US20230181047A1 - Medical device provided with sensors - Google Patents
Medical device provided with sensors Download PDFInfo
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- US20230181047A1 US20230181047A1 US17/990,406 US202217990406A US2023181047A1 US 20230181047 A1 US20230181047 A1 US 20230181047A1 US 202217990406 A US202217990406 A US 202217990406A US 2023181047 A1 US2023181047 A1 US 2023181047A1
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Definitions
- the present invention relates to a medical device provided with sensors.
- the invention also relates to a medical system comprising such a medical device and a method for querying such a medical device, particularly in a medical system.
- the invention particularly relates to an implantable medical device such as a stent (sometimes also referred to as “arterial endoprosthesis”, “vascular stent”, or simply “spring”) provided with sensors.
- a stent sometimes also referred to as “arterial endoprosthesis”, “vascular stent”, or simply “spring”
- a stent is a device of tubular shape produced by a deformable mesh, particularly made of metal or of a biodegradable polymer material.
- the stent is inserted into a patient's body in a folded state, with the meshes closed, and is then extended inside the patient's body, for example by angioplasty which triggers the deployment of the meshes.
- the stent once deployed, helps keep a cavity open in the patient's body. It is known that fitting a stent may particularly cause tissue inflammation, hyperplasia and/or blood clotting.
- a stent may be provided with sensors, which make it possible to monitor the state of the tissues around the stent to, optionally, adapt the patient's treatment accordingly. Sensors may also be provided to ensure that the stent fulfils the function thereof of keeping a cavity open.
- a contactless querying device configured to measure an electromagnetic field emitted by the stent implanted in the patient.
- the patent EP-B-2 271 933 as such describes a method for characterising cells in the vicinity of a medical device implanted in a patient, particularly a stent, using impedance measurements at different frequencies.
- the application WO-A-2009/1 361 677 describes an implantable medical device such as a stent, having an electrically conductive surface and an impedance sensor for measuring the impedance of the conductive surface of the implantable medical device, at different frequencies, using the conductive surface as an electrode. The measurements made are used to determine the degree of restenosis of the tissues at the level of the implantable device, i.e. the tissue thickness having grown at the level of the conductive surface of the implantable medical device.
- U.S. Pat. No. 8,478,3708 a stent provided with sensors distributed on the inner surface thereof, oriented towards the passage through the stent, or “luminal” surface.
- the sensors are configured to send a specific characteristic output signal in response to an excitation.
- the specific characteristic signal may particularly be a wavelength specific to each of the sensors.
- U.S. Pat. No. 8,478,378 indicates that as such an output signal including signals from all or most of the sensors suggests that a large number of sensors are not coated with a layer of endothelial cells.
- the application DE-A-101 03 503 discloses a stent comprising electrodes for measuring the impedance of tissue in contact with the stent where each set of electrodes is associated with a multiplexer controlled by a control circuit. Implanting such multiplexers renders the stent structure complex.
- the application WO-A-2011/121581 describes an implantable medical device capable of responding to an electromagnetic query field emitted by a remote querying device.
- the implantable medical device is provided with a plurality of modulators consisting of RFID (“Radio-Frequency Identification”) chips, RFID chips arc suitable for the implantable medical device to respond to an electromagnetic query field according to a modulation generating a unique respective identification code.
- RFID Radio-Frequency Identification
- the use of RFID chips as sensors in the medical device limits however the number of sensors with which it may be provided.
- the multiplication of the RFID chips indeed increases the price of the medical device accordingly.
- the medical device must be at least partially made of a metallic material having good electrical conduction.
- the RFID chips must be implanted in the very structure of the implantable medical device, rendering the embodiment thereof particularly complex.
- Implantable medical devices are also known from WO-A-01/37 726 or U.S. Pat. No. 6,206,835. These medical devices include a structure implantable in the body to assist with carrying out a vital function in the body. One or a plurality of sensors are associated with this implantable structure, which make(s) it possible to measure a parameter associated with the structure. Finally, these medical devices include a communication circuit coupled with the sensor(s) to deliver a signal according to the parameter measured and to transmit this signal to a receiving device, outside the body, non-invasively.
- the aim of the invention is that of remedying the problems mentioned above.
- the aim of the invention is that of providing a medical device having a simple structure and therefore limited cost, suitable for distinguishing the quantities measured by various sensors with which the medical device is provided.
- the medical device is implantable in the patient's body and configured to make it possible to determine, without intruding the patient's body, whether it is implanted correctly.
- the invention relates to a medical device comprising an electrical measurement circuit, wherein are connected at least two variable-impedance sensors according to a detected physical quantity, an electrical power source for supplying power to the electrical measurement circuit, an antenna for emitting an electromagnetic field according to the impedance of the electrical measurement circuit, each of the sensors being associated with a switch for interrupting the current supply of the sensor in said measurement circuit, the medical device further comprising a system for controlling the switches in order to successively control the opening or the closing of the switches, according to determined configurations.
- the medical device is provided with any type of variable-impedance sensors connected to one another in a so-called measurement circuit.
- a control system makes it possible to switch off the current supply of the various sensors according to predetermined configurations, such that the electromagnetic field emitted by the medical device corresponds to the configuration of the measurement circuit.
- the term “disconnecting a sensor from the circuit” denotes hereinafter creating a circuit configuration such that the current passing through the sensor is nil, the other sensors being capable of being supplied with current.
- the sensor is for example disconnected from the circuit by being short-circuited per se or disconnected from the circuit by opening the sensor circuit, i.e. the sensor is disconnected from the circuit thereof.
- “disconnecting a sensor from the circuit”, in both scenarios denotes herein switching off the current supply of this sensor.
- the medical device includes one or a plurality of the following features taken alone or in combination:
- the invention also relates to a medical system comprising a medical device as described above in any combinations thereof and a unit for receiving information from the medical device, comprising means for sensing the electromagnetic field emitted by the antenna of the medical device.
- the medical system may further comprise a unit for querying the medical device, preferably merged with the unit for receiving information, preferably comprising means for emitting an electromagnetic field suitable for creating an induced current in the measurement circuit of the medical device.
- the medical system may comprise a comparator intended to compare an identifier emitted by the querying unit, with a binary code associated with a given combination of fixed impedances of the measurement circuit of the medical device.
- the medical system may further comprise a unit for processing the information received by the reception unit, for example a computer, the unit for processing information preferably having a screen to display in real time a model of the medical device whereon is transferred information relating to the values of the measurements made using the sensors.
- a unit for processing the information received by the reception unit for example a computer
- the unit for processing information preferably having a screen to display in real time a model of the medical device whereon is transferred information relating to the values of the measurements made using the sensors.
- the invention also relates to a method for querying a medical device as described above in any combinations thereof, particularly in a medical system as described above in any combinations thereof, comprising steps consisting of:
- the method may comprise a step for identifying the medical device.
- the method may also comprise a calibration step prior to each measurement or prior to certain measurements of the magnetic field emitted by the antenna of the medical device, corresponding to the magnetic field emitted by the antenna according to the current passing through the impedances and/or the elements of fixed and known impedance.
- FIG. 1 represents schematically a first example of a medical system comprising a medical device.
- FIG. 2 represents schematically a detail of the electrical circuit of the stent in FIG. 1 .
- FIG. 3 represents schematically a second example of a medical system comprising a medical device.
- FIG. 4 represents schematically a third example of a medical system comprising a medical device.
- FIG. 5 shows schematically a detail of the medical device in FIG. 4 .
- FIG. 6 represents schematically a fourth example of a medical system comprising a medical device.
- FIGS. 7 and 8 are schematic representations of alternative embodiments of the electrical circuits in FIGS. 1 and 3 .
- FIGS. 9 and 10 illustrate schematically an alternative embodiment of the electrical circuit in FIGS. 4 and 5 .
- FIGS. 11 and 12 illustrate two examples of electrical circuits having a plurality of measurement lines.
- FIG. 13 represents schematically in perspective a stent provided with sensors.
- FIG. 14 is a flow chart of a method for querying a medical device.
- FIG. 15 represents schematically a medical device identifier comparator.
- FIG. 1 illustrates schematically a medical system 10 comprising an implantable medical device 12 and a unit 14 , herein single, for querying the medical device 12 and receiving information from said medical device 12 .
- units for querying and receiving information may, alternatively, be separate.
- the medical device 10 may further comprise a unit for processing the information received by the receiving unit, for example a computer.
- the implantable medical device 12 includes a variable impedance 15 .
- the value of this variable impedance 15 is controlled by a control unit not shown, according to the impedance in a measurement circuit 16 , connecting particularly the various sensors 22 of the implantable medical device.
- the implantable medical device 12 further includes an electrical power source, herein a source of electric current formed by the body 18 of the implantable medical device 12 . Indeed, under the effect of an electromagnetic field emitted by the querying unit 14 , the body 18 of the implantable medical device 12 induces a current.
- an antenna or armature separate and electrically insulated from the body 18 of the implantable medical device 12 may also be provided, particularly in the case wherein the implantable medical device 12 is not suitable, completely or partially, for having an armature function.
- an electrical power source for the measurement circuit may include a current-conducting surface of the implantable medical device, suitable for inducing an electric current under the effect of an electromagnetic field.
- An electric battery or cell may also be provided as an electrical power source for the implantable medical device 12 .
- the body 18 of the implantable medical device 12 serves herein also as an emitting antenna, to emit an electromagnetic field outside the body wherein the implantable medical device is implanted.
- the intensity of this field is directly dependent on the variable impedance 15 , according to the impedance in the measurement circuit 16 .
- the intensity or a standard of the electromagnetic field emitted by the body 18 of the implantable medical device 12 is dependent on the impedance of the measurement circuit 16 .
- the implantable medical device 12 may include an antenna separate from the body of the implantable medical device or the antenna may be formed by a part at least of the implantable medical device.
- the implantable medical device 12 is for example a stent.
- the stent is a tubular metal device, preferably meshed, inserted into a natural human (or animal) cavity to keep it open, as described above in the introduction.
- the stent may for example be made of a metal alloy or polymer material, but other materials may also be envisaged.
