CZ29964U1 - Sensor for detecting saturation degree of dressing cover with body liquids - Google Patents

Abstract

A sensor (1) for detecting the degree of saturation of a bandage cover (11) with body fluids comprises an electrochemical cell formed by an electrode system (2) consisting of an anode (3) and a cathode (4) and generating electrical voltage upon contact with the body fluid. Each of the electrodes of the electrode system (2) is formed as at least one printing layer on the support base (5). Furthermore, the sensor (1) comprises a flat supporting base (5) with a thickness up to 1 mm and an indicator element (6) for visual indication of the degree of saturation of the bandage cover. The indicator element (6) is formed by at least one transparent conductive electrode formed as at least one printing layer on the support base (5) which is directly connected to the poles of the electrode system (2). The indicator element is made of a material exhibiting an electrochromic effect actuated by the voltage generated in the contact of the electrode system (2) with the body fluid.

Description

Sensor for detecting the degree of saturation of the dressing cover with body fluids

Field of technology

The technical solution relates to the field of detecting the degree of saturation of the dressing cover with body fluids.

Prior art

Acute and chronic wounds are a serious health problem and their unsuccessful treatment has significant health, social and economic consequences in the form of increased costs for hospitalization and reduced quality of life for patients. Especially for chronic wounds, it is necessary to ensure a stable moist environment with the removal of excess tissue fluid for successful treatment. However, the formation and amount of such a fluid changes very often. Excess fluid is collected into the outer layers of the dressing using a suitable absorbent material. However, knowledge of hydration of the wound under the dressing is essential for this method. If the wound is dry, its healing is inhibited. Conversely, if the amount of secretion is large, the wound is calibrated with its surroundings and the wound itself is exposed to the autolytic effect of the wound secretion. Frequent wound dressings and inspections can disrupt the natural processes in the wound and, as a result, impair the wound healing process. In addition, repeated and unnecessary inspections are demanding on the dressing material and the time required for the work of medical staff. This increases the financial cost of wound care.

For these reasons, it would be very appropriate to monitor the state of hydration of the wound without the need for unnecessary or, conversely, insufficient controls. A suitable solution is to monitor the condition of the wound, especially its hydration during the healing process.

Currently, pH monitoring using sensors placed on or around the wound is most often used as an indicator of wound healing. This method is based on the observation that the most common types of bacterial infection increase the pH value. While uninfected wound, healthy tissue may have a pH in the range of 5.5 to 6, pH values higher than 7.4 may signal infection in the wound. In the past, the monitoring of the pH value was solved by various approaches to the creation of electrode systems, including their preparation by printing techniques. The disadvantage of such a solution is the necessity of the presence of an electronic evaluation device for determining the exact pH value, which could detect changes in the wound healing state.

WO 2014188200 describes a mechanism for monitoring the amount of exudate in a wound dressing used on the principle of color change of the pH indicator. This change in pH is due to the exudate dissolving the soluble composition present in the dressing, which releases hydrogen or hydroxide ions into the exudate. This causes the color of the pH indicator to change and provides a visual indication of the exudate load on the dressing.

Sensors are designed to monitor wound moisture based on the assumption that it is necessary to ensure a suitable moisture level for optimal healing. Current wound humidity sensors are based on the principle of measuring the change in impedance or capacity. The presence of increased humidity in the case of a given sensor will cause a change in impedance or capacity. US 20080171957 discloses a sensor located in a dressing for measuring wound hydration without the need to remove the dressing from the wound. The measuring device consists of a pair of electrodes in a planar arrangement, which are isolated from each other. The electrodes are made of silver chloride. In the bandage, the terminals of the device for impedance measurement or electrochemical analysis are connected to the electrodes. The information obtained from the passage of direct and alternating current allows the external evaluation device to analyze the liquid in the dressing.

Temperature sensors are also used to indicate the course of wound healing, where the temperature difference is measured at two equivalent places on the body, in the sense of the wound site and the healthy site. Sensors are often based on thermistors.

