Passive physiological monitoring (P2M) system
First Claim
1. A method for passively monitoring physiology of a patient, the method comprising:
- engaging a first piezoelectric sensor with the patient by coupling the patient with a patient supporting surface including the first sensor;
engaging a second piezoelectric sensor in a location for sensing environmental noise, but not physiological signals from the patient;
engaging a third piezoelectric sensor with the patient, at a location remote from the first sensor;
sensing physiological signals and environmental noise with the first and third sensors and environmental noise with the second sensor;
isolating the physiological signals from the environmental noise by subtracting environmental noise sensed by the second sensor from the signals sensed by the first and third sensors;
comparing the physiological signals and environmental noise from the first sensor with the physiological signals and environmental noise from the third sensor to determine locations of the first and third sensors on the patient; and
displaying the physiological digital signals.
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Accused Products
Abstract
Passive Physiological monitoring apparatus and method have a sensor for sensing physiological phenomenon. A converter converts sensed data into electrical signals and a computer receives and computes the signals, and outputs computed data for real-time interactive display. The sensor is a piezoelectric film of polyvinylidene fluoride. A band-pass filter filters out noise and isolates the signals to reflect data from the body. A pre-amplifier amplifies signals. Signals detected include mechanical, thermal and acoustic signatures reflecting cardiac output, cardiac function, internal bleeding, respiratory, pulse, apnea, and temperature. A pad may incorporate the PVDF film and may be fluid-filled. The film converts mechanical energy into analog voltage signals. Analog signals are fed through the band-pass filter and the amplifier. A converter converts the analog signals to digital signals. A Fourier transform routine is used to transform into the frequency domain. A microcomputer is used for recording, analyzing and displaying data for on-line assessment and for providing realtime response. A radio-frequency filter may be connected to a cable and the film for transferring signals from the film through the cable. The sensor may be an array provided in a MEDEVAC litter or other device for measuring acoustic and hydraulic signals from the body of a patient for field monitoring, hospital monitoring, transport monitoring, home, remote monitoring.
272 Citations
33 Claims
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1. A method for passively monitoring physiology of a patient, the method comprising:
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engaging a first piezoelectric sensor with the patient by coupling the patient with a patient supporting surface including the first sensor; engaging a second piezoelectric sensor in a location for sensing environmental noise, but not physiological signals from the patient; engaging a third piezoelectric sensor with the patient, at a location remote from the first sensor; sensing physiological signals and environmental noise with the first and third sensors and environmental noise with the second sensor; isolating the physiological signals from the environmental noise by subtracting environmental noise sensed by the second sensor from the signals sensed by the first and third sensors; comparing the physiological signals and environmental noise from the first sensor with the physiological signals and environmental noise from the third sensor to determine locations of the first and third sensors on the patient; and displaying the physiological digital signals.
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2. A method for passively monitoring the physiology of a patient in an environment, comprising:
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coupling a first sensor with the patient; coupling a second sensor with the patient at a location remote from the first sensor; sensing physiological parameters of the patient and conditions of the environment around the patient with both the first and second sensors; converting the sensed physiological parameters and environment conditions into signals; correlating the signals from the first and second sensors; and using the correlation to extract signals associated with the physiology of the patient; calculating an energy spectrum from the signals; and extracting signals associated with the physiology of the patient by identifying peaks in the energy spectrum corresponding to physiological parameters of the patient. - View Dependent Claims (3, 4, 5, 6, 7, 8, 9, 10)
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11. Apparatus suitable for passively monitoring the physiology of a patient in a vibration environment, comprising:
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at least two sensors, each of said sensors being capable of passively sensing physiological parameters of a patient at a different location on the patient'"'"'s body and vibration from an environment around the patient; a converter communicating with the sensors for converting the sensed physiological parameters and environmental vibration into digital signals; and a processor communicating with the converter for processing the digital signals to extract signals associated with the physiology of the patient by correlating signals between sensors; wherein the processor further calculates an energy spectrum from the digital signals and extracts signals associated with the physiology of the patient by identifying peaks in the energy spectrum corresponding to selected physiological parameters. - View Dependent Claims (12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24)
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25. Apparatus for passively monitoring the physiology of a patient, comprising:
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a plurality of sensors for sensing mechanical activity at a plurality of different locations on the patient'"'"'s body; a converter communicating with the sensors for converting the sensed mechanical activity into a plurality of digital signals; and a processor communicating with the converter for extracting signals due to cardiac activity of the patient by selectively comparing the digital signals from said different locations on the patient'"'"'s body; wherein the processor further transforms the digital signals into frequency signals including respiration and heart rate harmonics, and differentiates respiration and heart rate harmonics by selectively comparing signals from said different locations on the patient'"'"'s body. - View Dependent Claims (26, 27)
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28. A method for passively monitoring the physiology of a patient, comprising:
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coupling a plurality of sensors with the patient at different locations on the patient'"'"'s body; sensing mechanical activity of the patient at each of said locations; converting the sensed mechanical activity into a plurality of signals; extracting signals associated with cardiac activity of the patient by selectively comparing the signals from said different locations on the patient'"'"'s body; and transforming the signals into frequency signals including respiration and heart rate harmonics, and differentiating respiration and heart rate harmonics by selectively comparing signals from different locations on the patient'"'"'s body.
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29. Apparatus for passively monitoring the physiology of a patient, comprising:
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at least two sensors, each sensor comprising a polarized polymer film with piezoelectric properties, for sensing physiological parameters of the patient at different parts of the patient'"'"'s body; a converter communicating with the sensors for converting the sensed physiological parameters into digital signals; and a processor communicating with the converter for determining pulse wave velocity in response to the time difference between corresponding signals from the sensors and for converting the pulse wave velocity into signals corresponding to blood pressure data; wherein the at least two sensors comprise a first sensor disposed at a first location along a patient supporting surface and a second sensor disposed at a second location along the patient supporting surface remote from the first location. - View Dependent Claims (30)
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31. Apparatus for passively monitoring the physiology of a patient, comprising:
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at least two sensors, each sensor comprising a polarized polymer film with piezoelectric properties, for sensing physiological parameters of the patient at different parts of the patient'"'"'s body; a converter communicating with the sensors for converting the sensed physiological parameters into digital signals; and a processor communicating with the converter for determining pulse wave travel time in response to the time difference between corresponding signals from the sensors and for converting the pulse wave travel time into signals corresponding to blood pressure data; wherein the at least two sensors comprise a first sensor disposed at a first location along a patient supporting surface and a second sensor disposed at a second location along the patient supporting surface remote from the first location. - View Dependent Claims (32)
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33. A method for passively monitoring the physiology of a patient, comprising:
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coupling a first sensor with the patient; coupling a second sensor with the patient at a location remote from the first sensor; sensing physiological signals and environmental noise and vibration with the first and second sensors; comparing the physiological signals and environmental noise and vibration from the first sensor with the physiological signals and environmental noise and vibration from the second sensor to determine locations of the first and second sensors on the patient; and isolating selected physiological signals from the environmental and noise vibration.
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Specification