositif. La visualisation de la plaie permettant un bon positionnement du dispositif peut également être réalisée sans ouvrir le dispositif, en regardant à travers le moyen de fermeture dudit dispositif, notamment lorsque le moyen de fermeture est réalisé en matériau transparent et/ou est muni d'une lentille transparente, éventuellement grossissante. In order to facilitate the positioning step, it is best to visualize the wound in order to place the device on the healthy skin around the wound. For this, one can in particular remove the closure means of the device before positioning the latter. Indeed, the sampling device used in the method according to the invention comprises a closure means which allows easy access to the wound without removing the device. Said closing means is fixed on the upper part of the chamber of the device or on the side wall of the chamber of the device, in particular by a screw thread, a clip, a pin, a crimping means and / or a bayonet system . Once the device is attached to the skin around the wound by its adhesive interface, the closing means of the device is placed back on the chamber of said device, for example by screwing it or by means of a pin inserted into adapted orifices placed on the closure means and on the chamber of the device. The visualization of the wound allowing a good positioning of the device can also be performed without opening the device, looking through the closure means of said device, in particular when the closure means is made of transparent material and / or is provided with a transparent lens, possibly magnifying.
Cette étape de positionnement du dispositif permet de le fixer autour de la plaie de manière temporaire et non-invasive . Le dispositif doit être fixé à la peau de manière suffisante pendant toute la durée de la cicatrisation.  This positioning step of the device makes it possible to fix it around the wound temporarily and non-invasively. The device must be attached to the skin sufficiently for the duration of the healing.
La deuxième étape de la méthode selon l'invention est l'observation macroscopique de la plaie et/ou de l'exsudat. The second step of the method according to the invention is the macroscopic observation of the wound and / or the exudate.
Par observation macroscopique, la demanderesse entend toute analyse réalisée de manière externe, c'est-à-dire de manière non- invasive ou encore sans intervention sur le site en question, de la plaie et/ou de l'exsudat.  By macroscopic observation, the Applicant hears any analysis performed externally, that is to say non-invasively or without intervention on the site in question, the wound and / or exudate.
Selon un mode de réalisation préféré, l'observation macroscopique de la plaie et/ou de l'exsudat comprend la détermination des paramètres physico-chimiques de ladite plaie et/ou dudit exsudât. Par paramètres physico-chimiques, on entend, au sens de la présente invention, différentes caractéristiques sensorielles de la plaie et/ou de l'exsudat, telles que notamment l'aspect de la plaie (couleur, texture, profondeur, superficie, odeur) et/ou l'aspect de l'exsudat (couleur, odeur, limpidité, viscosité) .  According to a preferred embodiment, the macroscopic observation of the wound and / or the exudate comprises the determination of the physico-chemical parameters of said wound and / or said exudate. By physico-chemical parameters is meant, in the sense of the present invention, different sensory characteristics of the wound and / or exudate, such as in particular the appearance of the wound (color, texture, depth, area, odor) and / or the appearance of the exudate (color, odor, clarity, viscosity).
L'observation macroscopique de la plaie peut ainsi consister en un suivi visuel, voire olfactif, de l'état et de la progression de la cicatrisation de la plaie. Ainsi, une observation simple de la plaie pourra être effectuée à l'aide d'un appareil photographique, d'une caméra vidéo, ou bien tout simplement grâce à l'œil humain. Une observation grossie pourra quant à elle être réalisée à l'aide d'une loupe, d'un dermoscope ou bien dans un autre registre, via une application pour « smartphone » comme par exemple l'application MOWA (« Mobile Wound Analyser ») . Enfin, une observation offrant encore de meilleures résolutions visuelles pourra être mise en œuvre à l'aide d'une microscopie biphotonique , d'une diffusion Raman, d'une microscopie confocale, d'un IRM, d'une échographie haute fréquence, ou encore par capillaroscopie . Ce dernier type de technologies permet une observation en profondeur de la plaie, de l'ordre de quelques centaines de micromètres, ce qui est impossible à l'œil nu. Il est à noter que des moyens de suivi étalons seront envisagés pour chaque type de technique de visualisation macroscopique utilisé. Un des modes de réalisation préféré de la présente invention réside en une prise de photographie qui peut notamment être effectuée sans ouvrir le dispositif lorsque celui-ci est réalisé en matériau transparent et/ou est muni d'une lentille transparente, éventuellement grossissante. Ce mode de réalisation est particulièrement aisé à mettre en œuvre. Dans le cas contraire, la prise de photographie est réalisée après avoir retiré le moyen de fermeture du dispositif, ledit moyen de fermeture étant remis en position fermée sur le dispositif une fois la photographie prise. La fréquence de la prise de photographie peut notamment être d'une photographie par jour, ce qui permet de visualiser la cinétique de la progression de la cicatrisation de la plaie. The macroscopic observation of the wound can thus consist of a visual or even olfactory follow-up of the state and progress of the healing of the wound. Thus, a simple observation of the wound can be performed using a camera, a video camera, or simply thanks to the human eye. A magnified observation can be performed using a magnifying glass, a dermoscope or in another register, via an application for "smartphone" as for example the application MOWA ("Mobile Wound Analyzer") . Finally, an observation offering even better visual resolutions can be implemented using a two-photon microscopy, a Raman scattering, a confocal microscopy, an MRI, a high-frequency ultrasound, or by capillaroscopy. This last type of technology allows a deep observation of the wound, of the order of a few hundred micrometers, which is impossible to the naked eye. It should be noted that standard monitoring means will be considered for each type of macroscopic visualization technique used. One of the preferred embodiments of the present invention resides in a photograph that can in particular be made without opening the device when it is made of transparent material and / or is provided with a transparent lens, possibly magnifying. This embodiment is particularly easy to implement. In the opposite case, the photographing is carried out after removing the closure means of the device, said closing means being returned to the closed position on the device once the photograph is taken. The frequency of taking photographs can be one photograph per day, which makes it possible to visualize the kinetics of the progression of the healing of the wound.
Les différentes photographies sont préférentiellement prises avec les mêmes réglages afin de pouvoir comparer les photographies entre elles. Ainsi, selon un mode de réalisation particulier, l'appareil photographique est positionné à la même distance de la plaie et avec le même angle pour chaque photographie, en utilisant par exemple un banc de photographie.  The different photographs are preferably taken with the same settings in order to be able to compare the photographs with each other. Thus, according to a particular embodiment, the camera is positioned at the same distance from the wound and with the same angle for each photograph, for example using a photography bench.
Selon un mode de réalisation préféré, la prise de la photographie peut être suivie ou simultanée à une comparaison avec un ou des moyens de suivi macroscopiques étalons. Ainsi, avant de prendre la photographie, on peut positionner à proximité du dispositif un moyen d'étalonnage tel que notamment un objet comprenant des graduations, et/ou un nuancier de teintes bien définies. Une fois les différentes photographies prises, le moyen d'étalonnage permet notamment de comparer les photographies, même lorsque les réglages de l'appareil photographique diffèrent, et de réaliser des mesures de la plaie sur les photographies.  According to a preferred embodiment, the taking of the photograph can be followed or simultaneous with a comparison with one or more standard macroscopic tracking means. Thus, before taking the photograph, it is possible to position near the device calibration means such as in particular an object comprising graduations, and / or a color chart of well-defined hues. Once the various photographs have been taken, the calibration means makes it possible in particular to compare the photographs, even when the camera settings differ, and to make measurements of the wound on the photographs.
