ES2848748A1 - Sterilizable biocompatible sensor (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

The invention relates to a sterilizable biocompatible sensor that allows the monitoring of a wound at different points in order to detect any possible inflammation and/or infection. The sensor developed is made up of at least one pair of printed electrical tracks made up of polymeric inks with silver, a base substrate made of permeable, biocompatible, flexible and stretchable material in which the printed electrical tracks are arranged, leaving the end of the tracks printed electrics attached to at least one temperature sensor. In this way, the printed electrical tracks conduct the temperature measured by the sensor to a data logger for control. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

STERILIZABLE BIOCOMPATIBLE SENSOR

TECHNICAL SECTOR

The present invention relates to a sterilizable biocompatible sensor that has at least one temperature sensor associated with a pair of printed electrical tracks that conduct the measured temperature to a data logger.

Advantageously, the electrical tracks, made up of polymeric inks with silver, are arranged on a flexible and stretchable base substrate and a film of material of the same nature as the base substrate is placed on them, providing a foldable and stretchable extension of the tracks that it favors its adaptation to any wound to be controlled.

The object of the invention is to achieve a sterilizable biocompatible sensor that makes it possible to monitor the temperature at different points of a wound, so that the evolution of the wound and eventual infection are controlled very precisely.

BACKGROUND OF THE INVENTION

The temperature of a long-standing wound is a fundamental parameter to know its condition, as well as the appearance of possible infections. Therefore, it is convenient to know its value, since it is an objective tool on which to base the therapeutic action of health personnel.

Dressings incorporating instruments for measuring temperature are known. However, these known dressings limit therapeutic practice, since they have a predetermined geometry, which cannot be modified, and therefore, they are not adaptable to the particular characteristics of the wound, nor do they allow the temperature to be measured at different points in the wound.

Additionally, known dressings provided with measuring instruments of the temperature does not offer the sensitivity and accuracy required for wound monitoring.

It should also be noted that known dressings offer an unstable temperature measurement, since, due to their structural limitations, there is always a free space between the dressing and the ulcer, so the temperature measurement obtained is not accurate.

Another of the drawbacks associated with known dressings that incorporate single-use temperature measurement instruments, not being possible to reuse them and resulting in an expensive solution, as the temperature instrumentation is limited to a single use.

For all the above, the applicant of the present patent application detects the need to develop a sterilizable biocompatible sensor, which can be reused, and which is precisely adapted to the characteristics of the wound.

DESCRIPTION OF THE INVENTION

The biocompatible sterilizable sensor advocated in the present invention makes it possible to solve the aforementioned problems, offering a configuration of high adaptability to the shape and depth of the wound to be monitored.

In this way, the sensor of the invention makes it possible to monitor the evolution of the wound temperature in a stable and precise way, and additionally makes it possible to detect an infectious process, constituting an effective control tool.

The sterilizable biocompatible sensor of the invention is made up of at least two printed electrical tracks formed by polymeric inks with silver, where each printed electrical track has a rectilinear shape of uniform thickness.

The printed electrical tracks are arranged on one of the surfaces of a base substrate which is a permeable, biocompatible, flexible and stretchable material. While on the printed electrical tracks a film of permeable, biocompatible, flexible and stretchable material is arranged.

Specifically, the film superimposed on the printed electrical tracks and the base substrate is preferably less thick than the base substrate itself.

The sterilizable biocompatible sensor includes at least one temperature sensor which is attached to one end of a pair of printed electrical tracks. In the event that more than one point of a wound needs to be measured, the biocompatible sterilizable sensor of the invention will have as many temperature sensors as points to be measured.

As will be seen in detail in the preferred embodiment of the invention, in the case of including a plurality of temperature sensors, each one is attached to one end of the pair of printed electrical tracks while the other end of the printed electrical tracks is attached. to a data logger to allow the recording and monitoring of the temperature measurements collected by the temperature sensors.

In this way, each pair or pair of printed electrical tracks function as conductors to transmit the temperature measured by each temperature sensor to the data logger. The data logger can be any type of commercial logger.

Advantageously, the nature of the base substrate, the printed electrical tracks and the film arranged on them provides the adaptation of the set, since it allows the base and film substrates to be cut longitudinally, bordering the printed electrical tracks and adjusting to the areas to be measured according to the criteria. clinical indicated.

In fact, the possibility of cutting the base substrate and the film according to certain clinical requirements, allows to minimize the area in contact with the wound, that is, the risk of occlusion of the wound is minimized due to the minimum presence of points in contact with the same.

