FR3001376A1 - Sensor for incorporation of intraocular pressure in flexible contact lens, has external capacitor including two electrodes separated by dielectric medium, where gap between electrodes varies according to intraocular pressure - Google Patents

Abstract

The sensor (200) has an inductor (201) of spiral shape arranged on a plane of the sensor. An external capacitor (215) includes two electrodes (215a, 215b) separated by a dielectric medium arranged on an outer periphery of the inductor. The electrodes of the external capacitor are arranged such that a gap between the electrodes varies according to the intraocular pressure. An internal capacitor (211) includes two electrodes (211a, 211b) separated by a dielectric medium arranged on an inner periphery of the inductor. An independent claim is also included for a flexible contact lens.

Description

The invention relates to the field of passive sensors, in particular intended to measure a physiological parameter such as intraocular pressure. The invention relates in particular to a flexible passive sensor for a contact lens.

Intraocular pressure is one of the physiological parameters for diagnosing certain diseases such as glaucoma. Ambulatory and non-invasive sensors have been developed to measure changes in intraocular pressure in a patient during his daily course. The development of non-invasive sensors allows more and more frequently on the one hand to overcome the invasive methods involving surgical procedures on the patient's eye. On the other hand, the fact of associating these sensors with ambulatory systems also avoids immobilization of the patient and allows an uninterrupted effective follow-up of the evolution of the intraocular pressure or of any other physiological parameter in real life situations. of the patient.

A passive sensor, that is to say not requiring any significant source of energy to operate, realized by means of an electric circuit LC, integrated in a soft contact lens and intended for the monitoring of the Intraocular pressure is known from EP 2 412 305 A1. A variation of the intraocular pressure causes a change in the resonance frequency of the LC circuit which can be detected and thus related to this variation. In particular, the application EP 2 412 305 A1 discloses a sensor comprising a capacitor and an inductance composed of first turns arranged on a first main face of a carrier substrate and second turns arranged on a second main face of the carrier substrate, opposite to the first main face. The document EP 2 412 305 A1 also discloses that the carrier substrate can be removed at least partially from the non-turn and / or capacitor regions, that the two sets of turns can intersect and be interconnected by conductive vias, as well as the capacitor can be formed integrally with the inductor so that its two electrodes are each arranged on one of the two opposite faces of the carrier substrate.

Some practical problems and unexpected constraints appeared during the manufacture of sensors and lenses as disclosed in EP 2 412 305 A1, in particular during the molding and then the use of the lenses.

A disadvantage observed in known state of the art sensors is a significant decrease in the sensitivity of the sensor, especially at the edge of the contact lenses. Other disadvantages have also been observed, in particular at the capacitor (s) of the LC circuit realized by the passive sensors known from the state of the art. The sensors known from the state of the art, such as for example EP 2 412 305 A1, use capacitors arranged on the outer periphery of an essentially circular and spiral inductance. When bending a capacitor having its electrodes on either side of the support substrate, in other words on two parallel planes tangent to the eye once the sensor is molded in the lens, misalignment can occur between the electrodes of said capacitor , then drives an undesired shift of the LC properties of the circuit, in particular of the resonant frequency of the circuit, the negative effect of which is particularly important at the edge of the lens. The present invention therefore aims to solve or prevent the disadvantages described above noted during the manufacture of passive sensors, their subsequent molding in contact lenses, and when wearing lenses equipped with such sensors by a subject of which a physiological parameter such as the intraocular pressure must be followed. An object of the present invention is achieved by an intraocular pressure sensor for incorporation into a contact lens according to an aspect of the present invention, the sensor comprising a substantially spiral geometry inductance arranged substantially on a first plane of the sensor, at least one external capacitor, with a first electrode and a second electrode separated by a dielectric medium, arranged on an outer periphery of the inductor. According to this aspect of the present invention, the sensor is characterized in that the first and second electrodes of the at least one external capacitor are arranged such that the gap between the electrodes varies as a function of the intraocular pressure. For the measurement of a physiological parameter such as the intraocular pressure, it is advantageous to work with an LC electrical circuit whose resonance frequency is situated in a frequency range adapted to medical applications on the one hand, and whose frequency of The resonance varies according to the variations of the physiological parameter while remaining in the right frequency range on the other hand, without the capacitive value of the capacitor (s) changing in an uncontrolled manner, in particular without the electrodes being misaligned in one direction. perpendicular to the plane of the sensor. The known sensors of the state of the art comprise at least one capacitor arranged on a circumference of the sensor outside the largest radius of the inductance, the electrodes of which are arranged in two planes juxtaposed in the direction of the thickness of the contact lens and therefore parallel to the surface of and thus have the problem that the bending of the sensor during incorporation into a contact lens causes an inappropriate misalignment of the electrodes of the capacitors, making the sensor less sensitive than expected by the theory to changes in intraocular pressure and therefore unreliable in practice. To solve this problem, this aspect of the invention makes it possible to use at least one capacitor located on a radius greater than the largest radius of the spiral inductance, so that this at least one external capacitor is in the more curved region of the lens and therefore more sensitive to changes in intraocular pressure. According to the invention, the two electrodes of the at least one capacitor are then arranged in such a way that the gap between these two electrodes varies according to the intraocular pressure but that these electrodes do not undergo any undesired misalignment which could for example to shift the resonant frequency outside the working frequency range. Advantageously, the sensor may further comprise an internal capacitor, with a first electrode and a second electrode separated by a dielectric medium, arranged on an inner periphery of the inductor and whose capacitive value is such that the resonance frequency of the sensor is less than 30 MHz. The advantage of using another capacitor arranged on an inner circumference of the spiral formed by the inductance of the sensor is that after molding, this other capacitor is in an area near the center of the lens, thus having less curvature than the areas bordering the contact lens. Thus this other capacitor is less sensitive to variations in intraocular pressure than a capacitor at the edge of the lens. The capacitive value of the first capacitor is therefore chosen so as to place the resonance frequency within the allowed frequency range for medical applications, in this case less than 30 MHz.