- the implantable medical device 12 is provided with variable-impedance sensors 22 according to the physical quantity detected thereby.
- the term physical quantity denotes herein any property of natural science which may be quantified by measurement or computation, and the different possible values whereof are expressed using any real number or a complex number.
- a physical quantity includes therefore, for example, a length, an electric current, a voltage, an impedance, a concentration of a chemical element or even the presence and/or concentration of a biological or biochemical element.
- the sensors 22 are distributed on the surface of the implantable medical device.
- the sensors 22 may particularly be distributed:
- the sensors may be coated with an active agent, for example to limit hyperplasia of the tissues in contact with the implantable medical device, particularly when they are positioned on the abluminal surface of a stent or more generally on the outer surface of an implantable medical device intended to be in contact with the wall of the cavity wherein the medical device is implantable.
- an active agent for example to limit hyperplasia of the tissues in contact with the implantable medical device, particularly when they are positioned on the abluminal surface of a stent or more generally on the outer surface of an implantable medical device intended to be in contact with the wall of the cavity wherein the medical device is implantable.
- a single sensor particularly a pressure sensor, on the abluminal surface of a stent, or more generally on the outer surface of an implantable medical device already makes it possible to obtain information relating to the poor positioning of the stent or implantable medical device in the cavity. If the pressure measured is low (i.e. less than a threshold pressure), it is likely that the sensor is not in contact with a wall of the cavity, but rather with blood, for example. In the case where two sensors or more are arranged on the abluminal or outer surface, the information may be obtained with more precision by comparing the values measured by the sensors with one another.
- the sensors are arranged at the locations of the implantable medical device, particularly a stent, subject to the least deformations during the fitting of the implantable medical device, in order to avoid damaging the sensors.
- FIG. 13 shows a stent 12 with sensors 22 a fixed to the vertices of the meshes 120 of the stent 12 and sensors 22 c fixed to the mid-point of the sides of the meshes of the stent, it is preferred that all the stents 22 c be fixed to the centre of sides of the meshes 120 of the stent 12 .
- the sensors 22 a , 22 c may be arranged on the inner face or on the outer face of the stent 12 .
- a pressure sensor in the vicinity of each end of the stent 12 , on the inner face of the stent. As such, a difference in pressure between the values measured by these two sensors may be determined which makes it possible to identify the appearance of a blockage inside the stent.
- Each of the sensors may particularly be chosen from:
- the sensors 22 are variable-impedance sensors, i.e. sensors wherein the impedance varies according to the amplitude or intensity of the physical quantity detected. Hence, in the event of variation of the amplitude of the physical quantity detected by a sensors of the implantable medical device 12 , the impedance of this sensor varies in the measurement circuit 16 , such that, in the absence of any other variation in the measurement circuit 16 , the impedance of the measurement circuit 16 also varies.
- each sensor 22 is associated with a switch 24 suitable for disconnecting from the circuit, in this instance short-circuiting, the sensor 22 with which it is associated.
- this is carried out by mounting the switch 24 in derivation (or in parallel) with the sensor 22 with which it is associated.
- the sensors 22 are herein mounted in series in the measurement circuit 16 .
- each switch is herein embodied by a transistor 24 , in this instance a silicon MOS-FET transistor, more specifically a depletion-mode, P-channel MOS-FET (or p-MOS) transistor.
- each switch or certain switches may be embodied by another type of transistor, particularly by a FET transistor, an enhancement-mode MOS-FET transistor, particularly an enhancement-mode N-channel MOS-FET transistor, by a MEMS (standing for “Micromechanical system”), or by a mechanical switch.
- FIG. 1 further illustrates a system 26 for controlling the switches 24 , suitable for successively controlling the opening or closing of the switches 24 according to determined configurations.
- the control system 26 includes control modules 28 arranged in series with one another, each control module 28 being suitable for controlling the opening or closing of the switch 24 with which it is associated.
- control system 26 is configured to normally keep the switches 24 closed and to open same successively and then to close them again such that, at each time, a single switch 24 is open.
- each control module 28 is formed herein of a logic circuit, embodied by means of transistors 30 , 32 , 34 , 36 , 38 , a resistor 40 and a capacitor 42 .
- the resistor 40 and the capacitor 42 introduce a charging time of the capacitor 42 and a discharging time of said capacitor 42 in the logic circuit.
- the control module 28 controls the opening of the associated switch 24 .
- the switch 24 is kept closed for the rest of the time, thereby short-circuiting the associated sensor 22 .
- each control module 28 is embodied by means of three P-channel transistors 32 , 34 , 38 and two N-channel transistors 30 , 36 , as follows (only the connections hereinafter are made);
- the PMOS type transistor 32 When the voltage applied at the input of the first inverter is close to zero, therefore less than the threshold voltage of the transistors 30 and 32 , the PMOS type transistor 32 is switched to the ON-state, charging the capacitor 42 . At the end of the charging thereof, the voltage at the input of the second inverter is greater than the threshold voltage of the transistors 36 and 38 , rendering the NMOS type transistor 36 ON. A voltage close to zero is transmitted at the output of the second inverter connected to the gate of the PMOS type transistor 34 . The latter is then switched to the ON-state, transmitting a voltage close to zero to the gate of the PMOS type switch 24 , which triggers the closing thereof. While a voltage close to zero is applied to the input of the first inverter, the switch 24 is kept closed.
- the NMOS type transistor 30 When a voltage greater than the threshold voltage of the transistors 30 and 32 is applied at the input of the first inverter, the NMOS type transistor 30 is switched to the ON-state, transmitting to the output thereof the ground potential, which triggers the discharging of the capacitor 42 .
- the voltage at the input of the second inverter decreases until it becomes less than the threshold voltage of the transistors 36 and 38 , inhibiting the transistor 36 and activating the transistor 38 .
- the latter thereby transmits to the output of the second inverter a potential greater than the threshold voltage of the transistor 34 , triggering the inhibition thereof. Consequently, the switch 24 opens.
- the opening is induced of the switch 24 which is connected thereto, followed by the successive opening of the switches 24 connected to the subsequent control modules 28 .
- the trailing edge of this pulse induces the closing of the switch of the first module after a time equal to ⁇ .
- the voltage pulse is propagated from one input 46 to another, such that the trailing edge of this pulse at the input of a module n corresponds to the leading edge of the pulse at the input of the module n+ 1 . As such, in this instance, during the propagation of the pulse, all the switches are closed except one.
- the voltage at the terminals of the measurement circuit 16 which is equal to the sum of the voltages at the terminals of each of the sensors mounted in series in the measurement circuit, exhibits successive peaks which are representative of the voltage at the terminals of each of the sensors.
- each representative of the voltage at the terminals of a sensor 22 corresponds an intensity of the electromagnetic fields emitted by the body 18 of the implantable medical device 12 having an emitting antenna function.
- FIG. 1 the presence of a rectifier 56 as well as of an alternating current generator 58 in the implantable medical device 12 is observed. They make it possible respectively to supply the control circuit 26 with direct current and the measurement circuit 16 with a current having a frequency distinct from, particularly less than, the frequency of the induced current in the antenna 18 . This may be useful as the frequency of the induced current is dependent on the electromagnetic field emitted by the unit 14 said frequency being preferably chosen such that the electromagnetic wave is absorbed to a low degree by the tissues traversed. The use of such a frequency in the measurement circuit could impede the precision of the measurements made.
- the measurement circuit 16 is moreover completed in FIG. 1 , by a combination of sets of an impedance 60 , that is fixed and known, and a switch 24 , controlled by a control module 28 , as is the case for the switches 24 associated with the sensors 22 .
- This combination of known impedances makes it possible to identify the implantable medical device queried, for example by associating a combination of impedances 60 that are unique and known to each implantable medical device 12 . This particularly useful in the case where a plurality of such implantable medical devices have been implanted in the body of the same patient. Some electromagnetic field peaks measured are then used to identify the implantable medical device 12 , the other peaks to determine the values measured by each of the sensors of the implantable medical device 12 identified.
- the first electromagnetic field peaks measured may be used for identifying the implantable medical device 12 and the subsequent peaks for determining the values measured by each of the sensors of the implantable medical device 12 identified.
- these impedances being known, they are also suitable for calibrating the medical system 10 . In other words, these known impedances make it possible to quantify more accurately the values measured by the different sensors of the different implantable medical devices.
- the medical device may include a comparator 94 for comparing an identifier ID 1 emitted by the querying unit 14 , with a binary code ID 2 associated with the combination of impedances 60 present on the electrical circuit, this binary code being derived for example from the output of the analogue/digital converter 80 , or an identifier saved in a memory in the stent.
- the medical device may then be configured to only respond to the query by the querying unit if the comparison is positive.
- the identification may be carried out iteratively, the querying unit merely emitting one identification value at a time, each stent wherein the value corresponding of the identifier not corresponding being disabled—i.e., herein, not electrically powered—for a time suitable for identifying the only stent corresponding to the unique identifier and carrying out the measurements using different sensors in this medical device.
- FIG. 3 represents a second example of a medical system 100 .
- This medical system is substantially identical to that described above.
- the known impedances 60 and the sensors are mounted in series with the switch 24 which is associated therewith, the sets formed of an impedance 60 or a sensor 22 and a switch 24 being mounted in parallel (or in derivation) with respect to one another.
- the control modules 28 being identical to those described above, the electromagnetic field emitted following the creation of an induced current, corresponds to the sum of all the impedances 60 and of all the sensors 22 , minus one, each of the impedances 60 and the sensors 22 being disconnected from the circuit, in this instance disconnected, successively.
- control module 28 having a different operation, which controls the closing of the switch 24 during a time interval only, the switch 24 being open the rest of the time.
- Such an operation may also be obtained by retaining the control module 28 as described above and by replacing the depletion-mode MOS-FET transistors used as switches 24 by enhancement-mode MOS-FET transistors.
- FIGS. 4 and 5 illustrate a further example of a medical system 200 .
- the control of the switch 24 for disconnecting from the circuit the sensor 22 or a known impedance 60 is implanted directly in a module 62 also comprising the known impedance 60 or the sensor 22 , and the switch 24 , herein embodied by a transistor.