The last group of sensors are pressure sensors, which are used to monitor the pressure, which gives information about the swelling of the crow. These sensors work on the principle of changing the resistance or capacitance depending on the elongation of the sensor due to the change in pressure. Pressure values measured by such sensors

-1 CZ 29964 AI are, however, affected by the attached bandage and subsequent fixation with a bandage and therefore the information value for doctors is relatively low.

The main disadvantage of all the above sensors is the need for external devices for measuring and evaluating their electrical signal. On the one hand, this increases the cost of monitoring, in addition, their transmission increases the risk of transmission of infection and the costs of their sterilization are not negligible. Comparing the costs with the information value and the impact on the effectiveness of subsequent treatment then reduces the use of such sensors.

The task of the technical solution is to create a sensor for detecting the degree of saturation of the wound cover with exudate, which will eliminate the above-mentioned shortcomings, will be cheap, efficient and its function will not depend on an external evaluation device. The sensor for detecting the degree of saturation of the wound cover with exudate according to this technical solution should have a universal use for various types of dressings, wound dressings or bandages intended for detecting their degree of saturation with body fluids.

The essence of the technical solution

The above-mentioned drawbacks are eliminated by the sensor for detecting the degree of saturation of the dressing cover by body fluids according to this technical solution.

The sensor for detecting the degree of saturation of the dressing cover with body fluid comprises an electrochemical cell, which is formed by an electrode system consisting of two electrodes, an anode and a cathode, and generating an electrical voltage after contact with the body fluid. Furthermore, the sensor comprises a flat support substrate with a thickness of up to 1 mm and an indication element for visually indicating the degree of saturation of the dressing cover, each of the electrodes of the electrode system being formed as at least one printing layer on the support substrate. The essence of the technical solution lies in the fact that the indicating element consists of at least one transparent conductive electrode, which is formed as at least one printing layer on the support substrate. The transparent conductive electrode is directly or indirectly connected to the poles of the electrode system and a structure is formed on it from materials exhibiting electrochromic or electrophoretic or electroluminescent or thermochromic visualization effect excited by voltage generated in contact of the electrode system with body fluid. The advantage of using a sensor is the fact that during healing it is necessary to ensure a constant circulation of tissue fluids without congestion and vice versa. The use of a sensor prevents disruption of the healing process due to premature dressing change. The course of healing can be monitored using the proposed sensor, which will allow a more sophisticated decision about the need to replace the cover bandage.

In a preferred embodiment, the display element is directly connected to the electrode system. In another preferred embodiment, the display element is indirectly connected to the electrode system via conductors.

The display element consists of a reference part and a visualization part for comparing the visual perception based on a change in the intensity of color or brightness or the contrast of the visualization part of the display element. The display element arranged on the support substrate represents a further advantage of the sensor, namely the possibility of detection without the need to use any other external electronic devices. The healing process and maintaining suitable conditions for wound healing, ensuring a suitable amount of exudate, ie the possibility of its sorption into the dressing of a dressing equipped with a humidity sensor is indicated by color intensity, brightness, contrast of the visualization part of the indicator, whose visual perception can be compared with the reference printed scale . Therefore, detection is easy even for an informed patient. The nursing staff or the instructed patient have the option of determining the suitability of the moment to replace the wound cover, which will streamline the healing process and would also reduce the overall cost of treatment.

In a preferred embodiment, the display element is made of a material having an electrochromic visualization effect. The electrochromic indicator element consists of a material from the group: WO ₃ , V ₂ O ₅ , NiO ₂ , Prussian blue and its analogues or conductive polymers based on poly (3,4-ethylenedioxythiophene) or PEDOT, polypyrrole, polyaniline and their derivatives

The electrode system consists of mutually compatible electrode materials of electrochemical cells of the type: Li / CuO, Li / LiFeS ₂ , Li / LiMnO ₂ , Li- (CF) _n , Zn / MnO ₂ , Zn / Ag ₂ O, Mg / MnO ₂ ,

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Zn / HgO, Ni / Cd, Ni / Zn, Ag / Zn. The electrode system, in the presence of body fluids and secretions, which are the electrolyte for the electrochemical cell, or the liquid medium for electrolyte formation, begins to produce an electrical voltage which begins to supply the low voltage indicator element. The given indication element therefore changes its state - hue, contrast, brightness - due to the given generated voltage.