Advantageously, the first electrode of the internal capacitor may be arranged on a plane parallel to the first plane of the sensor, preferably the first plane of the sensor, and the second electrode of the first capacitor may be arranged on a second plane of the sensor, preferably different from the foreground. Since the internal capacitor is arranged in an area of the sensor which will be slightly curved when incorporated in a contact lens, it is possible to use a sensor whose electrodes are on parallel planes in the direction of the contact lens. thickness of the sensor, and therefore of the lens, without the electrodes suffering from undesired misalignment during the molding and bending of the sensor in the lens. When the sensor is molded in a contact lens, the first and second planes of the sensor are then parallel to each other in the direction of the thickness of the lens and are tangent to the eye of the subject. It is advantageous, but not essential, for the manufacture of the sensor that one of the electrodes of the internal capacitor is arranged on the same plane as the inductor. Advantageously, the first electrode and the second electrode of the at least one external capacitor may be arranged on the same plane parallel to the first plane of the sensor, preferably in the first plane of the sensor. According to the invention, the at least one external capacitor is arranged in the most curved region of the sensor once incorporated in the lens and the most sensitive to changes in intraocular pressure. A geometry in which the two electrodes of the at least one external capacitor are initially on the same plane parallel to the plane of the inductor, preferably in terms of inductance to facilitate the manufacture of the sensor, and on circumferences successive outside the last turn of the inductor, is therefore advantageous. In addition, this geometry is always compatible with the advantage of the invention that undesired misalignments between the electrodes of the month an external capacitor are avoided, even if this capacitor is arranged at the edge of the lens and therefore undergoes a greater curvature than the internal capacitor when incorporated in the contact lens. Thus, once the sensor is incorporated in the contact lens, the gap between the electrodes of the at least one external capacitor will vary essentially as a function of the intraocular pressure.

Advantageously, the at least one external capacitor and / or the internal capacitor may be of substantially arcuate geometry, in particular according to the geometry of the inductor. It is advantageous for the flexibility of the sensor to use elements having similar geometries. Thus, capacitors whose electrodes have arcuate shapes that follow at least partially the geometry of the inductor, will allow greater flexibility when incorporating the contact lens than more conventional capacitors known in the state of the art. . In a variant of an embodiment of the present invention, the first electrode and the second electrode of the at least one external capacitor may each comprise a plurality of electrode segments, preferably each four electrode segments, in each case. wherein the electrode segments of the first electrode are interdigitated with the electrode segments of the second electrode. The gap between the electrodes of the at least one external capacitor varying according to the intraocular pressure once the sensor is incorporated in the lens and in place on the eye of a subject, the use of segments of Electrodes interdigitated with each other improves the sensitivity of the sensor compared to the case of two single electrodes. In a variant of the embodiment in which the electrodes of the at least one external capacitor are interdigitated, at least one of the electrode segments of the first electrode and at least one of the electrode segments of the second electrode of the at least one external capacitor may be in the form of interdigitated combs with each other. All segments or only a few selected segments of the first and second electrodes of the at least one external capacitor can thus be made even more sensitive to changes in intraocular pressure.

In one embodiment of the present invention, the inductor may comprise a first turn starting from the outer periphery portion of the inductor and rotating in a first spiral direction towards the inner periphery of the inductor, and a second extending coil. the first turn following the same spiral orientation from the inner periphery of the inductor to the outer periphery of the inductor, the first turn and the second turn intersecting in crossing areas, and the ends of the first turn and the second turn arranged on the outermost part of the inductor then forming the terminals of the inductor. Thus the turns forming the inductor are substantially arcuate. An inductance of the sensor according to the invention composed of intersecting turns according to this geometry and whose terminals start on the outermost circumference of the spiral has the advantage that a significant decrease in significant potential is observed in the region. sensor edge, which allows on the one hand to optimize the sensitivity of the sensor in this desired region, namely at the edge of the sensor and therefore once in place on the eye of a subject, in a region of the eye for which the lens will be sufficiently subject to changes in intraocular pressure to allow effective detection of variations in the physiological parameter. On the other hand, this geometry advantageously makes it possible to confine the electric field lines in the zone occupied by the lens, thus avoiding short circuits by the ocular fluids.