Il est à noter que la méthode objet de la présente invention permet par l'intermédiaire de l'utilisation dudit dispositif non invasif d'observer la plaie dans son ensemble, aspect que l'on ne peut retrouver dans des méthodes d'utilisation d'un dispositif de thérapie par pression négative ou de création de vide. En effet, ce sont des méthodes dans lesquelles l'utilisation d'un pansement occlusif ou d'une interface elle aussi occlusive est récurrente, et donc la visualisation totale de la plaie est impossible. On ne visualise au mieux que partiellement la plaie à l'aide de ces méthodes . It should be noted that the method that is the subject of the present invention makes it possible, through the use of said non-invasive device, to observe the wound as a whole, an aspect that can not be found in methods of use. a device negative pressure therapy or vacuum creation. Indeed, these are methods in which the use of an occlusive dressing or an interface that is also occlusive is recurrent, and therefore the total visualization of the wound is impossible. The wound is best visualized only partially using these methods.
Selon un mode de réalisation préféré, des analyses biologiques sont réalisées sur l'exsudat pour caractériser et/ou quantifier les différentes populations cellulaires contenues. Il est également possible de déterminer la présence mais aussi de quantifier les métabolites et/ou les microorganismes contenus dans ledit exsudât.  According to a preferred embodiment, biological analyzes are performed on the exudate to characterize and / or quantify the different cell populations contained. It is also possible to determine the presence but also to quantify the metabolites and / or microorganisms contained in said exudate.
Afin de réaliser ces analyses pour le suivi de la progression de la plaie grâce à la méthode selon l'invention, l'exsudat contenu dans le dispositif peut être prélevé et ledit exsudât peut être analysé. L'analyse peut notamment être une évaluation plus spécifique des paramètres physico-chimiques de l'exsudat prélevé par rapport aux mêmes paramètres observés sans prélèvement de l'exsudat. Ainsi on pourra déterminer avec plus de précision le volume d' exsudât produit par la plaie, mais aussi tous les paramètres ayant trait aux propriétés propres dudit exsudât (pH, T°C, couleur, odeur, limpidité, viscosité) .  In order to carry out these analyzes for monitoring the progress of the wound using the method according to the invention, the exudate contained in the device can be taken and said exudate can be analyzed. The analysis may in particular be a more specific evaluation of the physicochemical parameters of the exudate taken with respect to the same parameters observed without removal of the exudate. Thus it will be possible to determine more precisely the volume of exudate produced by the wound, but also all the parameters relating to the eigenvalues of said exudate (pH, T ° C, color, odor, clarity, viscosity).
Ledit prélèvement de l'exsudat peut notamment être effectué au moyen d'une pipette, munie d'un moyen d'aspiration tel qu'un cône, et/ou d'une seringue, soit après ouverture du moyen de fermeture du dispositif, soit au travers d'un septum positionné sur la paroi latérale de la chambre du dispositif ou sur le moyen de fermeture du dispositif. De préférence, le prélèvement de l'exsudat est effectué au travers d'un septum. Le prélèvement de l'exsudat au travers du septum permet de conserver la stérilité du milieu interne du dispositif vis-à-vis du milieu extérieur dudit dispositif. Selon un mode de réalisation préféré, l'exsudat n'est pas absorbé par un matériau absorbant avant son prélèvement. Selon un autre mode de réalisation préféré, l'exsudat n'est pas prélevé par un dispositif appliquant une pression négative à la plaie, telle qu'une pompe à vide.  Said removal of the exudate may in particular be carried out by means of a pipette, provided with a suction means such as a cone, and / or a syringe, either after opening of the closure means of the device, or through a septum positioned on the side wall of the device chamber or on the closure means of the device. Preferably, the removal of the exudate is carried out through a septum. The removal of the exudate through the septum makes it possible to preserve the sterility of the internal medium of the device vis-à-vis the external environment of said device. According to a preferred embodiment, the exudate is not absorbed by an absorbent material prior to sampling. According to another preferred embodiment, the exudate is not taken by a device applying a negative pressure to the wound, such as a vacuum pump.
Lorsque l'exsudat contenu dans le dispositif est trop visqueux pour pouvoir être facilement prélevé à la seringue, on peut avantageusement rendre l' exsudât moins visqueux en injectant dans le dispositif une solution physiologique, comme par exemple du sérum physiologique ou encore une solution diluée de chlorure de sodium. Selon un mode de réalisation préféré, on peut aspirer et réinjecter plusieurs fois la solution composée d' exsudât dilué par la solution physiologique afin de bien laver le site de la plaie et de récupérer le maximum de cellules, métabolites et/ou microorganismes afin de faciliter les analyses ultérieures. When the exudate contained in the device is too viscous to be easily removed by syringe, it can be advantageously make the exudate less viscous by injecting into the device a physiological solution, such as for example physiological saline or a dilute solution of sodium chloride. According to a preferred embodiment, it is possible to aspirate and reinject several times the diluted exudate solution with physiological solution in order to wash the wound site and recover the maximum number of cells, metabolites and / or microorganisms in order to facilitate subsequent analyzes.
Par métabolite, la demanderesse entend tous les composés organiques susceptibles d'être retrouvés dans une plaie, tels que par exemple, des protéines (protéines inflammatoires ou antiinflammatoires, des facteurs de croissance, des protéines de la matrice extracellulaire comme le collagène ou la fibrine) , des lipides (tels que des acides gras, des leucotriènes ) , de acides aminés, des hormones, de l'albumine, de l'urée.  By metabolite, the Applicant hears all organic compounds likely to be found in a wound, such as for example, proteins (inflammatory or anti-inflammatory proteins, growth factors, extracellular matrix proteins such as collagen or fibrin). lipids (such as fatty acids, leukotrienes), amino acids, hormones, albumin, urea.
Par microorganismes, la demanderesse entend tous les microorganismes susceptibles d'être retrouvés sur une plaie, infectée ou non, tels que par exemple, des bactéries (telles que celles composées par le genre Staphylococcus comme par exemple, S.aureus, S . epidermidis, S.pyogenes, par le genre Enterococcus, comme par exemple E.faecalis, par le genre Pseudomonas, comme par exemple P. aeruginosa, par la famille des Entérobactérie s , du type E.coli, Enterobacter sp . , Proteus sp . , Serratia sp . , ou encore par des bactéries du type anaérobique, comme Clostrium sp. ou Bacteroides sp . ) , des levures (Candida albicans) , des virus (rétrovirus, adénovirus), ou encore des parasites (ectoparasites , endoparasites , mesoparasites ) ,  By microorganisms, the applicant hears all the microorganisms likely to be found on a wound, infected or not, such as, for example, bacteria (such as those composed of the genus Staphylococcus, for example, S.aureus, S. epidermidis, S.pyogenes, by the genus Enterococcus, for example E. faecalis, by the genus Pseudomonas, for example P. aeruginosa, by the Enterobacteriaceae family, of the E.coli type, Enterobacter sp., Proteus sp., Serratia sp., or by anaerobic bacteria such as Clostrium sp. or Bacteroides sp.), yeasts (Candida albicans), viruses (retroviruses, adenovirus), or parasites (ectoparasites, endoparasites, mesoparasites),
Par cellules, la demanderesse entend toutes les cellules susceptibles d'être retrouvées sur une plaie, telles que notamment des cellules inflammatoires (granulocytes) , des fibroblastes , ou encore des kératinocytes .  By cells, the Applicant hears all the cells likely to be found on a wound, such as in particular inflammatory cells (granulocytes), fibroblasts, or even keratinocytes.