The carrier substrate is a vapor-permeable film or a laminate thereof with a nonwoven fabric or a transparent film of polycarbonate, polyvinyl chloride, polyethylene, polyethylene terephthalate or paper or ceramic material. The surface of the support substrate is modified to increase the free surface energy.

The printing layer of the electrode system and / or the indicator element is formed by printing techniques such as flexographic printing, pad printing, screen printing, gravure printing, offset printing, injection printing, aerosol jet printing, spray application, slot-die or Mayer rod coating. All types of solvents that can be used to form a binder solution or to prepare a suspension, which form the main part of the print formulation, are preferably used as the solvent system for the printing formulations of the individual functional layers of the sensor. The given technologies of applying printing formulations to the printing substrate represent an economical and productive way of creating an indication system at different volumes of serial production. The print formulations contain at least one substance modifying the rheological and physical properties of the print formulation from the group of rheology modifier, surfactant, flow and flow modifier, foam modifier, drying modifier, layer adhesion modifier. The print formulation covers the print substrate well, does not form precipitates and dries in an even layer. The group of substances modifying the rheological and physical properties of the printing formulation includes poly (vinylpyrrolidone), poly (vinyl alcohol), poly (vinylphenol), hydroxyethyl cellulose, cellulose acetate, alkyd resins, poly (vinyl chloride), polystyrene, poly (vinylidene fluoride), hydroxypropylcellulose, ethylcellulose and polymethyl methacrylate, carboxymethyl cellulose. Multifunctional alcohols, monofunctional alcohols, ketones, acetates, glycol ethers are used to adjust the printing properties. Acrylates, epoxides, oxethanes, urethanes, monofunctional and multifunctional, are preferably used for UV-curable formulations. Surfactants, flow and flow modifiers, foam modifiers, drying modifiers, layer adhesion modifiers, dispersion stabilizers, initiators for thermally and radiation-initiated radical and cationic polymerizations are used to adjust surface tension and printing properties.

The subject of the technical solution is also a dressing tampon or bandage with at least one sensor for detecting the degree of saturation of the dressing cover with body fluid, the essence of which consists in that the sensor comprises an electrochemical cell consisting of an electrode system consisting of anode and cathode fluid electrical voltage. Furthermore, the sensor comprises a flat support base with a thickness of up to 1 mm and an indicator element for visual indication of the degree of saturation of the dressing cover. The indicating element consists of at least one transparent conductive electrode which is directly or indirectly connected to the poles of the electrode system and is formed of a material having an electrochromic or electrophoretic or electroluminescent or thermochromic visualization effect excited by voltage generated in contact of the electrode system with body fluid. The electrochemical cell and the indicator element are formed as printing layers on a support substrate.

In a preferred embodiment, the support substrate of the sensor has a lower part provided with an adhesive layer for attachment to a dressing pad or bandage.

The subject of the technical solution is also a dressing cover with at least one built-in sensor for detecting the degree of saturation of the dressing cover with body fluid, the essence of which consists in that the sensor comprises an electrochemical cell consisting of an electrode system consisting of anode and cathode and generating after contact with body fluid Tension. Furthermore, the sensor comprises a flat support base with a thickness of up to 1 mm and an indicator element for visual indication of the degree of saturation of the dressing cover. The indicating element consists of at least one transparent conductive electrode which is directly or indirectly connected to the poles of the electrode system and is formed of a material having an electrochromic or electrophoretic or electroluminescent or thermochromic visualization effect excited by voltage generated in contact of the electrode system with body fluid. Both the electrochemical cell and the indicator element are formed as printing layers on a carrier

-3GB 29964 Background UI. In a preferred embodiment, the sensor support substrate has a bottom portion provided with an adhesive layer for attachment to a dressing pad or bandage in the dressing cover. By placing the sensor in the dressing cover, the saturation of the formation of the exudate of the crow as well as the drainage function of the dressing cover as a whole can be easily detected. The humidity detection location can be easily changed. It is also possible to use several sensors and monitor humidity in several places. This will allow a better and better dressing based on the actual condition of the bandage.