The first turn and the second turn can intersect in at least two, preferably only two crossing areas. The inductance of the sensor according to the invention is essentially flat, except for the crossing zones which necessarily have an extra thickness in the plane of the sensor. It is therefore advantageous to limit the crossings of the turns along sensor radii, preferably only two radii, so as not to obtain too many zones of excess thickness and thus to limit the more rigid zones of the sensor at the moment of incorporation into the sensor. a lens. The first turn and the second turn can intersect using conductive vias arranged in the crossing zones. The use of conductive vias makes it possible to arrange the crossings between the turns of the inductor. It is therefore preferable to limit the places where the vias are arranged to only crossover zones in order to leave enough flexibility for the sensor for molding in a lens. Similarly, the electrical connections between the at least one external capacitor and / or the internal capacitor and the terminals of the inductor can be achieved by means of conductive vias. The use of vias is not limited to crossings between the turns, but is also advantageous for making the various electrical connections between the sensor elements according to the invention. The first turn and / or the second turn may be formed at least partially of a succession of segments connected by the conductive vias. During the manufacture of the sensor, it is advantageous to have at least one inductor comprising at least one segmented turn to facilitate the manufacture and arrangement of crossings between the two turns. It is also possible that the two turns are segmented. The conductive vias may be connected by conductive traces preferably arranged on at least one plane different from the first plane of the sensor, which may be in particular the second plane of the sensor, and the conductive traces may preferably be separated from the first turn and and / or the second turn and / or the first and second electrodes of the at least one external capacitor and / or the first electrode of the internal capacitor and / or the second electrode of the internal capacitor by a dielectric medium. It is therefore possible to make electrical connections between sensor elements arranged on an external circumference of the inductor, such as the terminals of said inductor and / or the at least one external capacitor, and sensor elements arranged on a circumference. internal inductance, for example the internal capacitor.

A variant of the sensor according to the invention may further comprise at least one stiffening element for the at least one external capacitor. Once the molding in a contact lens is made, the presence of at least one blocker acting as a stiffening element at the level of the at least one external capacitor makes it possible to further improve the sensitivity of the sensor at the edge of the contact lens by further avoiding undesirable misalignments between the electrodes of the at least one external capacitor. It is then advantageous to arrange the stiffening element on the same plane as the first electrode and the second electrode of the at least one external capacitor, which makes it possible to further control the direction of movement of the electrodes of the at least one external capacitor as a function of intraocular pressure variation. The stiffening element may comprise a metallic material and / or a dielectric material, which may be chosen preferably depending on the desired mechanical properties and level of rigidity. The objective is also achieved by a contact lens, in particular a soft contact lens, comprising a sensor according to the aspect described above or one of its variants or a combination thereof, in which the sensor is molded. inside the lens. A contact lens according to the invention will therefore be more sensitive to changes in intraocular pressure, particularly in areas close to its edge, than lenses known from the state of the art because it combines the use of at least one external capacitor and, if necessary, an internal capacitor making it possible to place the resonant frequency of the sensor in the right frequency range on the one hand, and to follow intraocular pressure variations while remaining in this frequency range on the other hand go. When molding with the lens, the inductor can be bent perpendicular to the first plane of the sensor, which is the plane on which the sensor has been made, following the curvature of the lens. The arrangement of the capacitors of the sensor according to the invention makes it possible to avoid undesired misalignments between the electrodes of said capacitors during the incorporation of the sensor in a contact lens. Various aspects to better understand the present invention and the advantages described above will be detailed in the following, in particular using advantageous embodiments illustrated by means of the accompanying figures, in which: Figure 1 schematically illustrates a example of an embodiment of a sensor combining several advantageous aspects of the invention; Figure 2 illustrates a detail of the sensor shown in Figure 1; and Figure 3 illustrates another detail of the sensor shown in Figure 1. Figures 1 to 3 schematically show a sensor 200 for measuring a physiological parameter such as intraocular pressure according to an embodiment of the present invention. Figure 1 shows the sensor 200 in a three-dimensional view from above, and Figures 2 and 3 show details of the sensor 200, again in three-dimensional views. In addition, the sensor 200 illustrated in Figures 1 to 3 is shown flat, that is to say in its state before molding in a contact lens and bending according to the spherical cap geometry of the contact lens.