L' exsudât prélevé est alors transféré dans un contenant adapté, tel que notamment un tube à essai ou un flacon muni d'un septum. Selon un mode de réalisation particulier, lorsque le prélèvement de 1' exsudât dans le dispositif est réalisé au travers d'un septum et que l'exsudat est transféré dans un flacon muni d'un septum, l' exsudât n'est pas en contact avec l'air libre ce qui empêche sa contamination par des agents pathogènes extérieurs. The removed exudate is then transferred to a suitable container, such as in particular a test tube or a septum-filled bottle. According to a particular embodiment, when the removal of the exudate in the device is carried out through a septum and the exudate is transferred to a septum-filled flask, the exudate is not in contact with the open air which prevents its contamination by external pathogens.
Si le moyen de fermeture a été retiré pour réaliser le prélèvement de l' exsudât, ledit moyen de fermeture est remis en position fermée sur le dispositif après le prélèvement.  If the closure means has been removed to take the exudate sample, said closure means is returned to the closed position on the device after sampling.
Les analyses biologiques qui peuvent être réalisées sur l' exsudât sont multiples et variées. Ainsi, dès le premier jour de la mise en œuvre de la méthode selon l'invention, on peut effectuer un suivi phénotypique et fonctionnel des populations cellulaires, telles que notamment les cellules inflammatoires ou les cellules cutanées. Ces analyses, réalisées notamment à l'aide de la cytométrie en flux, permettent de suivre les différentes étapes de la cicatrisation dont plus particulièrement la phase inflammatoire, bien que le suivi de la deuxième phase, dite phase de granulation ou d' épidermisation (appelée également phase de prolifération) puisse également être réalisé. Ces analyses permettent de vérifier que la phase de granulation commence et que la phase inflammatoire ne persiste pas dans le temps, ce qui pourrait nuire à une bonne cicatrisation. Ainsi si l'on réalise un suivi par cytométrie en flux du nombre de granulocytes présents dans l' exsudât, on verra, au tout début de la phase inflammatoire que les granulocytes sont majoritaires. Si la phase inflammatoire se déroule correctement, quelques jours après la survenue de la plaie, le nombre de granulocytes aura fortement diminué, avec parallèlement une augmentation du nombre de monocytes et de fibroblastes qui permettent la formation du tissu de granulation. Si l'on constate que les granulocytes sont encore très nombreux trois jours après la survenue de la plaie, il est possible que la plaie présente un défaut dans la phase de résolution de l'inflammation qui peut trouver sa cause dans une infection bactérienne par exemple. Si le type de bactérie est identifié par l'analyse appropriée, le médecin pourra alors prescrire un traitement antibiotique, qui sera avantageusement injecté dans le dispositif afin d'être en contact avec la plaie et d'éliminer l'infection avant que des complications n'apparaissent.  The biological analyzes that can be performed on the exudate are multiple and varied. Thus, from the first day of the implementation of the method according to the invention, it is possible to carry out a phenotypic and functional monitoring of cell populations, such as, in particular, inflammatory cells or cutaneous cells. These analyzes, carried out in particular using flow cytometry, make it possible to follow the various stages of the cicatrization, particularly the inflammatory phase, although the follow-up of the second phase, called the granulation or epidermization phase (called also proliferation phase) can also be realized. These analyzes make it possible to verify that the granulation phase begins and that the inflammatory phase does not persist over time, which could hinder good healing. Thus, if flow cytometry is followed by the number of granulocytes present in the exudate, it will be seen at the very beginning of the inflammatory phase that the granulocytes are the majority. If the inflammatory phase proceeds correctly, a few days after the onset of the wound, the number of granulocytes will have greatly decreased, along with an increase in the number of monocytes and fibroblasts that allow the formation of granulation tissue. If it is found that the granulocytes are still very numerous three days after the onset of the wound, it is possible that the wound has a defect in the phase of resolution of the inflammation that can find its cause in a bacterial infection for example . If the type of bacteria is identified by the appropriate analysis, the doctor can then prescribe an antibiotic treatment, which will be advantageously injected into the device in order to be in contact with the wound and eliminate the infection before complications. 'appear.
Les analyses réalisées sur l' exsudât peuvent également permettre d'établir un suivi des médiateurs produits pendant la cicatrisation, tels que notamment les cytokines inflammatoires (TNF- a, IL12, ILl-β, IL6...) et anti-inflammatoires (TGF-β et IL-10), les médiateurs lipidiques comme les leucotriènes , les prostaglandines ou encore les facteurs de croissance (VEGF, PDGF) . Ces médiateurs peuvent notamment être quantifiés par un dosage ELISA. L'analyse de métabolites, et plus particulièrement de médiateurs contenus dans 1' exsudât permet également de suivre l'avancée de la cicatrisation. Ainsi, par exemple, si l' exsudât contient un taux anormalement élevé en quantité de cytokines inflammatoires, cela indique que la phase inflammatoire n'est pas terminée ce qui peut nuire à la bonne cicatrisation de la plaie. En effet, la présence prolongée de cytokines inflammatoires dans la plaie peut provoquer la dégradation de la matrice cellulaire et induire une chronicité de la plaie. Exudate analyzes can also be used to track mediators produced during the scarring, such as inflammatory cytokines (TNF-α, IL12, IL1-β, IL6, etc.) and anti-inflammatory cytokines (TGF-β and IL-10), lipid mediators such as leukotrienes, prostaglandins or even growth factors (VEGF, PDGF). These mediators can in particular be quantified by an ELISA assay. The analysis of metabolites, and more particularly of mediators contained in the exudate also makes it possible to follow the progress of the cicatrization. Thus, for example, if the exudate contains an abnormally high level of inflammatory cytokine content, this indicates that the inflammatory phase is not complete which may hinder the good healing of the wound. Indeed, the prolonged presence of inflammatory cytokines in the wound can cause degradation of the cell matrix and induce chronicity of the wound.