- a resistor 40 and a capacitor 42 are used to control the switch 24 such that it disconnects from the circuit the impedance 60 or the sensor 22 except during a charging time interval of the capacitor 42 .
- Charging the capacitor 42 activates the transistor 66 of the next module, inducing the charging of the corresponding capacitor 42 . Once charged, the capacitor 42 inhibits the associated transistor 24 , triggering the disconnection from the circuit of the impedance 60 or the sensor 22 which is connected thereto.
- each module 62 is embodied as following:
- each sensor 22 and impedance 66 is successively connected to the antenna 18 in order to be powered, the other sensors 22 and impedances 66 being for their part disconnected.
- FIG. 6 represents a fourth example of an embodiment of a medical system 300 .
- This medical system 300 is distinguished from the preceding example 200 , in that the measurement circuit 16 is directly connected to the antenna 18 for the emission of an electromagnetic field, without the intermediary of a separate variable impedance (the measurement circuit 16 itself having a variable impedance) and of a unit for controlling this variable impedance according to the impedance of the measurement circuit 16 .
- the electrical circuit on the medical device 12 is then particularly simplified.
- the measurement circuit 16 is connected directly to the antenna, the implantable medical device also comprising a control circuit associated with this measurement circuit and as described for example with regard to FIGS. 2 and 3 .
- each module may particularly by embodied in the following form.
- Two measurement electrodes for example of 60 ⁇ 60 ⁇ m 2 , made of an electrically conductive material, for example of polymer material or of metal alloy, preferably biocompatible, are deposited on an electrically insulating, biocompatible polymeric substrate (for example parylene).
- the electrical components of the control system and the switch are implanted in the polymeric substrate.
- the medical systems described above are suitable for carrying out a querying method 500 of the implantable medical device 12 , as shown by the flow chart in FIG. 14 .
- This method 500 includes a first step 502 consisting of powering the measurement circuit 16 .
- this power supply is carried out by an induced current in an antenna or in the body of the implantable medical device 12 when the latter is configured to generate an induced current. This makes it possible to power the measurement circuit 16 only when a measurement is made.
- the method 500 is continued by a step 504 consisting of activating the system for controlling the implantable medical device so that it successively controls the opening of the closing of each of the switches of the implantable medical device, according to determined configurations. It should be noted herein that within the scope of the examples described with regard to the figures, this activation is carried out simultaneously with the power supply of the measurement circuit 16 , by induction, in response to the emission of an electromagnetic field by the querying device.
- the method 500 then includes a step 506 for identifying the queried medical device. This step may, alternatively, be carried out before electrically powering the measurement circuit.
- the identification may be carried out either in the medical device per se, when the latter is provided with a comparator to compare an identification signal emitted by the querying unit with a unique identifier of the medical device.
- this identifier may take the form of a combination of known impedances in the medical device and/or in each measurement line of the medical device.
- the identification may be carried out iteratively, the querying unit merely emitting one digit of the identifier at a time, each of the medical devices wherein the identifier does not correspond to this digit being temporarily deactivated (i.e., in the example studied, not electrically powered).
- the identification is carried out in the processing unit, the signals emitted by the antenna 18 being interpreted by the processing unit to determine the combination of the impedances of the medical device and/or of the measurement line queried.
- a processing unit may be used to determine the value measured by each sensor and the implantable medical device that responded to the query, particularly if the controlled configurations of the measurement circuit are more complex.
- the processing unit may particularly be suitable for conducting Fourier analyses of the measured signals of electromagnetic fields emitted by the antenna of the implantable medical device, comparing the signals received (optionally processed) to previously measured signals and inferring therefrom the values measured by the various sensors of the implantable medical device, one location being suitable for being determined for each of the values measured.
- the medical device is temporarily deactivated, in the step 508 .
- the method 500 is continued then by a step 510 consisting of measuring the electromagnetic field emitted by the antenna of the implantable medical device.
- This measurement is made over a relatively long time so that the control system will have been able to control a relatively large number of different configurations of the measurement circuit so that the measurement makes it possible to determine the value measured by each of the sensors 22 of the implantable medical device 12 .
- the antenna 14 preferably emits a constant electromagnetic field to maintain the power supply of the measurement circuit 16 and the activation of the control system 26 .
- each configuration corresponds to the scenario where all the sensors or impedances of the measurement circuit are disconnected from the circuit, except one.
- the electromagnetic field measured it is possible to determine first of all the implantable medical device that responded to the query.
- the first peaks measured in the electromagnetic field emitted by the antenna correspond to fixed impedances, the combination whereof makes it possible to identify the implantable medical device.
- These magnetic fields measured may also be suitable for calibrating the system since the magnetic fields measured correspond to known impedances of the measurement circuit.
- the subsequent magnetic fields make it possible to determine the values measured by each of the sensors distributed on the implantable medical device.
- the corresponding magnetic fields emitted may be used to calibrate the following and/or preceding emitted signal, which originates from a measurement by a sensor 22 .
- the electrical power supply of the electrical circuit is switched off and the electrical circuit of the medical device 12 is deactivated.
- variable-impedance sensor may be used with any type of variable-impedance sensor according to the physical quantity detected thereby. It should also be noted that the sensors distributed on the implantable medical device may be of different types, i.e. they may detect different physical quantities.
- the method described above may particularly be used to determine whether the implantable medical device is suitably implanted (i.e. positioned) in the natural cavity that it is supposed to keep open, in particular, if it is indeed in contact with the wall of the cavity. Indeed, the effect of a stent, for example but this is true for most implantable medical devices, is markedly reduced if the latter is not bearing on the wall of the cavity (particularly of the vein or the artery) wherein it is inserted.
- the method described above makes it possible to determine whether each of these sensors is in contact with the wall, since it makes it possible to determine the pressure measured by each of the sensors.
- this function for determining the suitable position of the stent may be combined, that is to say that sensors, for example of pressure, may be arranged on the abluminal surface of the stent and sensors, optionally of another physical quantity, may be arranged on the luminal surface of the stent.
- sensors of the same physical quantity are distributed on the abluminal surface and on the luminal surface, substantially at the same position on the stent or implantable medical device.
- sensors of the same physical quantity are arranged at the same point of the stent, on either side of the stent body.
- the comparison of the values measured by each of these stent pairs also makes it possible to obtain indications of an incorrect position of the stent in the cavity.
- the sensor on the abluminal surface which should therefore be in contact with a wall, measures a substantially identical value to the sensor on the luminal surface, which is in contact with the blood, it is likely that the sensor on the abluminal surface is in fact in contact with blood also, not with a wall. It is therefore likely that the stent is poorly positioned in the cavity.
- a sensor arranged on the luminal or abluminal surface of the stent or, more generally, on a surface of an implantable medical device, particularly on a surface of the implantable medical device in contact with a wall of the cavity wherein the medical device is implanted or on a surface of the implantable medical device intended to be in contact with the blood is optionally coated with endothelial or smooth muscle tissue.
- EIS Electrical Impedance Spectroscopy
- the electrical circuit 10 A in FIG. 7 is an alternative embodiment of the circuit in FIG. 1 .
- the electrical circuit 10 A firstly includes an analogue/digital converter 80 situated between the electrical measurement circuit 16 and the variable impedance 15 connected to the antenna 18 in the emitting circuit.
- This analogue/digital converter 80 which may also be used in the electrical circuit 10 in FIG. 1 makes it possible to increase the range of signals which may be emitted by the antenna 18 .
- This converter 80 also makes it possible to enhance the signal-to-noise ratio of the measurements made.
- the electrical circuit 10 A is distinguished from that in FIG. 1 by the presence of an element 60 A of fixed and known impedance, for example a resistor, between the sensors 22 .
- the element 60 A is associated with a switch 24 controlled by a control module 28 in a module 62 A.
- the impedance of this element 60 A is preferably chosen such that the sensors 22 cannot attain this impedance value.
- the impedance of the element 60 A is less than 90% of the minimum impedance suitable for being attained by sensor 22 and/or greater than 110% of the maximum impedance suitable for being attained by a sensor 22 .
- a transition signal As such, between two emitted signals relative to a measurement by a sensor 22 , a transition signal, easily identifiable, is emitted. It is easier, as such, to distinguish between two successive measurements, separated by a signal of expected form. Moreover, the presence of this element 60 A between the sensors 22 may be suitable for calibrating the following and/or preceding sensor 22 . The measurement is therefore more precise. Obviously, further configurations may be envisaged. In particular, it is possible to envisage an element 60 A at the start of a line only, all the n sensors 22 , n being a natural integer different to zero, or even an irregular distribution of the elements 60 A on the measurement line.
- FIG. 8 represents an alternative embodiment 100 A of the electrical circuit 100 in FIG. 3 , with an analogue/digital converter 80 and elements 60 A of known and fixed impedance, such as the electrical circuit 10 A.
- the advantages of these modifications are the same as within the scope of the electrical circuit 10 A in FIG. 7 .
- FIG. 11 an electrical diagram of an alternative electrical circuit 10 B of the electrical circuit 10 in FIG. 1 has been represented.
- This electrical diagram 10 B is distinguished from the electrical circuit 10 in FIG. 1 in that it includes a plurality of measurement lines 90 , mounted in parallel, where the electrical circuit 10 in FIG. 1 merely includes a single line.
- the measurement lines 90 are identical to the single line represented in FIG. 1 .
- the measurement circuit 16 includes however line selectors 92 , to carry out the measurement in each of the lines independently from the other lines 90 , particularly each line in succession from one another.
- the line selectors 92 may adopt a substantially identical form to the control modules 28 , thereby supplying each line 90 with current, successively.
- an analogue/digital converter 80 is also provided between the parallel branches formed by the measurement lines 90 and the variable impedance 15 .
- the electrical circuit 10 C illustrated in FIG. 12 is similar to the electrical circuit 10 B in FIG. 11 . It is essentially distinguished by the presence of an analogue/digital converter 80 on each of the measurement lines 90 in parallel.