The sterilizable nature of all the elements that make up the biocompatible sterilizable sensor of the invention makes it possible to confirm that it is a device for more than one use, that is, it allows the elements to be subjected to sterilization cycles that allow their reuse.

Preferably, each temperature sensor is covered by a biocompatible material, such as PDMS (polydimethylsiloxane). The presence of a coating of a biocompatible material on each temperature sensor is highly recommended as it guarantees that the wound comes into direct contact with the biocompatible material that covers the temperature sensor, instead of directly on the material that makes up the sensor itself. Of temperature. Additionally, the presence of the biocompatible material coating provides airtightness to the temperature sensor, avoiding contact with possible exudate from the wound that could alter the measured temperature reading.

Optionally, and in order to perform a precision control of the temperature to be measured, the sterilizable biocompatible sensor includes temperature sensors with a sensitivity of between -3% per ° C and -5% per ° C, providing greater sensitivity than others. known.

On the other hand, it should be noted that the configuration of the sterilizable biocompatible sensor allows precise positioning on the wound, thus avoiding the formation of intermediate spaces between the temperature sensor and the wound that could affect the precision of the measurements. Of temperature. Therefore, the temperature reading measured by the sterilizable biocompatible sensor is reliable, obtaining values corresponding to the temperature of the skin surface.

Finally, we must emphasize that the biocompatible sterilizable sensor of the invention is not permanently associated with any type of dressing, thus allowing the clinician to select any type of auxiliary fixation means, as long as it does not damage the base substrate.

BRIEF DESCRIPTION OF THE DRAWINGS

To complement the description that is going to be made below and with the aim of helping a better understanding of the characteristics of the invention, according to a preferred example of a practical embodiment thereof, a set of drawings is attached as an integral part of said description. where, with an illustrative and non-limiting nature, the following has been represented:

Figure 1.- Shows a representation of the sterilizable biocompatible sensor made of according to a preferred embodiment of the object of the present invention.

Figure 2.- Shows a detailed view of the elements that make up the sterilizable biocompatible sensor represented in figure 1.

Figure 3.- Shows a representation of the biocompatible sensor made in accordance with the object of the present invention, including a light indicator.

Figure 4.- Shows a view of a practical application of the biocompatible sensor object of the invention located on a lower end.

PREFERRED EMBODIMENT OF THE INVENTION

In view of the figures outlined, and specifically in figure 1, we observe that the biocompatible sterilizable sensor object of the invention is integrated in a preferred embodiment by the following elements:

- A plurality of pairs or pairs of printed electrical tracks (1) which are arranged in parallel and integrated by polymeric inks with silver, where each printed electrical track (1) has a rectilinear shape of uniform thickness, - A base substrate (2) made of permeable, biocompatible, flexible and stretchable material, the printed electrical tracks (1) being arranged on one of the surfaces of the base substrate (2),

- A film of permeable, biocompatible, flexible and stretchable material, arranged on the printed electrical tracks (1),

- As many temperature sensors (3) as pairs of printed electrical tracks (1) include the biocompatible sterilizable sensor. Thus, each temperature sensor (4) is attached to the end of a pair of printed electrical tracks (1), which are located adjacent and parallel.

Necessarily, the sterilizable biocompatible sensor has as many temperature sensors (3) as there are specific points or areas to be monitored of a wound.

Each temperature sensor (3) is attached to one end of the two electrical tracks printed (1) while the other end of said printed electrical tracks (1) is linked to a data logger (4).

Advantageously, the data logger allows the recording of the temperature measurements collected by the temperature sensors (4) and, therefore, the monitoring of the condition of the wound.

As shown in figure 2, the base substrate (2) has an area such that it allows the arrangement of the printed electrical tracks (1) of a continuous rectilinear configuration and uniform thickness.

The base substrate (2) has a thickness, preferably, between 40 and 60 microns. On the base substrate (2) the printed electrical tracks (1) are arranged and on them - although it is not shown in figure 2 - the film that has a thickness, preferably, is arranged overlapping with the base substrate (2) between 20 and 30 microns.

In this way, the result is a biocompatible sensor made up of printed electrical tracks (1) that act as conductors of the measured temperature signal, where the presence of the permeable material film arranged on them offers a completely smooth finish. That is, the sterilizable biocompatible sensor offers a non-traumatic medium which does not generate pressure injury when placed on fragile skin surfaces, since the configuration of the printed electrical tracks (1) and the temperature sensors (3) do not present edges. high or sharp.