The advantages of the sensor for detecting the degree of saturation of the dressing cover by body fluids according to this technical solution lie in particular in the independence of the function of the sensor on another external evaluation device. Furthermore, according to the technical solution, the sensor is cheap, effective and has universal use for various types of bandages, wound covers or bandages designed to detect their degree of saturation with body fluids.

Explanation of drawings

The mentioned technical solution will be explained in more detail in the following figures, where:

Fig. 1 shows a view of a sensor with a directly connected indicating element to the electrode system, each transparent conductive electrode consisting of a reference and visualization part, Fig. 2 shows a view of a sensor with a directly connected indicating element to the electrode system, one transparent conductive electrode of which is the reference part of the indicating element and the second transparent conductive electrode is a visualizing part of the indicating element, Fig. 3 shows a view of a sensor with an indirectly connected indicating element to the electrode system by wires, consisting of only one transparent conductive electrode representing the visualizing part and the reference part not Fig. 4 shows a view of a sensor with a directly connected indicating element to the electrode system, where the indicating element consists of only one transparent conductive electrode, which forms a visualization part, Fig. 5 shows a view of a bandage with a built-in sensor, which is Fig. 6 shows a view of a dressing pad with a built-in sensor, which is permanently attached to a dressing pad by means of an adhesive layer, Fig. 7 shows a partial section of a dressing cover with a built-in sensor arranged on a patient's hand.

Example of implementing a technical solution

It is to be understood that the specific embodiments of the technical solution described and illustrated below are presented for illustration, not as a limitation of the technical solution to the examples given. Those skilled in the art will find, or be able to ascertain using routine experimentation, more or less equivalents to the specific embodiments described herein. These equivalents will also be included in the scope of the following protection claims.

Example 1

Polyethylene terephthalate film - PET was used for printing, the surface of which was treated to increase the free surface energy. Using a screen printing machine, a collector system for better conductivity of selected layers of sensor 1 was printed using a printing formulation containing silver particles, which showed a sheet resistance in the order of 100 mOhm / square. Subsequently, a layer of a carbon composite printing formulation was printed on the collector system. Using a printing formulation containing carbon nanostructures and Ag ₂ O, cathode 4 was printed, which showed a sheet resistance in the order of 10 ² to 10 ⁴ Ohm / square depending on the printing conditions. Using a printing formulation containing carbon nanostructures and Zn particles, anode 3 was printed, which showed a sheet resistance

-4GB 29964 UI in the order of 10 ² to 10 ³ Ohm / square depending on printing conditions. Subsequently, transparent conductive electrodes based on poly (3,4-ethylenedioxythiophene) polystyrene sulfonate or PEDOT: PSS were printed by flexographic printing, which were locally overprinted with a WO3-based formulation. The active part of the electrochemical cell was overprinted with a KC1-based electrolyte. The entire electrochromic part was overprinted with a UV-cured topcoat. The sensor 1 prepared in this way showed a significant change in color / contrast in the visualization part 8 of the indicator element 6 from a faint green color to a dark blue color in the presence of physiological saline, glucose or exudate.

Example 2

Polycarbonate foil - PC was used for printing, the surface of which was treated to increase the free surface energy. Using a screen printing machine, a collector system from a carbon composite printing formulation was printed on a given support substrate 5 for better conductivity of selected sensor layers 1 having a sheet resistance in the order of 10 ¹ to 10 ² Ohm / square. Using a printing formulation containing carbon nanostructures and MnO ₂ , cathode 4 was printed, which showed a sheet resistance in the order of 10 ² to 10 ³ Ohm / square depending on the printing conditions. Using a printing formulation containing carbon nanostructures and Zn particles, anode 3 was printed, which showed a sheet resistance in the order of 10 ² to 10 ³ Ohm / square depending on the printing conditions. Subsequently, transparent conductive electrodes based on an antimony doped tin oxide dispersion were printed by flexographic printing, which were locally overprinted with a WO3-based formulation. The active part of the electrochemical cell was overprinted with an electrolyte based on ionic liquid, where the layer was gelled by heat treatment. The entire electrochromic part was overprinted with a UV-cured topcoat. The sensor 1 prepared in this way showed a significant change in color / contrast in the visualization part 8 of the display element 6 from yellow to dark blue in the presence of physiological saline, glucose or exudate.

