Application of electrochemical impedance spectroscopy in sensor systems, devices, and related methods

What is claimed is: 1. A method for real-time detection of sensitivity loss for a working electrode of a sensor, the method comprising: receiving, at a microprocessor from the working electrode, multiple sets of impedance-related data for said working electrode, wherein an electrochemical impedance spectroscopy (EIS) procedure is performed to generate the multiple sets of impedance-related data for said working electrode, and wherein each of the multiple sets of impedance-related data includes data for at least one impedance-related parameter that is substantially glucose-independent; for each of said multiple sets of impedance-related data, calculating, by a microprocessor, respective values of 1 kHz imaginary impedance and relatively-higher frequency phase angle; monitoring, by said microprocessor, said respective values of the 1 kHz imaginary impedance and the relatively-higher frequency phase angle over time; determining, by said microprocessor, based on said monitoring of the respective values, that said working electrode is experiencing an oxygen deficiency-led loss of sensitivity when said respective values of relatively-higher frequency phase angle become more negative over time; based on the determination that the working electrode is experiencing an oxygen deficiency-led loss of sensitivity, determining, by the microprocessor, that said working electrode is not behaving normally; and based on said determination that the working electrode is not behaving normally, generating for presentation, by the sensor, an alert for a user of the sensor, the alert indicating that the sensor should be replaced. 2. The method of claim 1 , wherein each EIS procedure is performed for a predetermined range of frequencies. 3. The method of claim 1 , wherein the sensor includes a counter electrode, the method further comprising verifying said loss of sensitivity based on whether a voltage of the counter electrode rails. 4. The method of claim 1 , further including calculating, by said microprocessor, respective values of real impedance for each of said multiple sets of impedance-related data. 5. The method of claim 4 , wherein values are calculated for 0.1 kHz real impedance. 6. The method of claim 1 , wherein the sensor includes a plurality of redundant working electrodes, wherein EIS procedure is performed for each of the plurality of working electrodes to generate multiple sets of impedance-related data for each said working electrode, wherein said respective values of one or more impedance-related parameters are calculated for each said working electrode, and wherein said sensitivity-loss determination is made for each working electrode by comparing said respective values for at least one working electrode to said respective values for at least a second working electrode of the plurality of electrodes over time. 7. A sensor for real-time detection of sensitivity loss for a working electrode, the sensor comprising: storage circuitry to store an alert indicating that the sensor should be replaced; and a microprocessor that performs steps of: receiving, from the working electrode, multiple sets of impedance-related data for said working electrode, wherein an electrochemical impedance spectroscopy (EIS) procedure is performed to generate the multiple sets of impedance-related data for said working electrode, and wherein each of the multiple sets of impedance-related data includes data for at least one impedance-related parameter that is substantially glucose-independent; for each of said multiple sets of impedance-related data, calculating respective values of 1kHz imaginary impedance and relatively-higher frequency phase angle; monitoring said respective values of the 1 kHz imaginary impedance and the relatively-higher frequency phase angle over time; determining, based on said monitoring of the respective values, that said working electrode is experiencing an oxygen deficiency-led loss of sensitivity when said respective values of relatively-higher frequency phase angle become more negative over time; based on the determination that the working electrode is experiencing an oxygen deficiency-led loss of sensitivity, determining that said working electrode is not behaving normally; and based on said determination that the working electrode is not behaving normally, generating for presentation the alert for a user of the sensor. 8. The sensor of claim 7 , wherein each EIS procedure is performed for a predetermined range of frequencies. 9. The sensor of claim 7 , wherein the sensor further includes a counter electrode, the steps further comprising verifying said loss of sensitivity based on whether a voltage of the counter electrode rails. 10. The sensor of claim 7 , wherein the microprocessor further performs the steps of calculating respective values of real impedance for each of said multiple sets of impedance-related data. 11. The sensor of claim 10 , wherein values are calculated for 0.1 kHz real impedance. 12. The sensor of claim 7 , wherein the sensor further includes a plurality of redundant working electrodes, wherein said EIS procedure is performed for each of the plurality of working electrodes to generate multiple sets of impedance-related data for each said working electrode, wherein said respective values of one or more impedance-related parameters are calculated for each said working electrode, and wherein said sensitivity-loss determination is made for each working electrode by comparing said respective values for at least one working electrode to said respective values for at least a second working electrode of the plurality of electrodes over time. 13. A non-transitory, computer-readable medium having instructions that, when executed by one or more processors, cause operations comprising: receiving, at a microprocessor from a working electrode of a sensor, multiple sets of impedance-related data for said working electrode, wherein an electrochemical impedance spectroscopy (EIS) procedure is performed to generate the multiple sets of impedance-related data for said working electrode, and wherein each of the multiple sets of impedance-related data includes data for at least one impedance-related parameter that is substantially glucose-independent; for each of said multiple sets of impedance-related data, calculating, by a microprocessor, respective values of 1 kHz imaginary impedance and relatively-higher frequency phase angle; monitoring, by said microprocessor, said respective values of the 1 kHz imaginary impedance and the relatively-higher frequency phase angle over time; determining, by said microprocessor, based on said monitoring of the respective values, that said working electrode is experiencing an oxygen deficiency-led loss of sensitivity when said respective values of relatively-higher frequency phase angle become more negative over time; based on the determination that the working electrode is experiencing an oxygen deficiency-led loss of sensitivity, determining, by the microprocessor, that said working electrode is not behaving normally; and based on said determination that the working electrode is not behaving normally, generating an alert for presentation to a user of the sensor, the alert indicating that the sensor should be replaced. 14. The medium of claim 13 , wherein each EIS procedure is performed for a predetermined range of frequencies. 15. The medium of claim 13 , wherein the sensor further includes a counter electrode, the operations further comprising verifying said loss of sensitivity based on whether a voltage of the counter electrode rails. 16. The med