According to an advantageous variant of the invention, the sensor 200 represented in FIG. 1 comprises an inductor 201 with a first turn 202 starting from the outermost part of the inductor 201 and rotating in a first direction spiral towards the innermost part of the inductor 201, or more generally towards the center 210 of the sensor 200. The first turn 202 is extended by a second turn 203 which rotates in the same spiral direction, but from within the sensor 200 to the outermost part of the inductor 201, by crossing the first turn 202. The ends of the turns 202, 203 on the outer periphery of the inductor 201 form the two terminals or terminals 206a, 206b of inductance 201. According to an advantageous variant of the invention, the turns 202, 203 are both arranged on the same first plane of the sensor 200. In this embodiment, the turns 202, 203 intersect with each other. less in These two crossing zones 209a, 209e, but other embodiments of the invention could have more crossing zones for the turns 202, 203 of the inductor 201. This geometry of interlacing of the turns 202, 203 with the terminals 206a, 206b of the inductor 201 on the outermost part of the sensor 200 allows a significant potential drop in the region bordering the sensor 200 and optimizes the sensitivity of the sensor 200 in this region. At the same time, the electric field lines remain substantially confined in the molded lens, so that a short circuit by the ocular fluids of the patient is avoided. According to another advantageous variant of the invention, which can be combined with that described above, the sensor 200 further comprises a capacitor 211 with a first electrode 211a and a second electrode 211b. As illustrated in FIG. 1, the capacitor 211 of this embodiment is arranged in the innermost part of the sensor 200, in particular closer to the geometric center 210 of the sensor 200 relative to the most The capacitor 211 is thus an "internal" capacitor of the sensor 200. The first electrode 211a is arranged on a first plane, which may be the first plane of the sensor 200 and thus the plane of the turns 202. 203 of the inductor 201, while the second electrode 211b is arranged on a second plane, different from the plane on which is arranged the first electrode 211a, and which may be a second plane of the sensor. The main role of the internal capacitor 211 is to shift the resonance frequency of the LC circuit realized by the sensor 200 in an authorized frequency band and practical for monitoring changes in the intraocular pressure. The capacitive value of the internal capacitor 211 can therefore be chosen such that the resonance frequency of the LC circuit of the sensor 200 is less than 30 MHz. The advantage of arranging the internal capacitor 211 in the inner part of the sensor 200 is that during molding with the lens, the electrodes 211a, 211b will be only slightly deformed and will hardly change the resonance frequency. of the LC circuit relative to the initial frequency, thus making it possible to follow the evolution of the physiological parameter. As shown in the detailed views of Figures 2 and 3, the turns 202, 203 intersect by means of a plurality of conductive vias 2071a, 2072a, ..., 207 (2n) a and 2071e, 2072e,. .., 207 (2m) e, n and m being integers, interconnected by conductive traces 2081a, 2082a, ..., 208 (n) a and 2081e, 2082e, ..., 208 (m) e arranged on a second plane of the sensor, which is a plane parallel to the first plane of the sensor 200 on which are arranged the turns 202, 203. Preferably, the second plane corresponding to the plane of the conductive traces 2081a, 2082a, ..., 208 (n) a and 2081e, 2082e, ..., 208 (m) e may be the same plane on which is arranged the second electrode 211b of the internal capacitor 211. Figure 2 illustrates a three-dimensional view of the top of the sensor 200 around the crossing zone 209e, while Figure 3 illustrates a three-dimensional view of the underside around the crossing zone 209a, showing in particular also the condensate 211. Each of the crossing zones 209a, 209e comprises a plurality of crossings 2091a, 2092a, ..., 209 (n) a and 2091e, 2092e, ..., 209 (m) e between the first turn 202 and the second turn 203 of the inductor 201. It is illustrated in particular in Figures 1 to 3, according to a variant of the invention, that one of the two turns 202, 203, here the turn 203, is composed of a series of segments 2031a, 2032a, ..., 203 (m) a and 2031b, 2032b, ..., 203 (n) b, interconnected by conductive vias 2071a, 2072a, ..., 2070a and 2071e, 2072e , ..., 207 (2m) e and by the conductive traces 2081a, 2082a, ..., 208 (n) a and 2081e, 2082e, ..., 208 (m) e arranged in the crossing zones 209a, 209e parallel to the respective crossings 2091a, 2092a, ..., 209 (n) a and 2091e, 2092e, ..., 209 (m) e between the first turn 202 and the second turn 203. In other embodiments , the turn 202 could be composed of such a succession of segments instead of the turn 203, and in e yet other embodiments the two turns 202, 203 could be composed of such segments. For the embodiment illustrated in FIGS. 1 to 3, the integers n and m therefore correspond to the number of segments 2031a, 2032a, ..., 203 (m) a and 2031b, 2032b, ..., 203 (n) b of the turn 203 on each side of the crossing zones 209a, 209e. In the particular case of FIGS. 1 to 3, n = 8 and m = 9, so that each of the crossing zones 209a, 209e comprises respectively n = 8 or m = 9 crossings 2091a, 2092a, ..., 209 (n ) a and 2091e, 2092e, ..., 209 (m) e and conductive traces 2081a, 2082a, ..., 208 (n) a and 2081e, 2082e, ..., 208 (m) e, respectively connected to means of 2n = 16 or 2m = 18 conductive vias 2071a, 2072a, ..., 2070a and 2071e, 2072e, ..., 207 (2m) e. However, it is obvious to those skilled in the art that the integers n and m may vary in other embodiments of the invention, depending on the number of turns of the spiral geometry of the inductor 201 and the chosen location. in the geometry of the inductor 201 to start the second turn 203 relative to the first turn 202.