Example 3

PET film was used for printing, the surface of which was treated to increase the free surface energy. Using a screen printing machine, a collector system for better conductivity of selected layers of sensor 1 was printed using a printing formulation containing silver particles, which showed a sheet resistance in the order of 10 ¹ to 10 ² mOhm / square. Subsequently, a layer of a graphite-based carbon composite print formulation was printed on the collector system. Using a printing formulation containing carbon nanostructures and MnO ₂ , cathode 4 was printed, which showed a sheet resistance in the order of 10 ² to 10 ⁴ Ohm / square depending on the printing conditions. Using a printing formulation containing graphite and Mg particles, anode 3 was printed, which showed a sheet resistance in the order of 10 ² to 10 ³ Ohm / square depending on the printing conditions. Subsequently, transparent conductive electrodes based on PEDOT: PSS were printed by flexographic printing, which were locally overprinted with a formulation based on a polyaniline dispersion. The active part of the electrochemical cell was overprinted with an electrolyte based on H3PO4, which after drying formed a gel electrolyte. The entire electrochromic part was overprinted with a UV-cured topcoat. The sensor 1 prepared in this way showed a significant change in color / contrast in the presence of physiological saline, glucose or exudate in the visualization part 8 of the indicator element 6 from a faint green color to purple.

Example 4

A nonwoven fabric was used for printing, the surface of which was treated with a coating and subsequent calendering. Using a flexographic printing machine, a collector system from a printing formulation for better conductivity of selected layers of the sensor 1 containing silver particles was printed on a given support substrate 5, which showed a sheet resistance in the order of 500 mOhm / square. Subsequently, a carbon composite was printed having a sheet resistance in the order of 10 ³ to 10 ⁴ Ohm / square. Cathode 4 was printed using a printing formulation containing graphite and MnO _2. Anode 3 was printed using a printing formulation containing graphite and Zn particles. Subsequently, transparent conductive electrodes based on PEDOT: PSS dispersion were printed by flexographic printing, which were locally overprinted with a polyaniline-based formulation. hydrochloride PANLHCl. The active part of the electrochemical cell was overprinted with an electrolyte based on ionic liquid, where the layer was gelled by heat treatment.

-5CZ 29964 UI

The entire electrochromic part was overprinted with a UV-cured topcoat. The sensor 1 thus prepared showed a change in color / contrast in the visualization part 8 of the indicator element 6 from green to blue-violet in the presence of physiological saline, glucose or exudate.

Example 5

The sensor 1 was made according to Example 3, with the difference that a nonwoven fabric was used as the support substrate 5. Indicator element 6 was based on PEDOT: PSS and Prussian blue. A LIC104-based gel electrolyte was used as the electrolyte. The visualization part 8 of the indication element 6 showed a change in color / contrast of light blue to dark blue.

Example 6

The sensor 1 was manufactured according to Example 2, with the difference that PET film was used as the support substrate 5. The layers of sensor 1 were prepared by screen printing. Indicator element 6 was based on a transparent conductive layer of doped SnO ₂ and Prussian blue. A LIC104-based gel electrolyte was used as the electrolyte. The visualization part 8 of the indication element 6 showed a change in color / contrast of light yellow to dark blue.

Example 7

The sensor 1 was made according to Example 4, with the difference that PET film was used as the support substrate 5. Indicator element 6 was based on a transparent conductive layer of PEDOT: PSS and viologen. A gel electrolyte based on LiClO ₄ was used as the electrolyte. The visualization part 8 of the indication element 6 showed a change in color / contrast of light blue to dark purple.