- the electrical circuit 10 B, 10 C includes a plurality of measurement lines
- the measurement lines extend on the medical device 12 , particularly on the stent 12 in imbricated coaxial helices.
- the measurement lines extends in parallel along helices wound around one another. Indeed, this makes it possible to minimise the distance between sensors of different lines.
- This is particularly advantageous because if a sensor 22 of a line 90 , or even the entire line 90 is defective, the missing value(s) may be better approximated by the values measured with the other measurement line(s), of which one or a plurality of sensors are situated in the vicinity.
- the device 12 thereby gains in robustness, which is particularly advantageous when it is implanted in a patient's body.
- the electrical circuits described are suitable for determining for each sensor of the electrical circuits, the value measured thereby.
- Representing the pressures measured by pressure sensors arranged on the outer surface of the medical device, particularly of the stent, can enable the practitioner to determine whether this medical device is correctly implanted or not: a measured pressure that is too low, for example, may indicate that the stent is not in contact with the wall of the cavity receiving same.
- the processing unit of the medical system described above comprising for example an electronic control unit and a screen, or a computer, may be suitable for determining a real-time model, for example a 3D model, based on the values measured and displaying the model on the screen.
- the values between the measurement points may, in this case, be approximated, particularly by convolution according to the distance to the closest measurement points.
- Various visual and/or acoustic signals may be emitted by the processing unit, in the scenario where at least one measured value does not meet expectations.
- the visual signals may particularly be suitable for identifying on the model shown, the sensors 22 for which the measured values are not conforming.
- the processing unit may process the digital values measured, compare them to expected value ranges and display as an output in a different manner, the points where the measurement is within the ranges and the points where the measurement is not within the ranges, for example by using different display colours.
- the visual signals complete the display of the model described above.
- the implantable medical device may be chosen from the group comprising:
- the medical device may not be implantable. It can then, in particular, be applied on a part of the human body.
- the medical device may in this case take the form of a dressing, bandage or strip to be applied onto a patient's skin.
- the medical device may also take the form of a contact lens to be placed on a patient's cornea.
- the medical device may be neither implantable in the human body, not applicable thereon.
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Abstract
The invention relates to a medical device (12) comprising an electrical measurement circuit (16), in which are connected at least two variable-impedance sensors (22), the impedance of which varies according to a detected physical quantity, an electrical power source (18) for supplying power to the electrical measurement circuit (16), an antenna (18) for emitting an electromagnetic field according to the impedance of the electrical measurement circuit (16), each of the sensors (22) being associated with a switch (24) for interrupting the current supply of the sensor (22) in said measurement circuit (16), the medical device (12) additionally comprising a system (26) for controlling the switches (24) in order to successively control the opening or the closing of the switches (24), according to determined configurations. The medical device (12) may in particular be applied to the human body or implanted within the human body.
Description
- The present invention relates to a medical device provided with sensors. The invention also relates to a medical system comprising such a medical device and a method for querying such a medical device, particularly in a medical system.
- The invention particularly relates to an implantable medical device such as a stent (sometimes also referred to as “arterial endoprosthesis”, “vascular stent”, or simply “spring”) provided with sensors.
- A stent is a device of tubular shape produced by a deformable mesh, particularly made of metal or of a biodegradable polymer material. The stent is inserted into a patient's body in a folded state, with the meshes closed, and is then extended inside the patient's body, for example by angioplasty which triggers the deployment of the meshes. The stent, once deployed, helps keep a cavity open in the patient's body. It is known that fitting a stent may particularly cause tissue inflammation, hyperplasia and/or blood clotting.
- Consequently, a stent may be provided with sensors, which make it possible to monitor the state of the tissues around the stent to, optionally, adapt the patient's treatment accordingly. Sensors may also be provided to ensure that the stent fulfils the function thereof of keeping a cavity open.
- It is known to query a stent, i.e. collect information from this stent, using a contactless querying device, retained outside the patient. Generally, such a contactless querying device is configured to measure an electromagnetic field emitted by the stent implanted in the patient.
- The patent EP-B-2 271 933 as such describes a method for characterising cells in the vicinity of a medical device implanted in a patient, particularly a stent, using impedance measurements at different frequencies.
- The application WO-A-2009/1 361 677 describes an implantable medical device such as a stent, having an electrically conductive surface and an impedance sensor for measuring the impedance of the conductive surface of the implantable medical device, at different frequencies, using the conductive surface as an electrode. The measurements made are used to determine the degree of restenosis of the tissues at the level of the implantable device, i.e. the tissue thickness having grown at the level of the conductive surface of the implantable medical device.
- These documents disclose methods providing overall information on the implantable device, without making it possible to obtain independently the measurements made by each sensor with which the implantable medical device is provided.
- Moreover, it is known from U.S. Pat. No. 8,478,378, a stent provided with sensors distributed on the inner surface thereof, oriented towards the passage through the stent, or “luminal” surface. The sensors are configured to send a specific characteristic output signal in response to an excitation. The specific characteristic signal may particularly be a wavelength specific to each of the sensors. U.S. Pat. No. 8,478,378 indicates that as such an output signal including signals from all or most of the sensors suggests that a large number of sensors are not coated with a layer of endothelial cells.
- The application DE-A-101 03 503 discloses a stent comprising electrodes for measuring the impedance of tissue in contact with the stent where each set of electrodes is associated with a multiplexer controlled by a control circuit. Implanting such multiplexers renders the stent structure complex.
- It is known from the applications US-A-2011/0054583 and US-A-2012/0190989 a sensor array topology in a stent. Such a topology enables addressing of the sensors by row and by column, enabling activation of the sensors in a reconfigurable manner and independently from one another.
- Finally, the application WO-A-2011/121581 describes an implantable medical device capable of responding to an electromagnetic query field emitted by a remote querying device. The implantable medical device is provided with a plurality of modulators consisting of RFID (“Radio-Frequency Identification”) chips, RFID chips arc suitable for the implantable medical device to respond to an electromagnetic query field according to a modulation generating a unique respective identification code.
- The use of RFID chips as sensors in the medical device limits however the number of sensors with which it may be provided. The multiplication of the RFID chips indeed increases the price of the medical device accordingly. Moreover, according to this document, the medical device must be at least partially made of a metallic material having good electrical conduction. Finally, according to this document, the RFID chips must be implanted in the very structure of the implantable medical device, rendering the embodiment thereof particularly complex.
- Implantable medical devices are also known from WO-A-01/37 726 or U.S. Pat. No. 6,206,835. These medical devices include a structure implantable in the body to assist with carrying out a vital function in the body. One or a plurality of sensors are associated with this implantable structure, which make(s) it possible to measure a parameter associated with the structure. Finally, these medical devices include a communication circuit coupled with the sensor(s) to deliver a signal according to the parameter measured and to transmit this signal to a receiving device, outside the body, non-invasively.
- The aim of the invention is that of remedying the problems mentioned above. In particular, the aim of the invention is that of providing a medical device having a simple structure and therefore limited cost, suitable for distinguishing the quantities measured by various sensors with which the medical device is provided. In one preferred embodiment, the medical device is implantable in the patient's body and configured to make it possible to determine, without intruding the patient's body, whether it is implanted correctly.
- The invention relates to a medical device comprising an electrical measurement circuit, wherein are connected at least two variable-impedance sensors according to a detected physical quantity, an electrical power source for supplying power to the electrical measurement circuit, an antenna for emitting an electromagnetic field according to the impedance of the electrical measurement circuit, each of the sensors being associated with a switch for interrupting the current supply of the sensor in said measurement circuit, the medical device further comprising a system for controlling the switches in order to successively control the opening or the closing of the switches, according to determined configurations.
- As such, according to the invention, the medical device is provided with any type of variable-impedance sensors connected to one another in a so-called measurement circuit. A control system makes it possible to switch off the current supply of the various sensors according to predetermined configurations, such that the electromagnetic field emitted by the medical device corresponds to the configuration of the measurement circuit. By carrying out successive measurements, corresponding to linearly independent configurations—for example one sensor disconnected from the circuit at a time or all the sensors disconnected from the circuit at a time except one—it is very readily possible to obtain qualitative information on the values measured by each of the sensors of the medical device, arranged at known locations on the medical device.
- The term “disconnecting a sensor from the circuit” denotes hereinafter creating a circuit configuration such that the current passing through the sensor is nil, the other sensors being capable of being supplied with current. The sensor is for example disconnected from the circuit by being short-circuited per se or disconnected from the circuit by opening the sensor circuit, i.e. the sensor is disconnected from the circuit thereof. In other words, “disconnecting a sensor from the circuit”, in both scenarios, denotes herein switching off the current supply of this sensor.
- Preferably, the medical device includes one or a plurality of the following features taken alone or in combination:
-
- the medical device is implantable in the human body or can be applied on the human body;
- each switch is formed by one or more transistors, particularly one or more field-effect transistors FET, more particularly one or more metal-oxide-semiconductor field-effect transistors MOS-FET, enhancement or depletion mode, N-channel or P-channel type, one or more MEMS, or one or more mechanical switches;
- the system for controlling the switches includes a control circuit, powered by the electrical power source, and configured, preferably, to control successively the opening or closing of the various switches, one after the other;
- the control system includes components implanted directly in the measurement circuit, preferably to control successively the opening or closing of the various switches, one after the other;
- the control system includes modules having the same structure, arranged in series with respect to one another, each controlling an associated switch;
- the input of the first module controls successively the opening or closing of the various switches, one after the other; in other words, a change of status of this input triggers, after some time, a change of status at the output of the module corresponding to the input of the next module;
- each module includes a series RC circuit the charging or discharging whereof triggers the closing or opening of the associated switch;
- charging or discharging of a series RC circuit of a module induces the charging or discharging of the series RC circuit of the next module;
- each module includes:
- a first transistor the source whereof is connected to the input of the module, the gate to the output thereof and the drain to the gate of the associated switch,
- a first inverter the input whereof is connected to that of the module and the output to a first terminal of the resistor of the series RC circuit, the second terminal of the resistor being connected to a first terminal of the capacitor, the second terminal thereof being connected to the ground,
- a second inverter the input whereof is connected to the second terminal of the resistor and the output to that of the of the module, said output forming the input of the next module.