FIG. 3 illustrates in particular an advantageous variant of the invention according to which the two electrodes 211a, 211b of the internal capacitor 211 are connected to the two terminals 206a, 206 on the outer edge of the inductor 201 by means of other conductive vias 212a, 212b, 212c and other conductive traces 213a, 213b arranged on the same plane, which may preferably be the second plane of the sensor, in particular the same plane as that of the conductive traces 2081a, 2082a, ..., 208 (n a and / or 2081e, 2082e, ..., 208 (m) e and / or the second electrode 211b of the internal capacitor 211. According to the invention and as illustrated in FIGS. 1 and 3, the sensor 200 comprises at least one capacitor 215 arranged in the outermost part of the sensor 200, that is to say on the outer periphery of the inductor 201, and which is therefore an "external" capacitor of the sensor 200 In other embodiments of this aspect of the invention, a sensor 200 could include additional external capacitors. According to a variant of the invention, advantageous during bending of the sensor 200 molded in a lens, the electrodes 215a, 215b are situated on the same plane in order to avoid excessive deformation of the external capacitor 215, which could modify the frequency circuit resonance in an undesired manner. It is advantageous to arrange additional capacitors 215 on external regions of the sensor 200 to increase its sensitivity. The internal capacitor 211 arranged towards the most central portion of the sensor 200 has the role of shifting the resonance towards the desired frequency range, preferably less than 30 MHz, while the external capacitor or capacitors 215 on the outer periphery of the sensor 200 , increase the sensitivity of the sensor 200. As illustrated in the views of Figures 1 and 3, the at least one external capacitor 215 is arranged on the same plane, in other words the first electrode 215a and the second electrode 215b of the less an external capacitor 215 are arranged on the same plane, which can advantageously and preferably correspond to the first plane of the sensor 200 on which are arranged the inductance 201 and / or possibly also the first electrode 211a of the internal capacitor 211. FIG. 3 also illustrates that the electrical connections between the internal capacitor 211, in particular the first electrode 211a, the inductor 201, in particular the Terminal 206a, and the at least one external capacitor 215, in particular its second electrode 215b, are made by means of conductive vias 212a, 212c, 214a, 214b, 214c, 214d interconnected by the conductive trace 213b. Likewise, the electrical connections between the internal capacitor 211, in particular the second electrode 211b and the inductor 201, in particular the second terminal 206b, are produced by means of the conductive via 212b and the conductive trace 213a, which in this mode of embodiment is an extension of the second electrode 211b of the internal capacitor 211. According to an advantageous embodiment, it is possible to manufacture the first electrode 215a of the at least one external capacitor 215 in an extension of one of the terminals 206a, 206b of the inductor 201. Thus, in the case illustrated in FIG. 3, the first electrode 215a of the at least one external capacitor 215 is connected to the second electrode 211b of the internal capacitor 211 at the second terminal 206b of the inductance, by means of the conductive trace 213a and the conductive via 212b. With the geometry thus described, the electrical connections between the inductor 201, the internal capacitor 211 and the at least one external capacitor 215 are essentially arranged in the same plane, the plane of the conductive traces 213a, 213b, which can advantageously be the second plane of the sensor 200, and thus the plane of the second electrode 211b of the internal capacitor 211, and that of the conductive traces 2081a, 2082a, ..., 208 (n) a connecting the segments 2031a, 2032a, ..., 203 (m) a, 2031e, 2032e, ..., 203 (m) e of the second turn 203.

Still according to an advantageous variant of the invention, it is also advantageous to use elements of the internal capacitor 211 and / or elements of the external capacitor 215 which are essentially arcuate, in particular for the case of the at least one second capacitor whose electrodes 215a, 215b are arranged on the same plane in order to avoid again too many misalignments due to the curvature during molding with a lens. Figures 1 to 3 illustrate an exemplary embodiment of this variant of the invention in which the internal capacitor 211 and the at least one external capacitor 215 are both substantially arcuate geometry according to the geometry of the inductor 201.