On the other hand, it should be noted that since the electrical tracks (1) are printed using polymeric inks with silver, a surface bonding of the mentioned printed electrical tracks (1) is generated on the base substrate (2).

Advantageously, the material nature of the base substrate (2), of the printed electrical tracks (1) and of the film superimposed on them, gives a maximum elongation capacity of the aforementioned set of 10% of its length. This property favors the application of the sterilizable biocompatible sensor on large wounds.

Figure 3 shows the sterilizable biocompatible sensor which includes an optional element that corresponds to a light indicator (5). Advantageously, the light indicator (5) alerts the correct operation of the sterilizable biocompatible sensor in a visual way, being a very agile checking means for the user.

Similarly, figure 3 shows in a clearly differentiated way that the length of each pair of printed electrical tracks (1) can even have different lengths. Specifically, figure 3 represents the electrical tracks on the base substrate (2), where the base substrate (2) has already been cut, bordering the printed electrical tracks (1).

Taking into account that the printed electrical tracks (1) are arranged between flexible and stretchable materials (the base substrate (2) and the film), these can take different forms, allowing the user of the sterilizable biocompatible sensor of the present invention to modify the position of the temperature sensors (3) located at one of the ends of the printed electrical tracks (1) with great ease.

Due to all of the above, one of the notable advantages of the sterilizable biocompatible sensor of the invention resides in the configuration of the printed electrical tracks (1) that comprise it, which present a foldable and stretchable extension that favors its adaptation to the desired shape for the monitoring of a wound or ulcer, regardless of the shape and depth of the aforementioned injury.

Preferably, the permeable, biocompatible, flexible and stretchable material that integrates both the base substrate (2) and the film is polyurethane, allowing a high degree of flexibility and stretching that provides additional protection to shear, friction and compression mechanisms to which they can be subdued.

In a second preferred embodiment of the invention, the permeable, biocompatible, flexible and stretchable material that integrates both the base substrate (2) and the film is a textile.

Finally, figure 4 shows a practical application of the biocompatible sensor of the invention on a wound that we assume is located in a leg. Thus, in the figure outlined four temperature sensors (3) are observed that are arranged in different points of leg extension. Each temperature sensor (3) is linked to a pair of printed electrical tracks (1) that conduct the temperature signal collected by the temperature sensor (3) to the data logger (4).

Claims (8)

1§.- Biocompatible sterilizable sensor for temperature measurement at different points of a wound comprising: - At least one pair of printed electrical tracks (1) made up of polymeric inks with silver, where each printed electrical track (1) has a rectilinear shape of uniform thickness, - A base substrate (2) of permeable, biocompatible, flexible and stretchable material, the printed electrical tracks (1) being arranged on one of its surfaces, - A film of permeable, biocompatible, flexible and stretchable material, arranged on the printed electrical tracks (1), - At least one temperature sensor (3) which is attached to one end of a pair of printed electrical tracks (1), characterized by what the sterilizable biocompatible sensor has as many temperature sensors (3) as points to be measured in the wound, each temperature sensor (3) being attached to one end of the pair of printed electrical tracks (1) while the other end of the electrical tracks printed matter (1) is linked to a data logger (4) for recording the temperature measurements collected by the temperature sensors (4). 2§.- Biocompatible sterilizable sensor, according to claim 1§, characterized in that the base substrate (2) and the film are made of polyurethane. 3§.- Biocompatible sterilizable sensor, according to claim 1§, characterized in that the base substrate (2) and the film are integrated by a textile. 4.- Sterilizable biocompatible sensor, according to claim 1§ or any of the preceding claims, characterized in that the base substrate (2) has a thickness between 40 and 60 microns. 5§.- Biocompatible sterilizable sensor, according to claim 1§, characterized in that the film has a thickness between 20 and 30 microns. 6.- Sterilizable biocompatible sensor, according to claim 1§ or any of the preceding claims, characterized in that the base substrate (2), the film and / or the printed electrical tracks (1) have a maximum elongation capacity of 10 % of its length. 7§.- Sterilizable biocompatible sensor, according to claim 1§, characterized in that each temperature sensor (3) is covered by a biocompatible material. 8§.- Biocompatible sterilizable sensor, according to claim 1§ or 7§, characterized in that the temperature sensor (3) has a sensitivity of between -3% per ° C and -5% per ° C.