- each module includes:
- a first transistor the gate whereof is connected to the input of the module and the drain to the positive power supply terminal;
- a second transistor the source whereof is connected to that of the first transistor, the gate to the output of the module and the drain to a first terminal of the variable-impedance sensor the second terminal whereof is connected to the ground,
- a diode the anode whereof is connected to the source of the first transistor and the cathode to a first terminal of the resistor of the series RC circuit, the second terminal thereof being connected to the output of the module, the capacitor of the series RC circuit being connected between the output of the module and the ground.
- each set of a switch and a sensor is mounted in series and the sets of a switch and a sensor are mounted in parallel with respect to one another;
- each set of a switch and a sensor is mounted in parallel and the sets of a switch and a sensor are mounted in series with respect to one another; the electrical power source includes a current-conducting surface of the medical device, suitable for inducing an electrical current under the effect of an electromagnetic field;
- at least one of the sensors is arranged on a surface of the medical device, intended to be in contact with a part of the body whereon the device is applied or wherein the device is implantable;
- the antenna is formed by a part at least of the medical device;
- the measurement circuit includes a plurality of fixed impedances, each associated with a switch the opening and closing whereof are controlled by the control system; the medical device is implantable in the human body and is chosen from the group comprising:
- a vascular support or stent, at least one sensor being preferably arranged on an abluminal surface of the vascular stent,
- a heart valve,
- a cardiac stimulator,
- a cochlear implant,
- a throat implant,
- an orthopaedic implant,
- a brain implant,
- a retinal implant,
- a catheter, or
- a cellular tissue;
- each sensor is chosen from:
- a shear sensor,
- a pressure sensor,
- an impedance sensor,
- a heat dissipation sensor,
- a stress gauge, and
- a flow sensor, particularly of the hot-wire type;
- the implantable medical device is a vascular stent with at least one impedance sensor arranged on an abluminal surface of the vascular stent;
- the medical device forms a through conduit, the medical device including two pressure sensors arranged at each of the ends of the through conduit, in the through conduit;
- the medical device comprises between two sensors each associated with a switch, an element of fixed and known impedance being preferably provided between each of the sets of a sensor associated with a switch;
- the medical device is a meshed vascular stent, at least one sensor, preferably all the sensors, being arranged at the mid-point of one side of a mesh of the vascular stent;
- the medical device comprises at least one analogue/digital converter, the output signal whereof controls the emitting antenna, optionally indirectly, particularly via a variable resistor; and
- the medical device comprises a plurality of measurement lines, the measurement lines extending on the medical device, particularly on the vascular stent, along coaxial helices.
- The invention also relates to a medical system comprising a medical device as described above in any combinations thereof and a unit for receiving information from the medical device, comprising means for sensing the electromagnetic field emitted by the antenna of the medical device.
- The medical system may further comprise a unit for querying the medical device, preferably merged with the unit for receiving information, preferably comprising means for emitting an electromagnetic field suitable for creating an induced current in the measurement circuit of the medical device.
- The medical system may comprise a comparator intended to compare an identifier emitted by the querying unit, with a binary code associated with a given combination of fixed impedances of the measurement circuit of the medical device.
- The medical system may further comprise a unit for processing the information received by the reception unit, for example a computer, the unit for processing information preferably having a screen to display in real time a model of the medical device whereon is transferred information relating to the values of the measurements made using the sensors.
- The invention also relates to a method for querying a medical device as described above in any combinations thereof, particularly in a medical system as described above in any combinations thereof, comprising steps consisting of:
-
- powering the measurement circuit of the medical device,
- activating the control system so that it successively controls the opening or closing of each of the switches, according to determined configurations, and
- measuring the electromagnetic field emitted by the antenna of the medical device.
- The method may comprise a step for identifying the medical device.
- The method may also comprise a calibration step prior to each measurement or prior to certain measurements of the magnetic field emitted by the antenna of the medical device, corresponding to the magnetic field emitted by the antenna according to the current passing through the impedances and/or the elements of fixed and known impedance.
- The appended figures will help understand clearly how the invention may be embodied. In these figures, identical references denote similar elements.
-
FIG. 1 represents schematically a first example of a medical system comprising a medical device. -
FIG. 2 represents schematically a detail of the electrical circuit of the stent inFIG. 1 . -
FIG. 3 represents schematically a second example of a medical system comprising a medical device. -
FIG. 4 represents schematically a third example of a medical system comprising a medical device. -
FIG. 5 shows schematically a detail of the medical device inFIG. 4 , -
FIG. 6 represents schematically a fourth example of a medical system comprising a medical device. -
FIGS. 7 and 8 are schematic representations of alternative embodiments of the electrical circuits inFIGS. 1 and 3 . -
FIGS. 9 and 10 illustrate schematically an alternative embodiment of the electrical circuit inFIGS. 4 and 5 . -
FIGS. 11 and 12 illustrate two examples of electrical circuits having a plurality of measurement lines. -
FIG. 13 represents schematically in perspective a stent provided with sensors. -
FIG. 14 is a flow chart of a method for querying a medical device. -
FIG. 15 represents schematically a medical device identifier comparator. - Hereinafter in the description, elements that are identical or have an identical function bear the same reference sign in the various embodiments. For the purposes of conciseness of the present description, these elements are not described with regard to each of the embodiments, only the differences between the embodiments being described.
-
FIG. 1 illustrates schematically amedical system 10 comprising an implantablemedical device 12 and aunit 14, herein single, for querying themedical device 12 and receiving information from saidmedical device 12. Obviously, units for querying and receiving information may, alternatively, be separate. Themedical device 10 may further comprise a unit for processing the information received by the receiving unit, for example a computer. - The implantable
medical device 12 includes avariable impedance 15. The value of thisvariable impedance 15 is controlled by a control unit not shown, according to the impedance in ameasurement circuit 16, connecting particularly thevarious sensors 22 of the implantable medical device. The implantablemedical device 12 further includes an electrical power source, herein a source of electric current formed by thebody 18 of the implantablemedical device 12. Indeed, under the effect of an electromagnetic field emitted by the queryingunit 14, thebody 18 of the implantablemedical device 12 induces a current. Alternatively, an antenna or armature separate and electrically insulated from thebody 18 of the implantablemedical device 12 may also be provided, particularly in the case wherein the implantablemedical device 12 is not suitable, completely or partially, for having an armature function. In the latter case in particular, an electrical power source for the measurement circuit may include a current-conducting surface of the implantable medical device, suitable for inducing an electric current under the effect of an electromagnetic field. An electric battery or cell may also be provided as an electrical power source for the implantablemedical device 12. - The
body 18 of the implantablemedical device 12 serves herein also as an emitting antenna, to emit an electromagnetic field outside the body wherein the implantable medical device is implanted. For example, at a constant induced current intensity of the electrical power source, the intensity of this field is directly dependent on thevariable impedance 15, according to the impedance in themeasurement circuit 16. As such, the intensity or a standard of the electromagnetic field emitted by thebody 18 of the implantable medical device 12 (or more generally of the emitting antenna) is dependent on the impedance of themeasurement circuit 16. Alternatively, the implantablemedical device 12 may include an antenna separate from the body of the implantable medical device or the antenna may be formed by a part at least of the implantable medical device. - The implantable
medical device 12 is for example a stent. The stent is a tubular metal device, preferably meshed, inserted into a natural human (or animal) cavity to keep it open, as described above in the introduction. The stent may for example be made of a metal alloy or polymer material, but other materials may also be envisaged. - The implantable
medical device 12 is provided with variable-impedance sensors 22 according to the physical quantity detected thereby. The term physical quantity denotes herein any property of natural science which may be quantified by measurement or computation, and the different possible values whereof are expressed using any real number or a complex number. A physical quantity includes therefore, for example, a length, an electric current, a voltage, an impedance, a concentration of a chemical element or even the presence and/or concentration of a biological or biochemical element. - The
sensors 22 are distributed on the surface of the implantable medical device. In the particular case of the stent described herein, thesensors 22 may particularly be distributed: -
- only on the “abluminal” surface of the body of the stent, i.e. the surface opposite the lumen through the stent, intended to be in contact with the wall of the cavity to be kept open but not on the luminal surface; or
- only on the luminal surface but not on the abluminal surface; or
- both on the luminal and abluminal surfaces; and
- on the surfaces connecting the luminal and abluminal surfaces.
- The sensors may be coated with an active agent, for example to limit hyperplasia of the tissues in contact with the implantable medical device, particularly when they are positioned on the abluminal surface of a stent or more generally on the outer surface of an implantable medical device intended to be in contact with the wall of the cavity wherein the medical device is implantable.
- It should be noted that positioning a single sensor, particularly a pressure sensor, on the abluminal surface of a stent, or more generally on the outer surface of an implantable medical device already makes it possible to obtain information relating to the poor positioning of the stent or implantable medical device in the cavity. If the pressure measured is low (i.e. less than a threshold pressure), it is likely that the sensor is not in contact with a wall of the cavity, but rather with blood, for example. In the case where two sensors or more are arranged on the abluminal or outer surface, the information may be obtained with more precision by comparing the values measured by the sensors with one another.
- Preferably, the sensors are arranged at the locations of the implantable medical device, particularly a stent, subject to the least deformations during the fitting of the implantable medical device, in order to avoid damaging the sensors. As such, although
FIG. 13 shows astent 12 withsensors 22 a fixed to the vertices of themeshes 120 of thestent 12 andsensors 22 c fixed to the mid-point of the sides of the meshes of the stent, it is preferred that all thestents 22 c be fixed to the centre of sides of themeshes 120 of thestent 12. Thesensors stent 12. However, it is particularly advantageous to place a pressure sensor in the vicinity of each end of thestent 12, on the inner face of the stent. As such, a difference in pressure between the values measured by these two sensors may be determined which makes it possible to identify the appearance of a blockage inside the stent. - Each of the sensors may particularly be chosen from:
-
- a shear sensor,
- a pressure sensor,
- an impedance sensor,
- a heat dissipation sensor,
- a stress gauge, and
- a flow sensor of the “hot wire sensor” type.