Example 8

Self-adhesive polyvinyl chloride - PVC foil was used for printing, the surface of which was treated to increase the free surface energy. Using a screen printing machine, a collector layer from the print formulation was printed for better conductivity of selected layers of the carbon nanocomposite sensor 1. Cathode 4 was printed on it using a printing formulation containing carbon nanostructures and MnO ₂ , which showed a sheet resistance in the order of 10 ² to 10 ³ Ohm / square depending on the printing conditions. Using a printing formulation containing carbon nanostructures and Mg particles, anode 3 was printed, which showed a sheet resistance in the order of 10 ² to 10 ³ Ohm / square depending on the printing conditions. Subsequently, transparent conductive electrodes based on PEDOT: PSS were printed by flexographic printing, which were locally overprinted with a formulation based on Prussian blue. The active part of the electrochemical cell was overprinted with an electrolyte based on an ionic liquid, cured thermally or by radiation. The entire electrochromic part was overprinted with a UV-cured topcoat. The sensor 1 thus prepared showed, in the presence of physiological saline, glucose or exudate, a significant change in color / contrast in the visualization part 8 of the indicator element 6 from a faint color to dark blue.

Example 9

The sensor 1 was made according to Example 8, with the difference that a PET self-adhesive film was used as the support base 5. Indicator element 6 was based on a transparent conductive layer of ATO, i.e. on antimony doped tin oxide and viologen. A KC1-based gel electrolyte was used as the electrolyte. The visualization part 8 of the indication element 6 showed a change in color / contrast of light gray-green to purple.

Example 10

The sensor 1 was made according to Example 8, with the difference that a PET self-adhesive film was used as the support base 5. The indicator element 6 was based on a transparent WO ₃ , which was printed directly on the electrode system 2. A gel electrolyte based on LIC103 was used as the electrolyte. The visualization part 8 of the indication element 6 showed a change in color / contrast from light yellow to blue.

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Example 11

Self-adhesive PVC foil was used for printing, the surface of which was treated to increase the free surface energy. A layer of a carbon nanocomposite printing formulation was printed using a screen printing machine. Cathode 4 was printed on it using a printing formulation containing carbon nanostructures and MnO ₂ , which showed a sheet resistance in the order of 10 ² to 10 ³ Ohm / square depending on the printing conditions. Using a printing formulation containing carbon nanostructures and Zn particles, anode 3 was printed, which showed a sheet resistance in the order of 10 ² to 10 ³ Ohm / square depending on the printing conditions. Subsequently, transparent conductive electrodes based on PEDOT: PSS and Prussian blue were screen-printed. The active part of the electrochemical cell was overprinted with an electrolyte based on an ionic liquid, cured thermally or by radiation. The entire electrochromic part was overprinted with a UV-cured topcoat. The sensor thus prepared showed a significant change in color / contrast in the visualization part 8 of the indicator element 6 from a faint blue color to a dark blue one in the presence of physiological saline, glucose or exudate.

Industrial applicability

The sensor for detecting the degree of saturation of the wound cover by body fluids provides unique and advantageous properties from the point of view of detecting the state of wound healing, which is based on the possibility of monitoring the course of exudate formation. Exudate formation is a signal that can be used to monitor inflammatory activity at the wound site, but at the same time indicates the need for more frequent dressing changes.

Claims (14)