La méthode selon l'invention peut également comprendre une étape supplémentaire d'introduction d'une solution aqueuse ou non dans le dispositif. Ces solutions peuvent notamment permettre de réaliser un lavage de la plaie, par exemple une solution physiologique classique du type sérum physiologique, chlorure de sodium, eau stérile, eau savonneuse, ou encore une solution de lactate de Ringer. On peut également envisager l'introduction d'une solution comprenant un agent a n t i b a c t é r i e n et/ou un agent thérapeutique afin de traiter la plaie, auquel cas, la mise en contact de ces solutions sur le site cicatriciel sera prolongée, en comparaison à la mise en contact d'une solution de lavage sur le site cicatriciel sans utiliser de dispositif. Ainsi, si l'on souhaite nettoyer la plaie, on peut mettre au contact de la plaie une solution physiologique classique, par exemple après l'étape de positionnement du dispositif. On laisse la solution agir quelques minutes et on l'enlève du dispositif. D'une autre façon, si l'on souhaite traiter la plaie, on peut mettre au contact de la plaie une solution contenant un agent thérapeutiquement actif, par exemple tous les jours après l'étape d'observation macroscopique de la plaie et/ou de l'exsudat ou bien éventuellement après l'étape d'analyse de 1' exsudât. On laisse la solution agir plusieurs minutes voire heures ou encore jours et on l'enlève ensuite du dispositif si et seulement si la solution n'a pas été totalement absorbée au niveau de la plaie . Selon un autre mode de réalisation de la présente invention, la méthode comprend une étape supplémentaire dans laquelle une solution comprenant des agents thérapeutiquement actifs est mise au contact de la plaie à l'aide dudit dispositif. Ainsi, le dispositif utilisé dans la méthode permet de tester de nouveaux actifs, notamment des actifs cicatrisants ou antimicrobiens, directement au contact de la plaie. Ainsi, il sera possible d'utiliser diverses formes galéniques d'actifs, telles que notamment des solutions d'actifs permettant une action plus localisée sur la lésion, et plusieurs concentrations d'actifs. Ceci permettra donc de tester l'efficacité de certains actifs ainsi que de tester la tolérance de la plaie par rapport à la concentration de chacun des actifs. L'avantage majeur résidant bien évidemment dans la possibilité de tester une forme galénique particulière et atypique sur le site cicatriciel, c'est-à-dire non envisageable en temps normal sans l'aide dudit dispositif de la demanderesse, telle qu'une solution liquide d'agents actifs. De manière générale, les actifs sont choisis parmi : The method according to the invention may also comprise an additional step of introducing an aqueous solution or not into the device. These solutions may in particular make it possible to perform a washing of the wound, for example a physiological saline-type standard solution, sodium chloride, sterile water, soapy water or a solution of Ringer's lactate. It is also possible to envisage the introduction of a solution comprising an antibacterial agent and / or a therapeutic agent in order to treat the wound, in which case the bringing into contact of these solutions on the scar site will be prolonged, in comparison with the contacting a wash solution at the scar site without using a device. Thus, if it is desired to clean the wound, a conventional physiological solution may be brought into contact with the wound, for example after the step of positioning the device. The solution is allowed to act for a few minutes and removed from the device. In another way, if it is desired to treat the wound, a solution containing a therapeutically active agent may be brought into contact with the wound, for example every day after the macroscopic wound observation step and / or exudate or possibly after the exudate analysis step. The solution is left to act for several minutes to hours or days and then removed from the device if and only if the solution has not been fully absorbed into the wound. According to another embodiment of the present invention, the method comprises an additional step in which a solution comprising therapeutically active agents is brought into contact with the wound using said device. Thus, the device used in the method makes it possible to test new assets, in particular healing or antimicrobial active agents, directly in contact with the wound. Thus, it will be possible to use various galenic forms of assets, such as in particular asset solutions allowing a more localized action on the lesion, and several concentrations of active ingredients. This will test the effectiveness of certain assets and test the tolerance of the wound in relation to the concentration of each asset. The major advantage obviously resides in the possibility of testing a particular and atypical dosage form on the scar site, that is to say not possible in normal time without the aid of said device of the applicant, such as a solution liquid of active agents. In general, the assets are chosen from:
-les antibactériens tels que la polymyxine B, les pénicillines, l'acide clavulanique , les t é t r a cy c 1 i ne s , la minocycline, la chlorotétracycline , les aminoglycosides , l'amikacine, la gentamicine, la néomycine, l'argent et ses sels ( sul fadi a z i ne argentique) .  antibacterials such as polymyxin B, penicillins, clavulanic acid, tetracyclines, minocycline, chlorotetracycline, aminoglycosides, amikacin, gentamicin, neomycin, silver and its salts (sulfadi azi silver).
-les antiseptiques tels que le mercurothiolate de sodium, l'éosine, la chlorhexidine, le borate de phénylmercure, l'eau oxygénée, la liqueur de Dakin, le triclosan, le biguanide, 1 ' hexamidine , le thymol, le lugol, la povidone iodée, le merbromine, le chlorure de benzalkonium et de benzéthonium, l'éthanol et 1 ' isopropanol .  antiseptics such as sodium mercurothiolate, eosin, chlorhexidine, phenylmercury borate, hydrogen peroxide, Dakin liquor, triclosan, biguanide, hexamidine, thymol, lugol, povidone iodine, merbromine, benzalkonium and benzethonium chloride, ethanol and isopropanol.
-les antiviraux tels l'acyclovir, la famciclovir, le ritonavir. -les antifongiques tels que les polyènes, le nystatin, antivirals such as acyclovir, famciclovir, ritonavir. antifungals such as polyenes, nystatin,
1 ' amphotéri ci ne B, la natamycine, les imidazolés (miconazole, kétoconazole , clotrimazole , éconazole, bifonazole, butoconazole , fenticonazole, isoconazole, oxiconazole, sertoconazole , sulconazole, thiabendazole , tioconazole ) , les triazolés, les allylamines, la terbinafine, 1 ' amorolfine, la naftifine, la buténafine. -les antidouleurs tels que le paracétamol, la codéine, le dextropropoxyphène , le tramadol, la morphine et ses dérivés, les corticoïdes et ses dérivés. 1 amphotericin B, natamycin, imidazoles (miconazole, ketoconazole, clotrimazole, econazole, bifonazole, butoconazole, fenticonazole, isoconazole, oxiconazole, sertoconazole, sulconazole, thiabendazole, tioconazole), triazoles, allylamines, terbinafine, 1 amorolfine, naftifine, butenafine. pain-relievers such as paracetamol, codeine, dextropropoxyphene, tramadol, morphine and its derivatives, corticosteroids and its derivatives.
- les cicatrisants : le KSOS, le sucralfate, 1 ' allantoïne , le collagène ou l'acide hyaluronique .  the cicatrizants: KSOS, sucralfate, allantoin, collagen or hyaluronic acid.
Un autre objet de l'invention est une méthode d'analyse de la cicatrisation d'une plaie chez un animal comprenant les étapes suivantes : Another object of the invention is a method for analyzing wound healing in an animal comprising the following steps:
créer une plaie;  create a wound;
- fixer le dispositif de prélèvement sur le pourtour de la plaie ;  - fix the sampling device around the wound;
faire une observation macroscopique de la plaie et/ou de l' exsudât ; et/ou  make a macroscopic observation of the wound and / or exudate; and or
prélever l' exsudât contenu dans ledit dispositif et analyser ledit exsudât.  withdrawing the exudate contained in said device and analyzing said exudate.
La présente méthode, de même que la méthode précédemment décrite supra, sont réalisées sur l'animal. Par animal, on entend, au sens de la présente invention, un animal ou l'être humain. L'animal chez lequel on veut étudier la progression de la cicatrisation peut notamment être une souris, un porc et/ou un rat. Il peut également s'agir de l'être humain, en particulier des personnes souffrant d'un trouble métabolique ou d'une pathologie (tel que un diabète, une immunodéficience , une malnutrition, ou encore une insuffisance veineuse) qui influence le phénomène de cicatrisation.  The present method, as well as the method previously described above, are carried out on the animal. By animal is meant, in the sense of the present invention, an animal or the human being. The animal in which it is desired to study the progression of cicatrization may especially be a mouse, a pig and / or a rat. It may also be the human being, in particular people suffering from a metabolic disorder or pathology (such as diabetes, immunodeficiency, malnutrition, or venous insufficiency) which influences the phenomenon of healing.
Dans le cas du murin, avant de créer la plaie, ledit animal doit être préparé pour l'opération. Ainsi, on procède tout d'abord à l'anesthésie locale ou générale de l'animal. L'anesthésie peut notamment être réalisée par injection d'une solution anesthésiante pouvant être un mélange de kétamine et de xylazine. Après anesthésie de l'animal, on attend le temps nécessaire pour que l'anesthésie fasse effet. Si besoin, l'animal est ensuite tondu sur la zone où l'on souhaite créer la plaie. Cette étape-là est une étape dont on peut s'affranchir dans le cas de l'être humain. Néanmoins, selon les cas, elle peut être adaptée, et ceci au moyen d'une anesthésie locale de la zone de création de la plaie. On procède alors à la création d'une plaie sur l'animal. La plaie peut notamment être superficielle ou profonde c'est-à-dire qu'elle va jusqu'à l'hypoderme ou jusqu'au tissu musculaire. In the case of murine, before creating the wound, said animal must be prepared for the operation. Thus, it proceeds first to the local or general anesthesia of the animal. In particular, anesthesia can be performed by injecting an anesthetic solution that can be a mixture of ketamine and xylazine. After anesthesia of the animal, we wait for the time necessary for the anesthesia to take effect. If necessary, the animal is then mowed on the area where it is desired to create the wound. This step is a step that can be overcome in the case of the human being. Nevertheless, depending on the case, it can be adapted, and this by means of local anesthesia of the wound creation zone. We then proceed to the creation of a wound on the animal. In particular, the wound can be superficial or deep, that is to say it goes as far as the hypodermis or to the muscle tissue.
