Rate-adaptive therapy with sensor cross-checking
First Claim
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1. A method for estimating a maximum exercise capacity in a patient, comprising:
- measuring exertion levels attained by the patient and determining a periodic maximum exertion level;
measuring activity levels and associating the periodic maximum exertion level with a simultaneously taken activity level measurement; and
, estimating the patient'"'"'s maximum exercise capacity by cross-checking the periodic maximum exertion level with the simultaneously taken activity level measurement.
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Abstract
A method and system for automatically adjusting the operating parameters of a rate-adaptive cardiac pacemaker in which maximum exertion levels attained by the patient are measured at periodic intervals and stored in order to compute or update a maximum exercise capacity. The slope of the rate-response curve is then adjusted to map an exertion level corresponding to the updated maximum exercise capacity to a maximum allowable pacing rate. In accordance with the invention, a maximum exercise capacity is determined by cross-checking periodic maximum exertion level sensor values with a motion-level sensor value.
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Citations
20 Claims
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1. A method for estimating a maximum exercise capacity in a patient, comprising:
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measuring exertion levels attained by the patient and determining a periodic maximum exertion level;
measuring activity levels and associating the periodic maximum exertion level with a simultaneously taken activity level measurement; and
,estimating the patient'"'"'s maximum exercise capacity by cross-checking the periodic maximum exertion level with the simultaneously taken activity level measurement. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 14, 15, 16, 17, 18)
delivering paces to the heart in accordance with a rate-adaptive pacing mode;
adjusting a pacing rate by mapping a measured exertion level to a target pacing rate with a rate response curve defined with respect to a maximum exercise capacity; and
,adjusting the slope of the rate response curve in order for the exertion level corresponding to the estimated maximum exercise capacity to be mapped to a specified maximum allowable pacing rate.
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3. The method of claim 1 wherein exertion levels are measured with a minute ventilation sensor, and activity levels are measured with an accelerometer.
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4. The method of claim 1 further comprising mapping an activity level to a percentage of reserve exercise capacity and performing the cross-checking by dividing the periodic maximum exertion level by the percentage of reserve exercise capacity mapped to by the activity level measurement.
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5. The method of claim 4 wherein activity level measurements are mapped to a percentages of reserve exercise capacity by a linear relationship.
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6. The method of claim 4 wherein activity level measurements are mapped to discrete percentages of reserve exercise capacity in accordance with threshold values of activity levels.
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7. The method of claim 6 wherein exertion levels are measured with a minute ventilation sensor, activity levels are measured with an accelerometer, and accelerometer measurements are mapped to percentages of minute ventilation reserve in accordance with accelerometer threshold values representing minute ventilation reserve percentages.
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8. The method of claim 7 wherein accelerometer measurements below a first threshold value of approximately 60 mg are mapped to 50% of minute ventilation reserve, accelerometer measurements above the first threshold and below a second threshold of approximately 100 mg are mapped to 75% of minute ventilation reserve, and accelerometer measurements above the second threshold are mapped to 100% of minute ventilation reserve.
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9. The method of claim 1 wherein the periodic maximum exertion level is a daily maximum exertion level.
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10. The method of claim 1 further comprising:
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determining a plurality of periodic maximum exertion levels;
cross-checking the plurality of periodic maximum exertion levels; and
,estimating the maximum exercise capacity as a maximum among the plurality of cross-checked periodic maximum exertion levels.
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14. The pacemaker of claim 10 wherein the processor is programmed to perform the cross-checking by mapping the activity level measurement to a percentage of the patient'"'"'s reserve exercise capacity and dividing the periodic maximum exertion level by the percentage of reserve exercise capacity mapped to by the activity level measurement.
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15. The pacemaker of claim 14 wherein the processor is programmed to map activity level measurements to percentages of reserve exercise capacity by a linear relationship.
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16. The pacemaker of claim 14 wherein the processor is programmed to map activity level measurements to discrete percentages of reserve exercise capacity in accordance with threshold values of activity levels.
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17. The pacemaker of claim 16 wherein the exertion level sensor is a minute ventilation sensor, and the activity level sensor is an accelerometer, and the processor is programmed such that accelerometer measurements are mapped to percentages of minute ventilation reserve in accordance with accelerometer threshold values representing minute ventilation reserve percentages.
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18. The pacemaker of claim 17 wherein accelerometer measurements below a first threshold value of approximately 60 mg are mapped to 50% of minute ventilation reserve, accelerometer measurements above the first threshold and below a second threshold of approximately 100 mg are mapped to 75% of minute ventilation reserve, and accelerometer measurements above the second threshold are mapped to 100% of minute ventilation reserve.
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11. A rate-adaptive pacemaker, comprising:
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sensing channels for sensing atrial and ventricular depolarization signals, each channel including an electrode and a sense amplifier;
a pulse generator for delivering pacing pulses to the atrium and/or ventricle;
an exertion level sensor for measuring exertion levels;
an activity level sensor for measuring activity levels; and
,a processor for controlling the delivery of pacing pulses, wherein the processor is programmed to;
adjust the rate at which paces are delivered by mapping a measured exertion level to a target pacing rate with a rate response curve defined with respect to a maximum exercise capacity, and estimate a patient'"'"'s maximum exercise capacity by determining a periodic maximum exertion level and cross-checking the periodic maximum exertion level with a simultaneously taken activity level measurement. - View Dependent Claims (12, 13, 19, 20)
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Specification
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Current AssigneeCardiac Pacemakers Incorporated (Boston Scientific Corporation)
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Original AssigneeCardiac Pacemakers Incorporated (Boston Scientific Corporation)
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InventorsLang, Douglas J., Sun, Weimin, Jones, Bruce R.
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Primary Examiner(s)Evanisko, George R.
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Assistant Examiner(s)Bradford, Roderick
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Application NumberUS09/638,975Time in Patent Office910 DaysField of Search607/17, 607/18, 607/19, 607/23, 607/24, 607/20US Class Current607/18CPC Class CodesA61N 1/36585 controlled by two or more p...