According to an advantageous variant of an aspect of the invention, illustrated in FIGS. 1 to 3, the electrodes 215a, 215b of the external capacitor 215 may each comprise a plurality of respective electrode segments 2151a, 2152a, 2153a, 2154a and 2151b, 2152b, 2153b, 2154b. In the particular but not limiting case of this aspect of the invention, illustrated in FIGS. 1 to 3, each electrode 215a, 215b comprises respectively four electrode segments 2151a, 2152a, 2153a, 2154a and 2151b, 2152b, 2153b, 2154b . In addition, according to a preferred variant of an embodiment of this aspect of the invention, the electrode segments 2151a, 2152a, 2153a, 2154a of the first electrode 215a are interdigitated with the electrode segments 2151b, 2152b, 2153b, 2154b of the second electrode 215b. In the particular but not limiting case of this aspect of the invention, on one side of the crossing zones 209a, 209e, the electrode segments 2151a, 2152a of the first electrode 215a are interdigitated with the electrode segments 2151b , 2152b of the second electrode 215b, and on the other side of the crossing zones 209a, 209e, the electrode segments 2153a, 2154a of the first electrode 215a are interdigitated with the electrode segments 2153b, 2154b of the second electrode 215b of the at least one external capacitor 215. The different interdigitated electrode segments 2151a, 2151b, 2152a, 2152b and 2153b, 2153a, 2154b, 2154a follow each other on respective circumferences of the sensor 200. Thanks to such a geometry, a Once the sensor 200 is molded into a contact lens, the at least one external capacitor 215 will be arranged towards an outer periphery of the lens corresponding to a zone of the lens that will be more affected by the varia. intraocular pressure of the carrier subject than areas near the center of the lens. The interdigitated electrode segments 2151a, 2151b, 2152a, 2152b and 2153b, 2153a, 2154b, 2154a can thus be arranged in such a way that the gap between the electrodes 215a, 215b, in particular the respective spacings between the segments interdigitated electrode 2151a, 2151b, 2152a, 2152b and 2153b, 2153a, 2154b, 2154a, varies (s) the most as a function of intraocular pressure. In this way, the internal capacitor 211 arranged on an inner periphery of the sensor 200 with respect to the inductance 201, whose difference between the electrodes 211a, 211b varies only very little or so to say not, will have a capacitive value essentially constant and will therefore have the role of placing the resonance frequency of the LC circuit made by the sensor 200 in the right frequency range, namely less than 30 MHz. On the other hand, the at least one external capacitor 215, arranged on an external periphery of the sensor 200 relative to the inductor 201, will have a capacitive value which will vary as a function of the intraocular pressure changes, the resonance frequency of the LC circuit realized by the sensor 200 remaining however in the right frequency range allowed by the internal capacitor 211. As illustrated in the embodiment shown in Figures 1 and 2, it is possible to use a blocker 216 in the sensor 200, serving as stiffening element for the at least one external capacitor 215. The blocker 216 may be composed of a metallic and / or dielectric material. As illustrated in FIGS. 1 and 2, the blocker 216 may advantageously be arranged on a plane parallel to the electrodes 215a, 215b of the external capacitor 215. In particular, the blocker 216 may be arranged on a perimeter of the sensor 200 on the outside. with respect to the external capacitor 215, more particularly at the terminations of the electrode segments 2151a, 2151b, 2152a, 2152b and 2153b, 2153a, 2154b, 2154a. Thus, in the embodiment illustrated in FIGS. 1 and 2, the blocker 216 is arranged at the crossing zone 209e of the inductor 201, but on a perimeter further outside than the external capacitor 215. use of a blocker 216 makes it possible to partially stiffen the zone near the endings of the electrode segments 2151a, 2151b, 2152a, 2152b and 2153b, 2153a, 2154b, 2154a, which offers the advantage of limiting the differences between these segments. 2151a, 2151b, 2152a, 2152b and 2153b, 2153a, 2154b, 2154a the plane of the external capacitor 215 and to avoid any misalignment perpendicular to this plane when the sensor 200 is molded inside a used contact lens to monitor changes in physiological parameters such as intraocular pressure. In particular, the arrangement of the blocker 216 serving as a stiffening element ensures that only the spacing of the electrodes 215a, 215b, in particular electrode segments 2151a, 2151b, 2152a, 2152b and 2153b, 2153a, 2154b, 2154a, external capacitor 215 vary from one another, and that the central zone between the electrode segments 2151a, 2151b, 2152a, 2152b and 2153b, 2153a, 2154b, 2154a, which faces the crossing zone 209e, does not move in any direction. favor of the spacing between the electrodes 215a, 215b, in particular between the electrode segments 2151a, 2151b, 2152a, 2152b and 2153b, 2153a, 2154b, 2154a.

In a variant of this embodiment, it is possible to use more than one blocker 216 and therefore more than one stiffening element. For example, at least one other stiffening element could be arranged at the crossing zone 209a, or else at other locations of the periphery of the sensor 200.

In a variant of the aspect described above in which the at least one external capacitor 215 comprises electrode segments 2151a, 2152a, 2153a, 2154a of its first electrode 215a which can be interdigitated with electrode segments 2151b, 2152b , 2153b, 2154b of its second electrode 215b, it is also possible that one or more of the electrode segments 2151a, 2152a, 2153a, 2154a and 2151b, 2152b, 2153b, 2154b have a comb-like geometry, two interdigitated electrode segments on successive circumferences, for example the segments 2152a and 2152b, then forming interdigitated combs with each other. It is also preferred to have a dielectric medium between the electrodes 211a, 211b of the internal capacitor 211 and / or between the electrodes 215a, 215b, in particular between the interdigital electrode segments 2151a, 2151b, 2152a, 2152b and 2153b, 2153a. 2154b, 2154a, of the at least one external capacitor 215. Similarly, it is preferred to have a dielectric medium between the conductive traces 2081a, 2082a, ..., 208 (n) a, 2081e, 2082e,. .., 208 (m) e, 213a, 213b and the first turn 202 and / or the second turn 203, especially at the crossing areas 209a, 209e.