Qu'elles soient superficielles ou profondes, la littérature décrit déjà plusieurs manières de réaliser une plaie. Les plaies peuvent être de natures différentes selon les domaines d'études qui sont privilégiés.  Whether superficial or deep, the literature already describes several ways to achieve a wound. The wounds can be of different natures according to the fields of study which are privileged.
Dans la méthode selon l'invention, la plaie est créée mécaniquement, chimiquement, thermiquement et/ou par rayonnement. La plaie peut être créée mécaniquement à l'aide d'outils tels que des ciseaux, un emporte-pièce ou « biopsy punch ». Dans ce cas-là, on peut tracer la délimitation de la future lésion cutanée, en utilisant par exemple un marqueur et un patron. La peau de l'animal peut alors être pincée pour être coupée au ciseau ou à l'aide d'un scalpel, en suivant la ligne délimitant la lésion cutanée ou alors la peau peut être tendue afin d'y exercer une pression à l'aide d'un emporte-pièce ou « biopsy punch ». Des plaies superficielles peuvent également être créées mécaniquement. On peut notamment faire un « stripping » en apposant un adhésif puis en le retirant de la future zone de création de la plaie. En répétant l'opération plusieurs fois, il est ainsi possible de créer une lésion plus ou moins superficielle à la surface de la peau. D'une manière semblable, il est également possible d'effectuer un frottement prolongé sur l'épiderme à l'aide d'outils tel qu'une râpe. D'autres moyens de création de lésion peuvent également être considérés tels que notamment les produits chimiques. Une solution caustique (soude, acide nitrique...) peut être déposée sur la partie de la peau à léser. La concentration de l'agent utilisé ainsi que la durée d'exposition détermineront la profondeur des plaies. Ce type de blessure s'apparente aux brûlures (source chaude et/ou froide, électrique, rayonnement...) qu'il est également possible de reproduire. Ainsi, tout comme l'emploi de produits chimiques, la profondeur et l'étendue de la brûlure dépendra essentiellement de la durée et des propriétés physico-chimiques des outils ou solutions employés. De manière plus particulière, des systèmes de dépression pourront être employés afin de produire des décollements (bulles de succion) ou phlyctènes. On peut également envisager des procédures d'écrasement de la peau, mais aussi des procédures de ligature ou de section vasculaire, afin d'obtenir des plaies ischémiques. Il sera également possible de créer une plaie avec un appareil émettant un rayonnement, tel que le LASER ou des rayons ionisants de type β ou gamma . In the method according to the invention, the wound is created mechanically, chemically, thermally and / or by radiation. The wound can be created mechanically using tools such as scissors, a cookie cutter or "biopsy punch". In this case, we can trace the delineation of the future skin lesion, using for example a marker and a pattern. The skin of the animal can then be pinched to be cut with a chisel or with a scalpel, following the line delimiting the cutaneous lesion or the skin can be stretched to exert a pressure on the skin. using a cookie cutter or "biopsy punch". Superficial wounds can also be created mechanically. In particular, a "stripping" can be done by affixing an adhesive and then removing it from the future area of creation of the wound. By repeating the operation several times, it is thus possible to create a more or less superficial lesion on the surface of the skin. In a similar way, it is also possible to carry out a prolonged friction on the epidermis with the aid of tools such as a rasp. Other means of lesion creation can also be considered such as in particular chemicals. A caustic solution (sodium hydroxide, nitric acid ...) can be deposited on the part of the skin to be damaged. The concentration of the agent used and the duration of exposure will determine the depth of the wounds. This type of injury is similar to burns (hot and / or cold, electrical, radiation ...) that can also be reproduced. Thus, just like the use of chemicals, the depth and extent of the burn will depend essentially on the duration and physicochemical properties of the tools or solutions used. In particular, depression systems may be employed to produce detachments (suction bubbles) or phlyctenes. Crushing procedures can also be considered skin, but also ligation or vascular section procedures, to obtain ischemic wounds. It will also be possible to create a wound with a device emitting radiation, such as LASER or β or gamma ionizing rays.
Le dispositif de prélèvement est alors fixé sur la peau saine autour de la plaie au moyen de son interface adhésive comme décrit précédemment .  The sampling device is then attached to the healthy skin around the wound by means of its adhesive interface as described above.
L'observation macroscopique de la plaie est réalisée de façon préférentielle en prenant des photographies de la plaie comme décrit précédemment. Le suivi biologique de la plaie par prélèvement de l'exsudat contenu dans le dispositif et son analyse est réalisé comme décrit précédemment. Ainsi, on peut notamment réaliser le suivi phénotypique et fonctionnel de diverses populations cellulaires, telles que notamment les granulocytes , les lymphocytes, les monocytes, les f ib r ob 1 a s t e s , et/ou réaliser le suivi de métabolites contenus dans l'exsudat tels que notamment les cytokines, les médiateurs lipidiques, les facteurs de croissance, voire également le suivi de microorganismes, tel que décrit précédemment .  Macroscopic observation of the wound is preferentially performed by taking photographs of the wound as previously described. The biological monitoring of the wound by sampling the exudate contained in the device and its analysis is performed as described above. Thus, it is possible in particular to carry out the phenotypic and functional monitoring of various cell populations, such as, in particular, granulocytes, lymphocytes, monocytes, fibroblasts, and / or to carry out the monitoring of metabolites contained in the exudate such as that especially cytokines, lipid mediators, growth factors, or even the monitoring of microorganisms, as described above.
De plus, il peut être intéressant d'étudier l'influence de divers facteurs pathologiques ou physiologiques sur la cicatrisation de la plaie sur l'animal. Ainsi, on peut comparer la cicatrisation d'un animal présentant un état physiologique particulier par rapport à celle d'un animal sain. De plus, puisque la méthode selon l'invention met en œuvre un dispositif non-invasif, on peut réaliser un suivi fiable des médiateurs et des métabolites produits dès la création de la plaie chez l'animal, ce qui n'était pas possible avec les dispositifs invasifs implantés sous la peau de l'art antérieur.  In addition, it may be interesting to study the influence of various pathological or physiological factors on the healing of the wound on the animal. Thus, one can compare the healing of an animal with a particular physiological state compared to that of a healthy animal. In addition, since the method according to the invention implements a non-invasive device, it is possible to reliably monitor the mediators and metabolites produced as soon as the wound is created in the animal, which was not possible with invasive devices implanted under the skin of the prior art.
