Closed loop impedance-based cardiac resynchronization therapy systems, devices, and methods
First Claim
1. A machine-assisted method comprising:
- measuring a first impedance signal, the first impedance signal being substantially indicative of a volume of a first ventricle of a heart as the first ventricle expands and contracts during a cardiac cycle of the heart;
measuring a second impedance signal, the second impedance signal being substantially indicative of a volume of a second ventricle, different from the first ventricle, as the second ventricle expands and contracts during the same cardiac cycle;
forming a function that parameterizes the first impedance signal as the function of the second impedance signal during the same cardiac cycle, the forming the first function includes forming a Lissajous function that parameterizes the first impedance signal as the function of the second impedance signal during the same cardiac cycle, the Lissajous function enclosing a loop area during the cardiac cycle; and
computing an indication of a degree of synchrony or asynchrony between the right and left ventricles using an indication of the loop area wherein computing the degree of synchrony or asynchrony includes;
computing a rectangular area defined by maximum and minimum impedances of each of the first and second ventricles during the cardiac cycle; and
computing a synchronization fraction by forming a difference of the rectangular area less the loop area, and dividing the difference by the rectangular area.
1 Assignment
0 Petitions
Accused Products
Abstract
This document discusses, among other things, systems, devices, and methods measure an impedance and, in response, adjust an atrioventricular (AV) delay or other cardiac resynchronization therapy (CRT) parameter that synchronizes left and right ventricular contractions. A first example uses parameterizes a first ventricular volume against a second ventricular volume during a cardiac cycle, using a loop area to create a synchronization fraction (SF). The CRT parameter is adjusted in closed-loop fashion to increase the SF. A second example measures a septal-freewall phase difference (PD), and adjusts a CRT parameter to decrease the PD. A third example measures a peak-to-peak volume or maximum rate of change in ventricular volume, and adjusts a CRT parameter to increase the peak-to-peak volume or maximum rate of change in the ventricular volume.
-
Citations
14 Claims
-
1. A machine-assisted method comprising:
-
measuring a first impedance signal, the first impedance signal being substantially indicative of a volume of a first ventricle of a heart as the first ventricle expands and contracts during a cardiac cycle of the heart; measuring a second impedance signal, the second impedance signal being substantially indicative of a volume of a second ventricle, different from the first ventricle, as the second ventricle expands and contracts during the same cardiac cycle; forming a function that parameterizes the first impedance signal as the function of the second impedance signal during the same cardiac cycle, the forming the first function includes forming a Lissajous function that parameterizes the first impedance signal as the function of the second impedance signal during the same cardiac cycle, the Lissajous function enclosing a loop area during the cardiac cycle; and computing an indication of a degree of synchrony or asynchrony between the right and left ventricles using an indication of the loop area wherein computing the degree of synchrony or asynchrony includes; computing a rectangular area defined by maximum and minimum impedances of each of the first and second ventricles during the cardiac cycle; and computing a synchronization fraction by forming a difference of the rectangular area less the loop area, and dividing the difference by the rectangular area. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
-
-
11. A machine-assisted method comprising:
-
measuring a first impedance signal of a first ventricle as the first ventricle expands and contracts during a cardiac cycle, the first impedance signal measured by delivering a current to the first ventricle and measuring a resulting voltage across a first electrode and a second electrode, the first and second electrodes located near opposing sides of the first ventricle; measuring a second impedance signal of a second ventricle, different from the first ventricle, as the second ventricle expands and contracts during the same cardiac cycle, the second impedance signal measured by delivering a current to the second ventricle and measuring a resulting voltage across a third electrode and a fourth electrode, the third and fourth electrodes located near opposing sides of the second ventricle; forming a Lissajous function that parameterizes the first impedance signal as the function of the second impedance signal during the same cardiac cycle, the Lissajous function enclosing a loop area during the cardiac cycle; and automatically adjusting a cardiac resynchronization therapy parameter that synchronizes left and right ventricular heart contractions, the automatically adjusting controlled in a feedback loop manner to decrease the loop area for at least one subsequent cardiac cycle wherein automatically adjusting the cardiac resynchronization therapy parameter to decrease the loop area includes decreasing the loop area relative to a rectangle defined by maximum and minimum impedances of each of the first and second ventricles during the cardiac cycle.
-
-
12. A system comprising:
-
a device comprising; an impedance measurement circuit, including terminals configured to be coupled to electrodes in association with a first ventricle of a heart to measure a first impedance signal that is substantially indicative of a volume of the first ventricle of the heart as the first ventricle expands and contracts during a cardiac cycle of the heart, and in association with a second ventricle of the heart to measure a second impedance signal that is substantially indicative of a volume of the second ventricle of the heart as the second ventricle expands and contracts during the same cardiac cycle of the heart; and a processor circuit, coupled to the impedance measurement circuit to receive information about the first and second impedance signals over the cardiac cycle, the processor performing instructions to form a function that parameterizes the first impedance signal as the function of the second impedance signal during the same cardiac cycle, the forming the first function includes forming a Lissajous function that parameterizes the first impedance signal as the function of the second impedance signal during the same cardiac cycle, the Lissajous function enclosing a loop area during the cardiac cycle, and to compute an indication of a degree of synchrony or asynchrony between the right and left ventricles using an indication of the loop area wherein the instructions performable to compute the degree of synchrony or asynchrony includes; computing a rectangular area defined by maximum and minimum impedances of each of the first and second ventricles during the cardiac cycle; and computing a synchronization fraction by forming a difference of the rectangular area less the loop area, and dividing the difference by the rectangular area. - View Dependent Claims (13, 14)
-
Specification