Systems and methods for compensating long term sensitivity drift of electrochemical gas sensors exposed to nitric oxide

What is claimed: 1. A method for compensating nitric oxide sensor drift affiliated with therapeutic gas delivery, comprising: delivering, via a flow control valve affiliated with a therapeutic gas delivery system, a predetermined dosage of therapeutic gas comprising nitric oxide to a breathing circuit for delivery to a patient; detecting, via a system controller affiliated with the therapeutic gas delivery system, if an alarm is active or has been active within a predetermined timeframe at a time a nitric oxide sensor calibration is to be executed according to an identified sensor calibration schedule stored in a system controller memory, wherein the nitric oxide sensor calibration is postponed if the active alarm is detected or has been detected within the predetermined timeframe, and the nitric oxide sensor calibration is executed when the active alarm is not detected or has not been detected within the predetermined timeframe, wherein the nitric oxide sensor calibration schedule is modified based upon a change in the predetermined dosage of nitric oxide being delivered to the patient, and wherein the change in the predetermined dosage is an increase in the predetermined dosage, the nitric oxide sensor calibration occurs with a greater frequency; continuously monitoring, via the nitric oxide sensor affiliated with the therapeutic gas delivery system, a signal indicative of a concentration of nitric oxide in the breathing circuit; and determining a compensated response to the signal indicative of the nitric oxide concentration in the breathing circuit after the nitric oxide sensor calibration occurs. 2. The method of claim 1 , further comprising: retrieving a baseline calibration value, the baseline calibration value corresponding to a known output concentration of therapeutic gas at a specified output current; and retrieving a slope associated with the baseline calibration value, the slope corresponding to a correlation between measured output current at specific output concentrations; the method further comprising utilizing the previous value of the slope to determine a set of correlated values between voltages and nitric oxide. 3. The method of claim 2 , wherein determining a compensated response further comprises: storing, in memory affiliated with the therapeutic gas delivery system, expected signals from the nitric oxide sensor correlated to nitric oxide concentrations in the breathing circuit; determining, via the system controller affiliated with the therapeutic gas delivery system, signal drift between (i) a signal received from the nitric oxide sensor during the nitric oxide calibration indicative of zero concentration nitric oxide and (ii) an expected signal, stored in memory affiliated with the therapeutic gas delivery system, from the nitric oxide sensor when exposed to zero concentration nitric oxide; and offsetting the expected signals from the nitric oxide sensor correlated to nitric oxide concentrations in the breathing circuit by the determined signal drift of the nitric oxide sensor. 4. The method of claim 3 , further comprising postponing the execution of the nitric oxide sensor calibration by a predetermined time period if (i) the presence of interfering gas is detected and/or (ii) if a user is interacting with or has interacted with the therapeutic gas delivery system within a predetermined timeframe at the time the nitric oxide sensor calibration is intended to be executed. 5. The method of claim 2 , wherein the calibration includes: interrupting the continuous monitoring of the signal indicative of nitric oxide concentration according to the identified sensor calibration schedule; exposing the nitric oxide sensor to a gas having a zero concentration of nitric oxide for a period of time sufficient to detect the output signal indicative of the zero concentration; and determining the response by the nitric oxide sensor to the gas having a zero concentration of nitric oxide. 6. The method of claim 5 , wherein the identified sensor calibration schedule comprises a set of signals representing intended intervals between interruptions of the continuous monitoring of the signal indicative of nitric oxide concentration. 7. The method of claim 6 , wherein the intended intervals are larger for a smaller change in the setting in the system controller. 8. The method of claim 5 , further comprising: storing the signal, received from the nitric oxide sensor during the nitric oxide calibration indicative of zero concentration of nitric oxide, in the system controller memory affiliated with the therapeutic gas delivery system. 9. The method of claim 8 , further comprising: accessing a slope of a previous calibration line stored in the memory affiliated with the therapeutic gas delivery system, and generating a new calibration line using the stored signal received from the nitric oxide sensor during the nitric oxide calibration indicative of zero concentration nitric oxide and the slope of a previous calibration line. 10. The method of claim 5 , further comprising postponing the execution of the nitric oxide sensor calibration by a predetermined time period if (i) the presence of interfering gas is detected and/or (ii) if a user is interacting with or has interacted with the therapeutic gas delivery system within a predetermined timeframe at the time the nitric oxide sensor calibration is intended to be executed. 11. The method of claim 5 , further comprising: communicating to a user when (i) monitoring the concentration of nitric oxide in the breathing circuit with the nitric oxide sensor is interrupted and/or (ii) performing the nitric oxide sensor calibration. 12. The method of claim 5 wherein the nitric oxide sensor is a first nitric oxide sensor, further comprising: monitoring the concentration of nitric oxide in the breathing circuit with a second nitric oxide sensor when monitoring the concentration of nitric oxide in the breathing circuit with the first nitric oxide sensor is interrupted, whereby communication of the nitric oxide concentration to a user during calibration is enabled. 13. The method of claim 12 , further comprising exposing the second nitric oxide sensor to the gas having a zero concentration of nitric oxide for the period of time sufficient to de-saturate and/or detect the output signal indicative of the zero concentration after exposing the first nitric oxide sensor to the gas having a zero concentration of nitric oxide for the period of time sufficient to de-saturate and/or detect the output value indicative of the zero concentration; and comparing the signal from the second nitric oxide sensor to the signal of the first nitric oxide sensor to determine the difference in drift between the first nitric oxide sensor and the second nitric oxide sensor. 14. The method of claim 1 , further comprising: identifying the type of nitric oxide sensor continuously monitoring the signal indicative of the concentration of nitric oxide in the breathing circuit; storing the type of nitric oxide sensor in the memory affiliated with the therapeutic gas delivery system; and utilizing the type of nitric oxide sensor in identifying the sensor calibration schedule. 15. The method of claim 14 , wherein the nitric oxide sensor is a three terminal electrochemical nitric oxide gas sensor or a four terminal electrochemical nitric oxide gas sensor. 16. The method of claim 15 , further comprising: exposing the nitric oxide sensor to ambient air when interrupting the continuous monitoring of the signal indicative of the concentration of nitric oxide in the breathing c