La méthode selon l'invention peut également comprendre une étape supplémentaire de lavage de la plaie par une solution physiologique comprenant un agent antibactérien et/ou un agent thérapeutique, telle que décrite précédemment. Ainsi, si l'on souhaite nettoyer la plaie, on peut mettre au contact de la plaie une solution comprenant un agent antibactérien, par exemple après l'étape de positionnement du dispositif. On laisse la solution agir quelques minutes et on l'enlève du dispositif. Au contraire, si l'on souhaite traiter la plaie, on peut mettre au contact de la plaie une solution contenant un agent thérapeutiquement actif, par exemple plusieurs minutes voire heures ou encore jours et ce tous les jours après l'étape de prise de la photographie et/ou après l'étape d'analyse de l' exsudât. On laisse la solution agir sur le site et on l'enlève du dispositif si et seulement si elle n'a pas été totalement absorbée au niveau de la plaie. Cette étape supplémentaire peut notamment permettre d'étudier l'influence et l'efficacité d'un agent thérapeutiquement actif sur la cicatrisation de la plaie de l'animal. The method according to the invention may also comprise an additional step of washing the wound with a physiological solution comprising an antibacterial agent and / or a therapeutic agent, as described above. Thus, if it is desired to clean the wound, a solution comprising an antibacterial agent may be placed in contact with the wound, for example after the step of positioning the device. The solution is allowed to act for a few minutes and removed from the device. On the contrary, if we wish to treat the wound, a solution containing a therapeutically active agent may be placed in contact with the wound, for example several minutes or even hours or days and this every day after the photographing step and / or after the stage of analysis of the exudate. The solution is allowed to act on the site and removed from the device if and only if it has not been fully absorbed into the wound. This additional step can in particular make it possible to study the influence and the effectiveness of a therapeutically active agent on the healing of the wound of the animal.
Il sera ainsi possible, par exemple, d'appliquer la méthode selon l'invention à deux groupes d'animaux, un groupe de contrôle d'animaux qui n'est pas traité par un agent thérapeutiquement actif et un groupe test d'animaux qui reçoit un traitement avec agent thérapeutiquement actif, et ce tous les jours. En comparant les photographies prises entre les deux groupes d'animaux, et/ou en comparant les analyses biologiques des exsudats, on pourra vérifier si l'agent thérapeutiquement actif améliore la cicatrisation des plaies et adapter le dosage ou la fréquence d'administration du traitement .  It will thus be possible, for example, to apply the method according to the invention to two groups of animals, an animal control group which is not treated with a therapeutically active agent and a test group of animals which receives treatment with a therapeutically active agent every day. By comparing the photographs taken between the two groups of animals, and / or by comparing the biological analyzes of the exudates, it will be possible to check whether the therapeutically active agent improves wound healing and to adapt the dosage or the frequency of administration of the treatment. .
L'invention sera mieux comprise à la lumière des figures suivantes qui ne sont qu' illustratives et ne sauraient en rien limiter l'invention. The invention will be better understood in the light of the following figures which are only illustrative and can not in any way limit the invention.
La figure 1 est une vue en coupe transversale d'un dispositif permettant la mise en œuvre de l'invention.  Figure 1 is a cross sectional view of a device for implementing the invention.
La figure 2 est une photographie d'une souris sur laquelle on a créé une plaie dorsale.  Figure 2 is a photograph of a mouse on which a dorsal wound has been created.
La figure 3 est une photographie de la souris de la figure 2 sur laquelle on a fixé la chambre d'un dispositif de prélèvement sur la peau saine autour de la plaie par un adhésif.  Figure 3 is a photograph of the mouse of Figure 2 on which the chamber of a sampling device was placed on the healthy skin around the wound by an adhesive.
La figure 4 est une photographie de la souris de la figure 3 sur laquelle on a fixé le moyen de fermeture sur la chambre du dispositif au moyen d'une goupille.  Figure 4 is a photograph of the mouse of Figure 3 on which the closure means was fixed to the device chamber by means of a pin.
La figure 5 représente différentes photographies d'une plaie sur une souris saine, les photographies étant prises à différents intervalles de temps à partir du jour de la création de la plaie (J0) jusqu'au 14ème jour après la création de la plaie (J14) . Figure 5 shows different photographs of a wound on a healthy mouse, the photographs being taken at different time intervals from the day of wound creation (D0) to 14 days after wound creation (D14).
La figure 6 représente les différents résultats de l'analyse par cytométrie en flux des populations cellulaires contenues dans 1' exsudât issu d'une plaie sur une souris saine, les analyses étant réalisées à différents intervalles de temps à partir du 1er jour après la création de la plaie (Jl) jusqu'au 7ème jour après la création de la plaie (J7) .  FIG. 6 represents the different results of the flow cytometric analysis of the cell populations contained in the exudate resulting from a wound on a healthy mouse, the analyzes being carried out at different time intervals starting from the first day after the creation. from the wound (J1) until the 7th day after the creation of the wound (J7).
La figure 7 est un graphique représentant la quantité d'une cytokine anti-inflammatoire (TGF-β) , mesuré par dosage ELISA, contenues dans les exsudats issus de plaies dorsales chez des souris saines .  Figure 7 is a graph showing the amount of an anti-inflammatory cytokine (TGF-β), measured by ELISA, contained in exudates from dorsal wounds in healthy mice.
L'invention va être décrite plus en détails à l'aide des exemples suivants qui sont donnés à titre purement illustratif et non limitatif. The invention will be described in more detail with the aid of the following examples which are given for purely illustrative and non-limiting purposes.
Exemples : Examples:
Exemple 1 : Création d' une plaie et mise en place du dispositif sur la plaie dorsale de la souris .  Example 1: Creation of a wound and placement of the device on the back wound of the mouse.
Afin de créer une plaie sur une souris telle que photographiée sur la Figure 2, la souris est d'abord anesthésiée par injection d'un mélange de kétamine et de xylazine par voie intra-péritonéale . Ensuite, on coupe la peau de la souris avec un ciseau, sur sa partie dorsale .  In order to create a wound on a mouse as photographed in FIG. 2, the mouse is first anesthetized by injecting a mixture of ketamine and xylazine intraperitoneally. Then, cut the skin of the mouse with a chisel, on its dorsal part.
On va placer sur la souris le dispositif (1) de la figure 1. Le dispositif (1) est constitué d'une chambre tubulaire (2) comprenant une paroi latérale (3), et deux extrémités, inférieure (4) et supérieure (5), ouvertes. Ladite extrémité inférieure (4) de la chambre tubulaire (2) présente une collerette (6) externe en matériau souple. L'interface (7) du dispositif (1) est constituée d'une couche mince de colle chirurgicale, appliquée sur la surface inférieure de la collerette (6) de la chambre tubulaire (2) . Un moyen de fermeture (8) du dispositif (1) est fixé à la partie supérieure de la chambre tubulaire (2) au moyen d'une goupille (9) .  The device (1) of FIG. 1 is placed on the mouse. The device (1) consists of a tubular chamber (2) comprising a lateral wall (3), and two extremities, lower (4) and upper ( 5), open. Said lower end (4) of the tubular chamber (2) has an outer collar (6) of flexible material. The interface (7) of the device (1) consists of a thin layer of surgical glue applied to the lower surface of the collar (6) of the tubular chamber (2). A closing means (8) of the device (1) is fixed to the upper part of the tubular chamber (2) by means of a pin (9).