A sensor (1) for detecting the degree of saturation of a dressing cover (11) by body fluid comprising an electrochemical cell formed by an electrode assembly (2) consisting of two electrodes, an anode (3) and a cathode (4) and generating an electrical voltage upon contact with the body fluid, a flat support substrate (5) with a thickness of up to 1 mm, and an indication element (6) for visually indicating the degree of saturation of the dressing cover, each of the electrodes of the electrode system (2) being formed as at least one printing layer on the support substrate (5); in that the indicator element (6) is formed by at least one transparent conductive electrode formed as at least one printing layer on the support substrate (5), which is directly or indirectly connected to the poles of the electrode system (2) and is formed of a material having an electrochromic or electrophoretic or an electroluminescent or thermochromic visualization effect excited by a voltage generated in contact of the electrode assembly (2) with a body fluid. Sensor according to Claim 1, characterized in that the display element (6) is directly connected to the electrode system (2). Sensor according to Claim 1, characterized in that the display element (6) is indirectly connected to the electrode system (2) via conductors (12). Sensor according to one of Claims 1 to 3, characterized in that the display element (6) consists of a reference part (7) and a visualization part (8) for comparing visual perception based on a change in color intensity or brightness or contrast of the visualization part (8). indicator element (6). Sensor according to one of Claims 1 to 4, characterized in that the display element (6) is made of a material having an electrochromic visualization effect. Sensor according to Claim 5, characterized in that the electrochromic display element (6) consists of a material from the group: WO ₃ , V ₂ O ₅ , NiO ₂ , Prussian blue and its analogs or conductive polymers based on poly (3,4 -ethylenedioxythiophene), polypyrrole, polyaniline and their derivatives. -7 CZ 29964 UI Sensor according to one of Claims 1 to 6, characterized in that the electrode system (2) is formed by mutually compatible electrode materials of electrochemical cells of the type: Li / CuO, Li / LiFeS ₂ , Li / LiMnO ₂ , Li- (CF) _n , Zn / MnO ₂ , Zn / Ag ₂ O, Mg / MnO ₂ , Zn / HgO, Ni / Cd, Ni / Zn, Ag / Zn. Sensor according to one of Claims 1 to 7, characterized in that the support substrate (5) is a vapor-permeable film or a laminate thereof with a nonwoven fabric or a transparent film made of polycarbonate, polyvinyl chloride, polyethylene, polyethylene terephthalate or paper or ceramic material. Sensor according to one of Claims 1 to 8, characterized in that the surface of the support substrate (5) is modified to increase the free surface energy. Sensor according to one of Claims 1 to 9, characterized in that the printing layer of the electrode system (2) and / or the indicator element (6) is formed by printing techniques such as flexography, pad printing, screen printing, gravure printing, offset printing, injection printing, aerosol jet printing, spray application, slot-die or Mayer bar coating. A dressing tampon (9) or bandage (10) with at least one sensor (1) for detecting the degree of saturation of the dressing cover (11) with body fluid, characterized in that the sensor (1) comprises an electrochemical cell formed by an electrode assembly (2) consisting from the anode (3) and the cathode (4) and generating, after contact with the body fluid, an electrical voltage, a flat support substrate (5) up to 1 mm thick, and an indicator element (6) for visually indicating the degree of saturation of the dressing formed by at least one transparent conductive an electrode which is directly or indirectly connected to the poles of the electrode system (2) and is made of a material exhibiting an electrochromic or electrophoretic or electroluminescent or thermochromic visualization effect excited by voltage generated in contact of the electrode system (2) with body fluid, the electrochemical cell and indicator element (6) are formed as printing layers on a carrier substrate (5). A dressing pad or bandage according to claim 11, characterized in that the support substrate (5) of the sensor (1) has a lower part provided with an adhesive layer (13) for attachment to the dressing pad (9) or bandage (10). A dressing (11) with at least one built-in sensor (1) for detecting the degree of saturation of the dressing with body fluid, characterized in that it consists of a dressing tampon (9) and / or a bandage (10) with at least one sensor (1) , which comprises an electrochemical cell formed by an electrode assembly (2) consisting of an anode (3) and a cathode (4) and generating an electrical voltage upon contact with a body fluid, a flat support substrate (5) up to 1 mm thick, and an indicator element (6) for visual indication of the degree of saturation of the dressing cover formed by at least one transparent conductive electrode which is directly or indirectly connected to the poles of the electrode system (2) and is made of material exhibiting electrochromic or electrophoretic or electrochuminescent or thermochromic visualization effect excited by voltage generated in electrode system contact ( 2) with a body fluid, wherein the electrochemical cell and the indicator element (6) are formed as printing layers on a support substrate (5). The dressing cover (11) according to claim 13, characterized in that the support base (5) of the sensor (1) has a lower part provided with an adhesive layer (13) for attachment to a dressing pad (9) or a bandage (10).