- The
sensors 22 are variable-impedance sensors, i.e. sensors wherein the impedance varies according to the amplitude or intensity of the physical quantity detected. Hence, in the event of variation of the amplitude of the physical quantity detected by a sensors of the implantablemedical device 12, the impedance of this sensor varies in themeasurement circuit 16, such that, in the absence of any other variation in themeasurement circuit 16, the impedance of themeasurement circuit 16 also varies. - As illustrated, each
sensor 22 is associated with aswitch 24 suitable for disconnecting from the circuit, in this instance short-circuiting, thesensor 22 with which it is associated. Herein, this is carried out by mounting theswitch 24 in derivation (or in parallel) with thesensor 22 with which it is associated. Thesensors 22 are herein mounted in series in themeasurement circuit 16. For reasons of ease of embodiment and miniaturisation, each switch is herein embodied by atransistor 24, in this instance a silicon MOS-FET transistor, more specifically a depletion-mode, P-channel MOS-FET (or p-MOS) transistor. In further embodiments, each switch or certain switches may be embodied by another type of transistor, particularly by a FET transistor, an enhancement-mode MOS-FET transistor, particularly an enhancement-mode N-channel MOS-FET transistor, by a MEMS (standing for “Micromechanical system”), or by a mechanical switch. -
FIG. 1 further illustrates asystem 26 for controlling theswitches 24, suitable for successively controlling the opening or closing of theswitches 24 according to determined configurations. Herein, thecontrol system 26 includescontrol modules 28 arranged in series with one another, eachcontrol module 28 being suitable for controlling the opening or closing of theswitch 24 with which it is associated. - In this instance, the
control system 26 is configured to normally keep theswitches 24 closed and to open same successively and then to close them again such that, at each time, asingle switch 24 is open. - For this purpose, each
control module 28 is formed herein of a logic circuit, embodied by means oftransistors resistor 40 and acapacitor 42. Theresistor 40 and thecapacitor 42 introduce a charging time of thecapacitor 42 and a discharging time of saidcapacitor 42 in the logic circuit. During these charging and discharging times, thecontrol module 28 controls the opening of the associatedswitch 24. Theswitch 24 is kept closed for the rest of the time, thereby short-circuiting the associatedsensor 22. - More specifically, and as shown in
FIG. 2 , herein, eachcontrol module 28 is embodied by means of three P-channel transistors channel transistors -
- first and
second branches measurement circuit 16 are connected in parallel, thefirst branch 44 being the positive power supply terminal and thesecond branch 46 being the input of themeasurement circuit 16 which is powered by a start circuit, not shown in the figures, configured to generate a crenelated voltage pulse during a certain time interval; - the gate of the
first transistor 30 and the gate of thesecond transistor 32 are connected together, as well as to the source of thethird transistor 34 and to thesecond branch 46 of the precedingcontrol module 28, the twotransistors - the gate of the
fourth transistor 36 and the gate of thefifth transistor 38 are connected together as well as to a terminal of theresistor 40 and to a terminal of thecapacitor 42, the twotransistors - the source of the
first transistor 30, the source of thefourth transistor 36 and a terminal of thecapacitor 42 are connected to theground 48; - the other terminal of the
resistor 40, which is not connected to thecapacitor 42, is connected to the drain of thefirst transistor 30 and to the drain of thesecond transistor 32; - the drain of the
fourth transistor 36 and the drain of thefifth transistor 38 are connected together to thesecond branch 46 of thenext control module 28, as well as the gate of thethird transistor 34; - the source of the
second transistor 32 and the source of thefifth transistor 38 are connected together to thefirst branch 44 of the precedingcontrol module 28; - the drain of the
third transistor 34 is connected to the gate of thetransistor 24 having a switch function to short-circuit thesensor 22.
- first and
- When the voltage applied at the input of the first inverter is close to zero, therefore less than the threshold voltage of the
transistors PMOS type transistor 32 is switched to the ON-state, charging thecapacitor 42. At the end of the charging thereof, the voltage at the input of the second inverter is greater than the threshold voltage of thetransistors NMOS type transistor 36 ON. A voltage close to zero is transmitted at the output of the second inverter connected to the gate of thePMOS type transistor 34. The latter is then switched to the ON-state, transmitting a voltage close to zero to the gate of thePMOS type switch 24, which triggers the closing thereof. While a voltage close to zero is applied to the input of the first inverter, theswitch 24 is kept closed. - When a voltage greater than the threshold voltage of the
transistors NMOS type transistor 30 is switched to the ON-state, transmitting to the output thereof the ground potential, which triggers the discharging of thecapacitor 42. During this discharging, the voltage at the input of the second inverter decreases until it becomes less than the threshold voltage of thetransistors transistor 36 and activating thetransistor 38. The latter thereby transmits to the output of the second inverter a potential greater than the threshold voltage of thetransistor 34, triggering the inhibition thereof. Consequently, theswitch 24 opens. As such, by applying a high positive voltage at the input of the first inverter of thefirst control module 28, the opening is induced of theswitch 24 which is connected thereto, followed by the successive opening of theswitches 24 connected to thesubsequent control modules 28. The start circuit, not shown, powering theinput 46 of the first module is configured to generate a crenelated voltage pulse for a time interval τ=RC. The trailing edge of this pulse induces the closing of the switch of the first module after a time equal to τ. The voltage pulse is propagated from oneinput 46 to another, such that the trailing edge of this pulse at the input of a module n corresponds to the leading edge of the pulse at the input of the module n+1. As such, in this instance, during the propagation of the pulse, all the switches are closed except one. - With such a control system, the voltage at the terminals of the
measurement circuit 16, which is equal to the sum of the voltages at the terminals of each of the sensors mounted in series in the measurement circuit, exhibits successive peaks which are representative of the voltage at the terminals of each of the sensors. To each of the successive peaks, each representative of the voltage at the terminals of asensor 22, corresponds an intensity of the electromagnetic fields emitted by thebody 18 of the implantablemedical device 12 having an emitting antenna function. - In
FIG. 1 , the presence of arectifier 56 as well as of an alternatingcurrent generator 58 in the implantablemedical device 12 is observed. They make it possible respectively to supply thecontrol circuit 26 with direct current and themeasurement circuit 16 with a current having a frequency distinct from, particularly less than, the frequency of the induced current in theantenna 18. This may be useful as the frequency of the induced current is dependent on the electromagnetic field emitted by theunit 14 said frequency being preferably chosen such that the electromagnetic wave is absorbed to a low degree by the tissues traversed. The use of such a frequency in the measurement circuit could impede the precision of the measurements made. - The
measurement circuit 16 is moreover completed inFIG. 1 , by a combination of sets of animpedance 60, that is fixed and known, and aswitch 24, controlled by acontrol module 28, as is the case for theswitches 24 associated with thesensors 22. This combination of known impedances makes it possible to identify the implantable medical device queried, for example by associating a combination ofimpedances 60 that are unique and known to each implantablemedical device 12. This particularly useful in the case where a plurality of such implantable medical devices have been implanted in the body of the same patient. Some electromagnetic field peaks measured are then used to identify the implantablemedical device 12, the other peaks to determine the values measured by each of the sensors of the implantablemedical device 12 identified. For example, the first electromagnetic field peaks measured may be used for identifying the implantablemedical device 12 and the subsequent peaks for determining the values measured by each of the sensors of the implantablemedical device 12 identified. Furthermore, these impedances being known, they are also suitable for calibrating themedical system 10. In other words, these known impedances make it possible to quantify more accurately the values measured by the different sensors of the different implantable medical devices. - Alternatively, according to the embodiment represented partially and schematically in
FIG. 15 , the medical device may include acomparator 94 for comparing an identifier ID1 emitted by the queryingunit 14, with a binary code ID2 associated with the combination ofimpedances 60 present on the electrical circuit, this binary code being derived for example from the output of the analogue/digital converter 80, or an identifier saved in a memory in the stent. The medical device may then be configured to only respond to the query by the querying unit if the comparison is positive. Advantageously, the identification may be carried out iteratively, the querying unit merely emitting one identification value at a time, each stent wherein the value corresponding of the identifier not corresponding being disabled—i.e., herein, not electrically powered—for a time suitable for identifying the only stent corresponding to the unique identifier and carrying out the measurements using different sensors in this medical device. -
FIG. 3 represents a second example of amedical system 100. This medical system is substantially identical to that described above. However, in this embodiment, in themeasurement circuit 16 of the implantablemedical device 12, the knownimpedances 60 and the sensors are mounted in series with theswitch 24 which is associated therewith, the sets formed of animpedance 60 or asensor 22 and aswitch 24 being mounted in parallel (or in derivation) with respect to one another. Hence, thecontrol modules 28 being identical to those described above, the electromagnetic field emitted following the creation of an induced current, corresponds to the sum of all theimpedances 60 and of all thesensors 22, minus one, each of theimpedances 60 and thesensors 22 being disconnected from the circuit, in this instance disconnected, successively. - Alternatively, obviously, it is possible to embody a
control module 28 having a different operation, which controls the closing of theswitch 24 during a time interval only, theswitch 24 being open the rest of the time. Such an operation may also be obtained by retaining thecontrol module 28 as described above and by replacing the depletion-mode MOS-FET transistors used asswitches 24 by enhancement-mode MOS-FET transistors. -
FIGS. 4 and 5 illustrate a further example of amedical system 200. According to this example, the control of theswitch 24 for disconnecting from the circuit thesensor 22 or a knownimpedance 60 is implanted directly in amodule 62 also comprising the knownimpedance 60 or thesensor 22, and theswitch 24, herein embodied by a transistor. As for the other examples described above, aresistor 40 and acapacitor 42 are used to control theswitch 24 such that it disconnects from the circuit theimpedance 60 or thesensor 22 except during a charging time interval of thecapacitor 42. Charging thecapacitor 42 activates thetransistor 66 of the next module, inducing the charging of the correspondingcapacitor 42. Once charged, thecapacitor 42 inhibits the associatedtransistor 24, triggering the disconnection from the circuit of theimpedance 60 or thesensor 22 which is connected thereto. - Herein, as represented in
FIG. 5 , eachmodule 62 is embodied as following: -
- the first and
second branches - a terminal of the
sensor 22 or of theimpedance 60 is connected to theground 48; - the other terminal of the
sensor 22 or of theimpedance 60 is connected to the drain of thetransistor 24; - the gate of the
second transistors 66 is connected to thesecond branch 46 of the precedingmodule 62; - the drain of the
second transistor 66 is connected to thefirst branch 44 of the preceding andnext modules 62; - the source of the
second transistor 66 is connected to the source of thetransistor 24 and to adiode 64; - the other terminal of the
diode 64, which is not connected to thetransistors impedance 40; - the other terminal of the
impedance 40, which is not connected to thediode 64, is connected to the gate of thetransistor 24, to a terminal of acapacitor 42, connected by the other terminal thereof to theground 48, and to thesecond branch 46 of thenext module 62.