On retire le moyen de fermeture du dispositif en le dégoupillant. On enlève la goupille (9) afin de retirer le moyen de fermeture (8) du dispositif (1) . On enduit la surface inférieure de la collerette (6) de la chambre tubulaire (2) d'une couche mince de colle chirurgicale afin de constituer l'interface (7) du dispositif. Le dispositif (1) est positionné au-dessus de la plaie de manière à la circonscrire. On exerce une pression suffisante sur la partie supérieure du dispositif (1) jusqu'à la prise complète de l'adhésif sur la peau de la souris selon la figure 2. On enduit la surface extérieure et le pourtour de la collerette (6) du dispositif (1) ainsi que la peau à proximité du dispositif de colle chirurgicale jusqu'à prise complète de l'adhésif tel que photographié sur la figure 3. On replace le moyen de fermeture (8) sur le dispositif en insérant une goupille (9) et en l'insérant dans des orifices placés sur la chambre (2) du dispositif (1) et sur le moyen de fermeture (8) afin de maintenir ces deux éléments ensemble. Le dispositif (1) est alors fixé sur le dos de la souris tel que photographié sur la figure 3. The closure means is removed from the device by unhooking it. The pin (9) is removed in order to remove the means of closure (8) of the device (1). The lower surface of the flange (6) of the tubular chamber (2) is coated with a thin layer of surgical glue to form the interface (7) of the device. The device (1) is positioned above the wound so as to circumscribe it. Sufficient pressure is applied on the upper part of the device (1) until the adhesive is completely taken on the skin of the mouse according to FIG. 2. The outer surface and the periphery of the collar (6) are coated. device (1) as well as the skin near the surgical glue device until the adhesive is fully set as shown in FIG. 3. The closure means (8) are placed on the device by inserting a pin (9). ) and inserting it into orifices placed on the chamber (2) of the device (1) and on the closing means (8) in order to hold these two elements together. The device (1) is then fixed on the back of the mouse as photographed in FIG.
Exemple 2 Suivi photographique de 1 ' avancée de la cicatrisation d' une plaie dorsale chez la souris . EXAMPLE 2 Photographic follow-up of the progress of wound healing of a dorsal wound in mice.
On réalise l'analyse de la progression de la cicatrisation d'une plaie chez une souris saine sur laquelle on a créé une plaie selon l'exemple 1 et positionné un dispositif (1) toujours selon l'exemple 1. La souris est anesthésiée avec un gaz et disposée sur un banc de photographie comprenant des graduations régulières afin de réaliser un étalonnage. On enlève la goupille (9) afin de retirer le moyen de fermeture (8) du dispositif (1) . On prend la photographie avec un appareil photographique classique, que l'on peut trouver dans le commerce. On replace le moyen de fermeture (8) sur le dispositif en chauffant une goupille (9) et en l'insérant dans des orifices placés sur la chambre (2) du dispositif (1) et sur le moyen de fermeture (8) afin de maintenir ces deux éléments ensemble. Une photographie par jour est prise, et ce dès le jour de la création de la plaie et pendant 14 jours. Les différentes photographies prises sont présentées sur la figure 4. Comme on l'observe sur les photographies, de JO à J5, correspondant à la phase inflammatoire et au démarrage de la phase proliférative, la taille de la plaie ne varie pas mais l'on assiste à la formation d'un tissu de granulation recouvrant progressivement le fascia musculaire mis à nu lors de l'excision du tissu cutané. De J5 à J14 la taille de la plaie diminue grâce au développement du tissu de granulation contenant les myofibroblastes permettant la contraction de la plaie. A J14, la plaie est quasiment refermée. The analysis of the progression of the cicatrization of a wound is carried out in a healthy mouse on which a wound has been created according to example 1 and positioned a device (1) still according to example 1. The mouse is anesthetized with a gas and arranged on a photography bench with regular graduations to perform a calibration. The pin (9) is removed in order to remove the closure means (8) from the device (1). We take photography with a conventional camera, which can be found on the market. The closure means (8) is replaced on the device by heating a pin (9) and inserting it into orifices placed on the chamber (2) of the device (1) and on the closing means (8) in order to maintain these two elements together. One photograph per day is taken, from the day of the creation of the wound and for 14 days. The different photographs taken are presented in Figure 4. As seen in the photographs, from OJ to D5, corresponding to the inflammatory phase and the start of the proliferative phase, the size of the wound does not vary, but attend training a granulation tissue gradually covering the muscular fascia exposed during the excision of the cutaneous tissue. From day 5 to day 14 the wound size decreases thanks to the development of the granulation tissue containing the myofibroblasts allowing the contraction of the wound. At day 14, the wound is almost closed.
Exemple 3 : Suivi cellulaire de l'avancée de la cicatrisation d'une plaie dorsale chez une souris saine. Example 3: Cellular monitoring of the advanced healing of a dorsal wound in a healthy mouse.
On réalise l'analyse de la progression de la cicatrisation d'une plaie sur une souris saine sur laquelle on a créé une plaie selon l'exemple 1 et positionné un dispositif de prélèvement toujours selon l'exemple 1. Avant de prélever l' exsudât, la souris est anesthésiée avec un gaz. Une solution physiologique est injectée à la seringue au travers d'un septum placé sur le moyen de fermeture du dispositif. On aspire et on réinjecte à la seringue trois fois 1' exsudât dilué par la solution physiologique afin de bien laver le site de la plaie et de récupérer le maximum de cellules pour 1 ' analyse .  The analysis of the progression of the healing of a wound is carried out on a healthy mouse on which a wound has been created according to example 1 and positioned a sampling device according to example 1. Before taking the exudate , the mouse is anesthetized with a gas. A physiological solution is injected into the syringe through a septum placed on the closure means of the device. The exudate diluted with physiological saline is aspirated and reinjected three times with the syringe so as to thoroughly wash the site of the wound and recover the maximum number of cells for analysis.
L' exsudât dilué est prélevé à la pipette et est transféré dans un flacon muni d'un septum.  The diluted exudate is pipetted and transferred to a septum vial.
Afin de déterminer la cinétique d' infiltration des granulocytes, caractérisés par l'expression des antigènes Ly6G et 7/4 à leur surface, les cellules sont incubées durant 15 minutes avec des anticorps anti-souris Ly6g et 7/4 chacun couplés à des fluorochromes . Enfin les cellules de l' exsudât sont de nouveau lavées. Les populations cellulaires de l' exsudât sont analysées par cytométrie en flux. Les données sont acquises par un cytomètre FACScalibur (BD Biosciences) en utilisant le logiciel CellQuest Pro.  In order to determine the infiltration kinetics of the granulocytes, characterized by the expression of the Ly6G and 7/4 antigens on their surface, the cells are incubated for 15 minutes with Ly6g and 7/4 anti-mouse antibodies each coupled to fluorochromes. . Finally the cells of the exudate are washed again. The cell populations of the exudate are analyzed by flow cytometry. The data is acquired by a FACScalibur (BD Biosciences) cytometer using CellQuest Pro software.
