Method and apparatus for determination of physiological parameters using cervical impedance

The claimed invention is: 1. An apparatus, comprising: an electrode configured to be extravascularly implanted, the extravascularly-implanted electrode adapted for encircling extravascular nerve tissue near a blood vessel without encircling the blood vessel; an electrical energy delivery circuit configured to be coupled to the extravascularly-implanted electrode and configured to: provide an electrical test signal directed from the extravascularly-implanted electrode to a location internal to a patient body and near the blood vessel when the electrode encircles the extravascular nerve tissue without encircling the blood vessel; and provide an electrostimulation signal directed from the extravascularly-implanted electrode toward the extravascular nerve tissue when the electrode encircles the extravascular nerve tissue without encircling the blood vessel; a detector circuit configured to receive an electrical response signal in response to the electrical test signal; and a signal processor circuit, coupled to the electrical energy delivery circuit and the detector circuit, the signal processor circuit configured to: determine a vessel dimension of the blood vessel near the extravascularly-implanted electrode using the received electrical response signal; compare the determined vessel dimension to a reference vessel dimension to determine a vessel dimension change; and output an indication of the determined vessel dimension change. 2. The apparatus of claim 1 , wherein the electrical energy delivery circuit is configured to provide the electrical test signal to the extravascular nerve tissue, wherein the extravascular nerve tissue includes a vagus nerve in a cervical region near the blood vessel including a carotid artery. 3. The apparatus of claim 2 , wherein the electrical energy delivery circuit is configured to provide the electrical test signal as a non-neurostimulating electrical test signal. 4. The apparatus of claim 2 , wherein the electrical energy delivery circuit is configured to provide a series of non-neurostimulating electrical test signals; wherein the detector circuit is configured to receive a corresponding series of electrical response signals in response to the series of non-neurostimulating electrical test signals; and wherein the signal processor circuit is configured to determine the vessel dimension change of the blood vessel near the extravascularly-implanted electrode using the series of received electrical response signals. 5. The apparatus of claim 1 , further comprising an electrode; wherein the electrical energy delivery circuit is configured to provide a neurostimulating therapy signal to the electrode; and wherein the electrical energy delivery circuit is further configured to provide a non-neurostimulating test signal to the same electrode. 6. The apparatus of claim 1 , wherein the electrical energy delivery circuit is configured to provide a neurostimulating therapy signal directed from the extravascularly-implanted electrode toward a vagus nerve; and wherein the electrical energy delivery circuit is configured to provide the electrical test signal as a portion of the neurostimulating therapy signal. 7. The apparatus of claim 1 , wherein the electrical energy delivery circuit is configured to provide a signal waveform comprising a first neurostimulating therapy signal pulse phase and a second non-neurostimulating signal pulse phase incapable of stimulating the nerve tissue. 8. The apparatus of claim 1 , wherein the signal processor circuit is further configured to: determine a pulse transit time using information about the vessel dimension change; and output information about a patient health status using the pulse transit time. 9. The apparatus of claim 8 , wherein the signal processor circuit is further configured to: trend the pulse transit time over multiple cardiac cycles; and output the information about a patient health status using information about the trended pulse transit time. 10. The apparatus of claim 1 , wherein the signal processor circuit is further configured to: determine a relative pulse pressure using information about the vessel dimension change; and output information about a patient health status using the relative pulse pressure. 11. The apparatus of claim 10 , wherein the signal processor circuit is further configured to: trend the relative pulse pressure over multiple cardiac cycles; and output the information about a patient health status using information about the trended relative pulse pressure. 12. The apparatus of claim 1 , wherein the signal processor circuit is further configured to determine at least one of an arterial compliance, an autonomic status, a cardiac contractility, a pulmonary vein distension, a respiratory effort, a respiratory disturbance, or a fluid status using the determined change in the vessel dimension; and output information about a patient health status using the at least one of an arterial compliance, an autonomic status, a cardiac contractility, a pulmonary vein distension, a respiratory effort, a respiratory disturbance, or a fluid status. 13. The apparatus of claim 1 , wherein the signal processor circuit is configured to determine a radial vessel dimension change of the blood vessel. 14. The apparatus of claim 1 , wherein the electrical energy delivery circuit is configured to provide the electrical test signal in response to a signal provided by a physiological sensor comprising at least one of: a posture sensor; a heart rate sensor; a respiration rate sensor; a respiratory phase sensor; a patient physical activity level sensor; or an arrhythmia sensor. 15. The apparatus of claim 1 , wherein the signal processor circuit is configured to provide the output indication in response to a signal provided by a physiological sensor comprising at least one of: a posture sensor; a heart rate sensor; a respiration rate sensor; a respiratory phase sensor; a patient physical activity level sensor; or an arrhythmia sensor. 16. A method of using an extravascularly-implanted electrode positioned at an extravascular nerve tissue, the method comprising: providing an electrical test signal directed from the extravascularly-implanted electrode to a location internal to a patient body and near a blood vessel, the extravascularly-implanted electrode encircling the extravascular nerve tissue without encircling the blood vessel; receiving an electrical response signal in response to the electrical test signal; measuring, using a processor circuit, a vessel dimension of the blood vessel near the extravascularly-implanted electrode using the received electrical response signal; comparing, using a processor circuit, the measured vessel dimension to a reference vessel dimension to determine a vessel dimension change; outputting an indication of the determined vessel dimension change; and providing an electrostimulation signal directed from the extravascularly-implanted electrode toward the extravascular nerve tissue. 17. The method of claim 16 , wherein the providing the electrical test signal includes providing the electrical test signal to the extravascular nerve tissue, wherein the extravascular nerve tissue includes a vagus nerve in a cervical region near the blood vessel including a carotid artery. 18. The method of claim 16 , further comprising: providing a neurostimulating therapy signal directed from the extravascularly-implanted electrode to a vagus nerve; and providing the electrical test signal as a portion of the