- the first and
- As for the preceding examples, due to the configuration of the
modules 62, eachsensor 22 andimpedance 66 is successively connected to theantenna 18 in order to be powered, theother sensors 22 andimpedances 66 being for their part disconnected. - Finally,
FIG. 6 represents a fourth example of an embodiment of amedical system 300. Thismedical system 300 is distinguished from the preceding example 200, in that themeasurement circuit 16 is directly connected to theantenna 18 for the emission of an electromagnetic field, without the intermediary of a separate variable impedance (themeasurement circuit 16 itself having a variable impedance) and of a unit for controlling this variable impedance according to the impedance of themeasurement circuit 16. The electrical circuit on themedical device 12 is then particularly simplified. - Obviously, it is possible to conceive a structure where the
measurement circuit 16 is connected directly to the antenna, the implantable medical device also comprising a control circuit associated with this measurement circuit and as described for example with regard toFIGS. 2 and 3 . - In practice, in the embodiments described above, each module may particularly by embodied in the following form. Two measurement electrodes, for example of 60×60 μm2, made of an electrically conductive material, for example of polymer material or of metal alloy, preferably biocompatible, are deposited on an electrically insulating, biocompatible polymeric substrate (for example parylene). The electrical components of the control system and the switch are implanted in the polymeric substrate.
- The medical systems described above are suitable for carrying out a
querying method 500 of the implantablemedical device 12, as shown by the flow chart inFIG. 14 . - This
method 500 includes afirst step 502 consisting of powering themeasurement circuit 16. Preferably, this power supply is carried out by an induced current in an antenna or in the body of the implantablemedical device 12 when the latter is configured to generate an induced current. This makes it possible to power themeasurement circuit 16 only when a measurement is made. - The
method 500 is continued by astep 504 consisting of activating the system for controlling the implantable medical device so that it successively controls the opening of the closing of each of the switches of the implantable medical device, according to determined configurations. It should be noted herein that within the scope of the examples described with regard to the figures, this activation is carried out simultaneously with the power supply of themeasurement circuit 16, by induction, in response to the emission of an electromagnetic field by the querying device. Themethod 500 then includes astep 506 for identifying the queried medical device. This step may, alternatively, be carried out before electrically powering the measurement circuit. - The identification may be carried out either in the medical device per se, when the latter is provided with a comparator to compare an identification signal emitted by the querying unit with a unique identifier of the medical device. As indicated above, this identifier may take the form of a combination of known impedances in the medical device and/or in each measurement line of the medical device. The identification may be carried out iteratively, the querying unit merely emitting one digit of the identifier at a time, each of the medical devices wherein the identifier does not correspond to this digit being temporarily deactivated (i.e., in the example studied, not electrically powered).
- Alternatively, the identification is carried out in the processing unit, the signals emitted by the
antenna 18 being interpreted by the processing unit to determine the combination of the impedances of the medical device and/or of the measurement line queried. A processing unit may be used to determine the value measured by each sensor and the implantable medical device that responded to the query, particularly if the controlled configurations of the measurement circuit are more complex. - To do this, the processing unit may particularly be suitable for conducting Fourier analyses of the measured signals of electromagnetic fields emitted by the antenna of the implantable medical device, comparing the signals received (optionally processed) to previously measured signals and inferring therefrom the values measured by the various sensors of the implantable medical device, one location being suitable for being determined for each of the values measured.
- If the identification is negative, the medical device is temporarily deactivated, in the
step 508. - If the identification is positive, the
method 500 is continued then by astep 510 consisting of measuring the electromagnetic field emitted by the antenna of the implantable medical device. This measurement is made over a relatively long time so that the control system will have been able to control a relatively large number of different configurations of the measurement circuit so that the measurement makes it possible to determine the value measured by each of thesensors 22 of the implantablemedical device 12. Throughout the measurement step, theantenna 14 preferably emits a constant electromagnetic field to maintain the power supply of themeasurement circuit 16 and the activation of thecontrol system 26. - Preferably, each configuration corresponds to the scenario where all the sensors or impedances of the measurement circuit are disconnected from the circuit, except one. As such, on the basis of the electromagnetic field measured, it is possible to determine first of all the implantable medical device that responded to the query. Indeed, the first peaks measured in the electromagnetic field emitted by the antenna correspond to fixed impedances, the combination whereof makes it possible to identify the implantable medical device. These magnetic fields measured may also be suitable for calibrating the system since the magnetic fields measured correspond to known impedances of the measurement circuit. Finally, the subsequent magnetic fields make it possible to determine the values measured by each of the sensors distributed on the implantable medical device.
- When
elements 60A are envisaged between thesensors 22, the corresponding magnetic fields emitted may be used to calibrate the following and/or preceding emitted signal, which originates from a measurement by asensor 22. - Once all the
sensors 22 of themedical device 12 have been queried, the electrical power supply of the electrical circuit is switched off and the electrical circuit of themedical device 12 is deactivated. - It should be noted herein that the method described may be used with any type of variable-impedance sensor according to the physical quantity detected thereby. It should also be noted that the sensors distributed on the implantable medical device may be of different types, i.e. they may detect different physical quantities.
- The method described above may particularly be used to determine whether the implantable medical device is suitably implanted (i.e. positioned) in the natural cavity that it is supposed to keep open, in particular, if it is indeed in contact with the wall of the cavity. Indeed, the effect of a stent, for example but this is true for most implantable medical devices, is markedly reduced if the latter is not bearing on the wall of the cavity (particularly of the vein or the artery) wherein it is inserted.
- For example, by placing pressure sensors on the abluminal surface of the stent, i.e. on the surface opposite the lumen through the stent, that which is intended to be in contact with the wall of the cavity wherein the implantable medical device is received, the method described above makes it possible to determine whether each of these sensors is in contact with the wall, since it makes it possible to determine the pressure measured by each of the sensors. Obviously, this function for determining the suitable position of the stent may be combined, that is to say that sensors, for example of pressure, may be arranged on the abluminal surface of the stent and sensors, optionally of another physical quantity, may be arranged on the luminal surface of the stent.
- Alternatively, sensors of the same physical quantity are distributed on the abluminal surface and on the luminal surface, substantially at the same position on the stent or implantable medical device. In other words, sensors of the same physical quantity are arranged at the same point of the stent, on either side of the stent body. The comparison of the values measured by each of these stent pairs also makes it possible to obtain indications of an incorrect position of the stent in the cavity. In particular if the sensor on the abluminal surface, which should therefore be in contact with a wall, measures a substantially identical value to the sensor on the luminal surface, which is in contact with the blood, it is likely that the sensor on the abluminal surface is in fact in contact with blood also, not with a wall. It is therefore likely that the stent is poorly positioned in the cavity.
- Obviously, the method described above may be suitable for obtaining numerous other items of information.
- In particular, it may be suitable for determining whether a sensor arranged on the luminal or abluminal surface of the stent or, more generally, on a surface of an implantable medical device, particularly on a surface of the implantable medical device in contact with a wall of the cavity wherein the medical device is implanted or on a surface of the implantable medical device intended to be in contact with the blood, is optionally coated with endothelial or smooth muscle tissue.
- It may also be suitable for determining the composition of the tissue coating the sensors distributed on the implantable medical device (particularly on the luminal surface or on the abluminal surface of a stent) for example by Electrical Impedance Spectroscopy (EIS), particularly by applying currents of separate frequencies in the measurement circuit.