Le prélèvement de l' exsudât et son analyse par cytométrie en flux sont réalisés 24 heures après la création de la plaie et répétés chaque jour pendant une semaine. Les résultats, présentant les différentes intensités de fluorescence pour chaque anticorps, sont regroupés sur la figure 6. A Jl post-lésion, on observe un exsudât composé essentiellement de granulocytes, représentés par un fort marquage Ly6G et 7/4. Dès J2 post-lésion, on observe une diminution progressive du marquage Ly6G jusqu'à sa disparition totale, tandis que le marquage 7/4 est conservé. Cette analyse des populations cellulaires composant l' exsudât permet de suivre la progression de la phase inflammatoire, caractérisée par l'infiltration des granulocytes , puis par leur disparition lors du démarrage de la phase proliférative . Exemple 4 Comparaison du nombre de cytokines antiinflammatoires contenues dans l' exsudât issu d'une plaie dorsale d'une souris saine Exudate sampling and flow cytometry analysis were performed 24 hours after wound creation and repeated daily for one week. The results, showing the different fluorescence intensities for each antibody, are grouped together in FIG. 6. At post-lesion, an exudate composed essentially of granulocytes, represented by a strong Ly6G and 7/4 marking, is observed. From D2 post-lesion, a gradual decrease in Ly6G labeling is observed until its total disappearance, while the 7/4 labeling is preserved. This analysis of The cell populations composing the exudate can be used to monitor the progression of the inflammatory phase, characterized by the infiltration of the granulocytes, then by their disappearance at the start of the proliferative phase. EXAMPLE 4 Comparison of the number of anti-inflammatory cytokines contained in the exudate resulting from a dorsal wound of a healthy mouse
On réalise le suivi de l'avancée de la cicatrisation d'une plaie sur un groupe de 2 souris saines. Sur chacune des deux souris, on créé une plaie selon l'exemple 1 et on positionne un dispositif de prélèvement toujours selon l'exemple 1. Avant de prélever 1' exsudât, chaque souris est anesthésiée avec un gaz. Une solution physiologique de volume connu est injectée à la seringue au travers d'un septum placé sur la chambre du dispositif. On aspire et on réinjecte à la seringue trois fois l' exsudât dilué par la solution physiologique afin de bien laver le site de la plaie, d'homogénéiser l'exsudat. L'exsudat dilué est prélevé à la seringue et est transféré dans un flacon muni d'un septum puis centrifugée afin de ne récupérer que le surnageant contenant les cytokines. Les cytokines inflammatoires et anti-inflammatoires contenues dans l'exsudat sont analysées par dosage ELISA et sont réalisés 48 heures après la création de la plaie et répétés chaque jour pendant une semaine. Le dosage de la cytokine TGF-β est représenté sur la figure 6. On observe une forte progression du taux de cytokines anti- inflammatoires du type TGF-β dès J2 post-lésion. Cette surproduction de cette cytokine anti-inflammatoire atteint son maximum à J5 post lésion, date de la fin de la phase inflammatoire, avant de revenir à un stade normal, à la fin du processus de cicatrisation.  The progress of wound healing is monitored on a group of 2 healthy mice. On each of the two mice, a wound was created according to Example 1 and a sampling device was always positioned according to Example 1. Before taking the exudate, each mouse was anesthetized with a gas. A physiological solution of known volume is injected into the syringe through a septum placed on the chamber of the device. The exudate diluted with physiological saline is aspirated and reinjected three times with the syringe so as to wash the site of the wound well, to homogenize the exudate. The diluted exudate is taken by syringe and transferred to a septum vial and centrifuged to recover only the supernatant containing the cytokines. Inflammatory and anti-inflammatory cytokines contained in the exudate are analyzed by ELISA and are performed 48 hours after the creation of the wound and repeated daily for one week. The cytokine TGF-β assay is shown in FIG. 6. A strong progression of the level of anti-inflammatory cytokines of the TGF-β type is observed as early as D2 post-lesion. This overproduction of this anti-inflammatory cytokine reaches its peak at 5 days after the end of the inflammatory phase, before returning to a normal stage at the end of the healing process.

Claims

REVENDICATIONS
1. Méthode non-invasive d'analyse de la progression de la cicatrisation d'une plaie, comprenant les étapes suivantes: A non-invasive method of analyzing the progress of wound healing, comprising the steps of:
fixer un dispositif non invasif de prélèvement sur le pourtour de la plaie ;  attach a non-invasive collection device around the wound;
faire une observation macroscopique de la plaie et/ou de l'exsudat et/ou  make a macroscopic observation of the wound and / or exudate and / or
prélever l'exsudat contenu dans ledit dispositif et analyser ledit exsudât.  withdrawing the exudate contained in said device and analyzing said exudate.
2. Méthode selon la revendication 1 caractérisée en ce que le dispositif comprend une chambre ayant une paroi latérale, une extrémité inférieure ouverte et une extrémité supérieure, une ouverture d'accès étant disposée sur l'extrémité supérieure et/ou sur la paroi latérale de ladite chambre, ledit dispositif comprenant en outre un moyen de fermeture amovible de la chambre qui s'adapte sur l'ouverture d'accès de la chambre et un élément de maintien, éventuellement de forme tubulaire, circonscrit ou inscrit à ladite chambre, ouvert à ses deux extrémités, ledit dispositif étant destiné à être en contact avec la peau et à circonscrire la plaie lors de son utilisation par l'intermédiaire d'une interface qui est un adhésif disposé sur une jupe en matériau souple, ladite jupe étant maintenue entre la paroi latérale de la chambre et l'élément de maintien. 2. Method according to claim 1 characterized in that the device comprises a chamber having a side wall, an open bottom end and an upper end, an access opening being disposed on the upper end and / or the side wall of said chamber, said device further comprising a removable closure means of the chamber which fits on the access opening of the chamber and a holding element, possibly of tubular shape, circumscribed or inscribed in said chamber, open to both ends, said device being intended to be in contact with the skin and circumscribing the wound during its use via an interface which is an adhesive disposed on a skirt of flexible material, said skirt being held between the side wall of the chamber and the holding member.
3. Méthode selon la revendication 1 ou 2, caractérisée en ce que l'observation macroscopique de la plaie et/ou de l'exsudat comprend la détermination des paramètres physico-chimiques de ladite plaie ou dudit exsudât. 3. Method according to claim 1 or 2, characterized in that the macroscopic observation of the wound and / or exudate comprises the determination of physico-chemical parameters of said wound or said exudate.
4. Méthode selon l'une quelconque des revendications 1 à 3, caractérisée en ce que l'observation macroscopique est suivie ou simultanée à une comparaison avec un ou des moyens de suivi macroscopiques étalons. 4. Method according to any one of claims 1 to 3, characterized in that the macroscopic observation is followed or simultaneous to a comparison with one or more standard macroscopic monitoring means.
5. Méthode selon l'une quelconque des revendications 1 à 4, caractérisée en ce que l' exsudât est prélevé au travers d'un septum positionné sur le dispositif de prélèvement. 5. Method according to any one of claims 1 to 4, characterized in that the exudate is taken through a septum positioned on the sampling device.
6. Méthode selon l'une quelconque des revendications 1 à 5, caractérisée en ce que l'analyse de l' exsudât permet de déterminer les métabolites, les composants cellulaires, et/ou les microorganismes contenus dans ledit exsudât et comprend la détermination des paramètres physico-chimiques dudit exsudât. 6. Method according to any one of claims 1 to 5, characterized in that the analysis of the exudate makes it possible to determine the metabolites, the cellular components, and / or the microorganisms contained in said exudate and comprises the determination of the parameters physico-chemical said exudate.
7. Méthode selon l'une quelconque des revendications 1 à 6, caractérisée en ce qu'elle comprend une étape de lavage de la plaie. 7. Method according to any one of claims 1 to 6, characterized in that it comprises a step of washing the wound.
8. Méthode selon l'une quelconque des revendications 1 à 7, caractérisée en ce qu'elle comprend une étape supplémentaire dans laquelle une solution de lavage ou une solution comprenant un ou plusieurs agents thérapeutiquement actifs est mise en contact avec la plaie à l'aide dudit dispositif. 8. Method according to any one of claims 1 to 7, characterized in that it comprises an additional step in which a washing solution or a solution comprising one or more therapeutically active agents is brought into contact with the wound to the wound. using said device.
PCT/FR2012/053069 2011-12-22 2012-12-21 Method for the microscopic and macroscopic analysis of wound healing progress WO2013093381A2 (en)

Applications Claiming Priority (4)

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FR1162295A FR2984722B1 (en) 2011-12-22 2011-12-22 NON-INVASIVE DEVICE FOR COLLECTING THE EXUDES OF A WOUND, USE THEREOF AND KIT COMPRISING SAID DEVICE
FR1162344A FR2984719B1 (en) 2011-12-22 2011-12-22 METHOD OF ANALYZING THE PROGRESSION OF WOUND HEALING AT MICROSCOPIC AND MACROSCOPIC LEVELS
FR1162344 2011-12-22
FR1162295 2011-12-22

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