The inductor 201 may also be of star-shaped geometry comprising a succession of branches, in particular an even number of branches, here more particularly eight branches 204a, 204b, 204c, 204d, 204e, 204f, 204g, 204h, and valleys. 205a, 205b, 205c, 205d, 205e, 205f, 205g, 205h, as illustrated in Figures 1-3. However, it is also possible that variants of this embodiment include an odd number of branches. The even numbered branch variant is preferred because the folding of the sensor 200 for molding in a contact lens is facilitated. In this case, as illustrated by the embodiment described with reference to FIGS. 1 to 3, the internal capacitor 211 and / or the at least one external capacitor 215 may have an arcuate geometry that at least partially adopts the geometry Thus, the two electrodes 211a, 211b of the internal capacitor 211 have an arcuate geometry partially following the star shape of the inductor 201, as illustrated in particular in FIGS. 1 and 3. Similarly, the segments 2151a, 2152a, 2153a, 2154a and 2151b, 2152b, 2153b, 2154b composing the electrodes 215a, 215b of the at least one external capacitor 215 also have an arcuate geometry according to the starry geometry of the inductor 201, as shown in FIGS. 1 to 3. In the star-shaped geometry variant, it is advantageous that the ends of the branches 204a, 204b, 204c, 204d, 204e, 204f, 204g, 204h and the bottom of each valley 205a, 205b, 205c, 205d, 205e, 205f, 205g, 205h are rounded, as shown in Figures 1 to 3, to allow better bending of the sensor 200 for molding in a contact lens. The dimensions of the sensor 200 may be adapted so as not to hinder the vision of a patient wearing a lens molded with such a sensor 200. In particular the distance between the center 210 of the star geometry, or the center of the sensor 200, and the end of each of the branches 204a, 204b, 204c, 204d, 204e, 204f, 204g, 204h may be substantially less than or equal to the radius of the lens, preferably between about 60 (3/0 and about 85 (3 / 0 the radius of the lens, so as not to exceed the lens after molding.Also, it is preferable that the distance between the center 210 and the bottom of each of the valleys 205a, 205b, 205c, 205d, 205e, 205f , 205g, 205h of the star geometry does not exceed about 55 (3/0 to about 75 (3/0 of the radius of the lens so as to be always less than the distance between the center 210 and the end of the branches 204a, 204b, 204c, 204d, 204e, 204f, 204g, 204h so as to respect These values are also preferable so as not to obstruct the view of the subject wearing a lens provided with such a sensor 200, especially in the dark or in low light conditions.

In the embodiment illustrated in FIGS. 1 to 3, the crossover zones 209a, 209e detailed in particular in FIGS. 2 and 3 are located in valleys 205a, 205e which are symmetrically opposed to the inductance 201, but in an alternative the zones of crossover could be in branches of the inductor 201. Nevertheless, in a variant of the combinations of inventive aspects leading to the embodiment illustrated in Figures 1 to 3, it is possible to arrange the crossing zones 209a, 209e in branches of the inductor 201, in particular symmetrically opposite branches, instead of the valleys 205a, 205e. By its various aspects, their possible variants and combinations, the invention makes it possible to solve several problems related to the manufacture and use of passive sensors for monitoring physiological parameters such as intraocular pressure. A variant of an aspect of the invention comprises arranging a capacitor in the inner portion of the sensor with respect to the inductor, which will therefore correspond to an area in the direction of the center of the lens. The inner zone of the lens being the least curved, any misalignment between the electrodes of the capacitor resulting from the curvature of the lens remains negligible or at least lower than the known case of the state of the art where the capacitor is on a circumference at the outside of the inductor. This capacitor in the center of the sensor has the role of shifting the resonance towards the desired range, for example less than 30 MHz. This variant is particularly advantageous in addition to the invention comprising arranging at least one capacitor on external regions of the sensor in order to increase its sensitivity at the edge of the contact lens. The at least one external capacitor arranged on the outer circumference of the sensor can thus increase the sensitivity of the sensor and can in particular be arranged such that the distance between its electrodes varies essentially as a function of the intraocular pressure. It is then advantageous for the electrodes of the at least one external capacitor to be arranged on the same plane of the sensor, which may be the plane of the inductor, which makes it possible to avoid misalignments due to the curvature of the sensor during its operation. incorporation into a contact lens. In addition, the sensitivity of the at least one external capacitor can be increased by using at least one blocker serving as a stiffening element to ensure that only the spacing of the electrodes of the external capacitor vary with each other, and that the central zone between the electrodes facing the crossover areas does not move in favor of the spacing between the electrodes. In addition, in the different aspects of the invention and their variants, it is possible to use arcuate elements preferably arranged on the same plane of the sensor, while the electrical connections between said elements are made by means of vias and electrical traces arranged on a second plane of the sensor. The conductive vias and conductive traces are then preferably arranged in the regions of intersection between the turns of the inductor. All aspects of the invention described above can be combined to obtain more sensor variants according to the invention.