- The
electrical circuit 10A inFIG. 7 is an alternative embodiment of the circuit inFIG. 1 . - The
electrical circuit 10A firstly includes an analogue/digital converter 80 situated between theelectrical measurement circuit 16 and thevariable impedance 15 connected to theantenna 18 in the emitting circuit. This analogue/digital converter 80, which may also be used in theelectrical circuit 10 inFIG. 1 makes it possible to increase the range of signals which may be emitted by theantenna 18. Thisconverter 80 also makes it possible to enhance the signal-to-noise ratio of the measurements made. - Moreover, the
electrical circuit 10A is distinguished from that inFIG. 1 by the presence of anelement 60A of fixed and known impedance, for example a resistor, between thesensors 22. As for theimpedances 60, theelement 60A is associated with aswitch 24 controlled by acontrol module 28 in amodule 62A. The impedance of thiselement 60A is preferably chosen such that thesensors 22 cannot attain this impedance value. For example, the impedance of theelement 60A is less than 90% of the minimum impedance suitable for being attained bysensor 22 and/or greater than 110% of the maximum impedance suitable for being attained by asensor 22. As such, between two emitted signals relative to a measurement by asensor 22, a transition signal, easily identifiable, is emitted. It is easier, as such, to distinguish between two successive measurements, separated by a signal of expected form. Moreover, the presence of thiselement 60A between thesensors 22 may be suitable for calibrating the following and/or precedingsensor 22. The measurement is therefore more precise. Obviously, further configurations may be envisaged. In particular, it is possible to envisage anelement 60A at the start of a line only, all then sensors 22, n being a natural integer different to zero, or even an irregular distribution of theelements 60A on the measurement line. -
FIG. 8 represents analternative embodiment 100A of theelectrical circuit 100 inFIG. 3 , with an analogue/digital converter 80 andelements 60A of known and fixed impedance, such as theelectrical circuit 10A. The advantages of these modifications are the same as within the scope of theelectrical circuit 10A inFIG. 7 . - The same applies for the
electrical circuit 200A illustrated byFIGS. 9 and 10 and obtained by making the same modifications to theelectrical circuit 200 inFIGS. 4 and 5 . - It should be noted herein that the presence of the
elements 60A of known and fixed impedance and of the analogue/digital converter 80 are independent. Embodiments may be envisaged not involving one of the two among the analogue/digital converter 80 and theelements 60A of known impedance. - In
FIG. 11 , an electrical diagram of an alternativeelectrical circuit 10B of theelectrical circuit 10 inFIG. 1 has been represented. This electrical diagram 10B is distinguished from theelectrical circuit 10 inFIG. 1 in that it includes a plurality ofmeasurement lines 90, mounted in parallel, where theelectrical circuit 10 inFIG. 1 merely includes a single line. Herein, themeasurement lines 90 are identical to the single line represented inFIG. 1 . Themeasurement circuit 16 includes howeverline selectors 92, to carry out the measurement in each of the lines independently from theother lines 90, particularly each line in succession from one another. Theline selectors 92 may adopt a substantially identical form to thecontrol modules 28, thereby supplying eachline 90 with current, successively. - In the example shown, an analogue/
digital converter 80 is also provided between the parallel branches formed by themeasurement lines 90 and thevariable impedance 15. - The
electrical circuit 10C illustrated inFIG. 12 is similar to theelectrical circuit 10B inFIG. 11 . It is essentially distinguished by the presence of an analogue/digital converter 80 on each of themeasurement lines 90 in parallel. - It should be noted that it is also possible to envisage electrical circuits with a plurality of
measurement lines 90 on the basis of theelectrical circuits FIGS. 3 and 4 . - It is also possible to envisage
elements 60A of known and fixed impedance between each of the sensors on each of these lines or on certain lines only. It is then possible to identify the line wherein the measurement is made at each time by choosing unique combinations ofimpedances 60 at the start of theline 90 for eachline 90. - In the scenario where the
electrical circuit medical device 12, particularly on thestent 12 in imbricated coaxial helices. In other words, the measurement lines extends in parallel along helices wound around one another. Indeed, this makes it possible to minimise the distance between sensors of different lines. This is particularly advantageous because if asensor 22 of aline 90, or even theentire line 90 is defective, the missing value(s) may be better approximated by the values measured with the other measurement line(s), of which one or a plurality of sensors are situated in the vicinity. Thedevice 12 thereby gains in robustness, which is particularly advantageous when it is implanted in a patient's body. - It should be noted that the electrical circuits described are suitable for determining for each sensor of the electrical circuits, the value measured thereby. The position of the sensors on the medical device, particularly on the stent, being known, it is possible to determine a model representing in real time, the progression of the physical parameters measured on the medical device. As such, a practitioner may obtain real-time information. This information may particularly relate to the correct positioning of the medical device, particularly of the stent, in a cavity of the human body. Representing the pressures measured by pressure sensors arranged on the outer surface of the medical device, particularly of the stent, can enable the practitioner to determine whether this medical device is correctly implanted or not: a measured pressure that is too low, for example, may indicate that the stent is not in contact with the wall of the cavity receiving same.
- The processing unit of the medical system described above, comprising for example an electronic control unit and a screen, or a computer, may be suitable for determining a real-time model, for example a 3D model, based on the values measured and displaying the model on the screen. The values between the measurement points may, in this case, be approximated, particularly by convolution according to the distance to the closest measurement points.
- Various visual and/or acoustic signals may be emitted by the processing unit, in the scenario where at least one measured value does not meet expectations. The visual signals may particularly be suitable for identifying on the model shown, the
sensors 22 for which the measured values are not conforming. - Alternatively, the processing unit may process the digital values measured, compare them to expected value ranges and display as an output in a different manner, the points where the measurement is within the ranges and the points where the measurement is not within the ranges, for example by using different display colours.
- The visual signals complete the display of the model described above.
- The invention is not restricted solely to the examples of embodiments described above with regard to the figures, by way of illustrative and non-restrictive examples.
- In particular, the implantable medical device may be chosen from the group comprising:
-
- a heart valve,
- a cardiac stimulator,
- a cochlear implant,
- a throat implant,
- an orthopaedic implant,
- a brain implant,
- a retinal implant,
- a catheter, or
- a cellular tissue (“tissue-engineered construct”).
- Alternatively, the medical device may not be implantable. It can then, in particular, be applied on a part of the human body. The medical device may in this case take the form of a dressing, bandage or strip to be applied onto a patient's skin. The medical device may also take the form of a contact lens to be placed on a patient's cornea.
- Finally, according to a further alternative embodiment, the medical device may be neither implantable in the human body, not applicable thereon.
Claims (21)
1.-34. (canceled)
35. A stent, comprising:
a plurality of impedance sensors, wherein one or more of the plurality of impedance sensors are positioned on an abluminal surface of the stent; and
a communication circuit configured to communicate data regarding impedance from the stent to a computing device;
wherein the stent is configured to be implanted in a body of a patient.
36. The stent of claim 35 , wherein one or more of the plurality of impedance sensors are positioned on a luminal surface of the stent.
37. The stent of claim 35 , wherein:
the stent comprises a mesh; and
one or more of the plurality of impedance sensors are fixed to a vertex of the mesh.
38. The stent of claim 35 , wherein:
the stent comprises a mesh; and
one or more of the plurality of impedance sensors are fixed to a mid-point of a side of the mesh.
39. The stent of claim 35 , wherein:
a first group of the plurality of impedance sensors are positioned on the abluminal surface of the stent;
a second group of the plurality of impedance sensors are positioned on a luminal surface of the stent; and
the impedance sensors of the first group and the impedance sensors of the second group are disposed at opposite positions at common points along a body of the stent.
40. The stent of claim 35 , wherein:
the stent comprises a mesh, wherein the mesh comprises a plurality of struts;
the stent comprises a plurality of measurement lines, wherein each of the plurality of measurement lines comprises two or more of the plurality of impedance sensors; and
the plurality of measurement lines are woven between struts of the plurality of struts.
41. The stent of claim 35 , wherein:
the stent comprises a plurality of measurement lines, wherein each of the plurality of measurement lines comprises two or more of the plurality of impedance sensors; and
the plurality of measurement lines extend along the stent in imbricated helices.
42. The stent of claim 35 , further comprising:
an hyperplasia-limiting coating on one or more of the plurality of impedance sensors.
43. The stent of claim 35 , wherein:
the stent comprises an electronic measurement circuit, wherein the plurality of impedance sensors are connected to the electronic measurement circuit; and
the electronic measurement circuit is implanted in an electrically insulating and biocompatible polymeric substrate.
44. The stent of claim 35 , wherein:
the plurality of impedance sensors are arranged in series in a measurement line; and
each impedance sensor of the plurality of impedance sensors is associated with a respective switch of a plurality of switches, wherein each of the plurality of switches are configured to regulate power to a respective impedance sensor of the plurality of impedance sensors.
45. The stent of claim 35 , wherein:
the plurality of impedance sensors are arranged in a plurality of measurement lines;
a measurement line of the plurality of measurement lines comprises at least two impedance sensors arranged in series; and
each impedance sensor of the plurality of impedance sensors is associated with a respective switch of a plurality of switches to regulate power to each of the plurality of impedance sensors.
46. The stent of claim 35 , further comprising a plurality of control circuits arranged in series with respect to one another, wherein:
the plurality of impedance sensors are arranged in series in a plurality of measurement lines;
each impedance sensor of the plurality of impedance sensors is associated with a respective switch of a plurality of switches; and
each control circuit of the plurality of control circuits is configured to control one or more associated switches of the plurality of switches to regulate power to a respective impedance sensor of the plurality of impedance sensors.
47. A medical system, comprising:
an implantable medical device, comprising:
a measurement circuit comprising one or more impedance sensors; and
a power source; and
a computing device configured to communicate with the implantable medical device and receive data regarding impedance from the implantable medical device.
48. The system of claim 47 , wherein the implantable medical device further comprises:
an antenna to emit an electromagnetic field according to an impedance of the measurement circuit; and
an analogue/digital converter situated between the measurement circuit and the antenna.
49. The system of claim 47 , wherein the measurement circuit further comprises:
a resistor between two sensors of the one or more impedance sensors, wherein the resistor comprises a fixed impedance.
50. The system of claim 47 , wherein the implantable medical device further comprises:
a plurality of measurement circuits, each comprising a measurement line comprising one or more sensors, wherein the measurement lines are mounted in parallel; and
a plurality of line selectors, wherein each line selector of the plurality of line selectors is associated with a respective measurement line and configured to control current supply to the respective measurement line.
51. The system of claim 47 , wherein the computing device further comprises an antenna configured to emit an electromagnetic field to induce power in the measurement circuit.
52. The system of claim 47 , wherein the measurement circuit of the implantable medical device comprises at least one circuit to generate an electrical signal at a frequency, the electrical signal to be applied to anatomy contacted by the implantable medical device and to be received by an impedance sensor of the one or more impedance sensors.
53. A method of operating an implantable medical device, comprising:
successively controlling opening and closing of a plurality of switches of a measurement circuit, the measurement circuit comprising a plurality of sensors each associated with a respective switch of the plurality of switches, such that each of the respective switches are selectively electrically connected between a power source of the implantable medical device and an antenna of the implantable medical device; and
adjusting an electromagnetic field emitted by the antenna of the implanted medical device at a time to be indicative of a value measured at the time by a sensor of the plurality of sensors.
54. The method of claim 53 , further comprising at least one of:
with a comparator of the implantable medical device, comparing an identifier emitted by a computing device separate from the implantable medical device with a binary code associated with at least one fixed impedance of the implantable medical device; or
with a computing device separate from the implantable medical device, analyzing a portion of a signal emitted by the antenna of the implantable medical device to determine an identifier for the implantable medical device.
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JP2019517837A (en) | 2019-06-27 |
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