Claims (18)

REVENDICATIONS1. An intraocular pressure sensor (200) for incorporation into a contact lens, comprising: an inductance (200) of substantially spiral geometry arranged substantially on a first plane of the sensor, and at least one external capacitor (215), with a first electrode ( 215a) and a second electrode (215b) separated by a dielectric medium, arranged on an outer periphery of the inductor (201), characterized in that the first (215a) and second (215b) electrodes of the at least one capacitor external (215) are arranged so that the gap between the electrodes (215a, 215b) varies as a function of the intraocular pressure. The sensor (200) of claim 1, characterized in that the sensor (200) further comprises an internal capacitor (211), with a first electrode (211a) and a second electrode (211b) separated by a dielectric medium, arranged on an inner periphery of the inductor (201), and in that the internal capacitor (211) has a capacitive value such that the resonant frequency of the sensor is less than about 30 MHz. 3. Sensor (200) according to claim 2, characterized in that the first electrode (211a) of the internal capacitor (211) is arranged on a plane parallel to the first plane, preferably the first plane of the sensor, and the second electrode ( 211b) of the internal capacitor (211) is arranged on a second plane of the sensor, preferably different from the first plane. 4. Sensor (200) according to any one of the preceding claims, characterized in that the first electrode (215a) and the second electrode (215b) of the at least one external capacitor (215) are arranged on the same parallel plane in the foreground of the sensor, preferably in the foreground of the sensor. 5. Sensor (200) according to any one of the preceding claims, characterized in that the at least one external capacitor (215) and / or the internal capacitor (211) is / are of substantially arcuate geometry, in particular according to the geometry of the inductance. The sensor (200) according to any of the preceding claims, characterized in that the first electrode (215a) and the second electrode (215b) of the at least one external capacitor (215) each comprise a plurality of segments of electrode, preferably each four electrode segments (2151a, 2152a, 2153a, 2154a, 2151b, 2152b, 2153b, 2154b), wherein the electrode segments (2151a, 2152a, 2153a, 2154a) of the first electrode ( 215a) are interdigitated with the electrode segments (2151b, 2152b, 2153b, 2154b) of the second electrode (215b). 7. Sensor (200) according to claim 6, characterized in that at least one of the electrode segments (2151a, 2152a, 2153a, 2154a) of the first electrode (215a) and at least one of the segments electrode (2151b, 2152b, 2153b, 2154b) of the second electrode (215b) of the at least one external capacitor (215) are in the form of interdigitated combs with each other. 8. Sensor (200) according to any one of the preceding claims, characterized in that the inductor (201) comprises a first turn (202) from the outer periphery portion of the inductor (201) and rotating in a first spiral direction toward the inner periphery of the inductor (201), and a second turn (203) extending the first turn (202) in the same spiral orientation from the inner periphery of the inductor (201) to the outer periphery of the inductor (201). the inductor (201), wherein the first turn (202) and the second turn (203) intersect in crossing areas, and the ends of the first turn (202) and the second turn (203) arranged on the outermost part of the inductor (201) form the terminals (206a, 206b) of the inductor (201). 9. Sensor (200) according to claim 8, characterized in that the first turn (202) and the second turn (203) intersect in at least two, preferably only two crossing zones (209a, 209e). 10. Sensor (200) according to claim 9, characterized in that the first turn (202) and the second turn (203) intersect by means of conductive vias (2071a, ..., 207 (2n) a, 2071e , ..., 207 (2m) e) arranged in the crossing zones (209a, 209e). 11. Sensor (200) according to any one of claims 8 to 10, characterized in that the electrical connections between the at least one external capacitor (215) and / or the internal capacitor (211) and the terminals (206a, 206b) of the inductor (201) are produced by means of conductive vias (212a, 212b, 212c, 214a, 214b, 214c, 214d). 12. Sensor (200) according to any one of claims 8 to 11, characterized in that the first turn (202) and / or the second turn (203) is / are formed (s) at least partially of a succession of segments (2031a, ..., 203 (m) a, 2031b, ..., 203 (n) b) connected by the conductive vias (2071a, ..., 207 (2n) a, 2071e, ... , 207 (2m) e). 13. Sensor (200) according to any one of claims 10 to 12, characterized in that the conductive vias (2071a, ..., 207 (2n) a, 2071e, ..., 207 (2m) e, 212a 212b, 212c, 214a, 214b, 214c, 214d) are connected by conductive traces (2081a, ..., 208 (n) a, 2081e, ..., 208 (m) e, 213a, 213b) arranged preferably on at least one plane different from the first plane of the sensor, in particular on the second plane of the sensor, and in which the conductive traces (2081a, ..., 208 (n) a, 2081e, ..., 208 ( m) e, 213a, 213b) are preferably separated from the first turn (202) and / or the second turn (203) and / or the first (215a) and second (215b) electrodes of the at least one capacitor external (215) and / or the first electrode (211a) of the internal capacitor (211) and / or the second electrode (211b) of the internal capacitor (211) by a dielectric medium. 14. Sensor (200) according to any one of the preceding claims, characterized in that the sensor (200) further comprises at least one stiffening element (216) for the at least one external capacitor (215). A sensor (200) according to claim 14 in combination with any one of claims 4 to 13, characterized in that the at least one stiffening element (216) is arranged on the same plane as the first electrode (215a). and the second electrode (215b) of the at least one external capacitor (215). 16. Sensor (200) according to any one of claims 14 or 15, characterized in that the at least one stiffening element (216) comprises a metallic material and / or a dielectric material. A contact lens, in particular a soft contact lens, comprising a sensor (200) according to any one of the preceding claims, wherein the sensor (200) is molded inside the lens. 18. Contact lens according to claim 17, wherein the inductor (201) is curved perpendicularly to the first plane of the sensor according to the curvature of the lens.