Body-worn pulse oximeter
First Claim
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1. A system for monitoring a patient, comprising:
- an oximetry sensor comprising a photodetector and a first light source and a second light source, the photodetector configured to generate a first signal by detecting a first radiation emitted by the first light source after the first radiation irradiates the patient, and a second signal by detecting a second radiation emitted by the second light source after the second radiation irradiates the patient;
an ECG system comprising a housing configured to be positioned on the patient'"'"'s chest, a differential amplifier circuit within the housing configured to operably connect to at least two electrodes and to generate therefrom an ECG signal, and a first motion sensor within the housing configured to generate therefrom a first motion signal;
an oscillometric blood pressure monitoring system comprising a pump and a cuff, the oscillometric blood pressure monitoring system configured to be positioned on the patient'"'"'s upper arm and to generate therefrom an oscillometric blood pressure signal;
a second motion sensor configured to be positioned on the patient'"'"'s arm above the elbow and to generate therefrom a second motion signal;
a third motion sensor configured to be positioned on the patient'"'"'s arm at the wrist and to generate therefrom a third motion signal;
a processing unit configured to be worn on the patient'"'"'s body and operably connected to the oximetry sensor and configured to receive therefrom the first and second signals, to the ECG system and configured to receive therefrom the ECG signal and the first motion signal, to the oscillometric blood pressure monitoring system and configured to receive therefrom the oscillometric blood pressure signal, to the second motion sensor and configured to receive therefrom the second motion signal, and to the third motion sensor and configured to receive therefrom the third motion signal,the processing unit comprising a processor configured to process;
i) the first and second signals to determine a value for oxygen saturation;
ii) the second and third motion signals to determine a blood pressure calibration value compensating for hydrostatic forces due to arm height;
iii) the first motion signal to determine the patient'"'"'s torso orientation with respect to gravity;
iv) the ECG signal, oscillometric blood pressure signal, and at least one of the first and second signals to determine a patient specific relationship between mean arterial blood pressure and pulse transit time; and
v) the blood pressure calibration value, the patient'"'"'s torso orientation, the patient specific relationship, the ECG signal, and at least one of the first and second signals to determine a blood pressure measurement for the patient.
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Abstract
The invention provides a body-worn system that continuously measures pulse oximetry and blood pressure, along with motion, posture, and activity level, from an ambulatory patient. The system features an oximetry probe that comfortably clips to the base of the patient'"'"'s thumb, thereby freeing up their fingers for conventional activities in a hospital, such as reading and eating. The probe secures to the thumb and measures time-dependent signals corresponding to LEDs operating near 660 and 905 nm. Analog versions of these signals pass through a low-profile cable to a wrist-worn transceiver that encloses a processing unit. Also within the wrist-worn transceiver is an accelerometer, a wireless system that sends information through a network to a remote receiver, e.g. a computer located in a central nursing station.
20 Citations
10 Claims
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1. A system for monitoring a patient, comprising:
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an oximetry sensor comprising a photodetector and a first light source and a second light source, the photodetector configured to generate a first signal by detecting a first radiation emitted by the first light source after the first radiation irradiates the patient, and a second signal by detecting a second radiation emitted by the second light source after the second radiation irradiates the patient; an ECG system comprising a housing configured to be positioned on the patient'"'"'s chest, a differential amplifier circuit within the housing configured to operably connect to at least two electrodes and to generate therefrom an ECG signal, and a first motion sensor within the housing configured to generate therefrom a first motion signal; an oscillometric blood pressure monitoring system comprising a pump and a cuff, the oscillometric blood pressure monitoring system configured to be positioned on the patient'"'"'s upper arm and to generate therefrom an oscillometric blood pressure signal; a second motion sensor configured to be positioned on the patient'"'"'s arm above the elbow and to generate therefrom a second motion signal; a third motion sensor configured to be positioned on the patient'"'"'s arm at the wrist and to generate therefrom a third motion signal; a processing unit configured to be worn on the patient'"'"'s body and operably connected to the oximetry sensor and configured to receive therefrom the first and second signals, to the ECG system and configured to receive therefrom the ECG signal and the first motion signal, to the oscillometric blood pressure monitoring system and configured to receive therefrom the oscillometric blood pressure signal, to the second motion sensor and configured to receive therefrom the second motion signal, and to the third motion sensor and configured to receive therefrom the third motion signal, the processing unit comprising a processor configured to process;
i) the first and second signals to determine a value for oxygen saturation;
ii) the second and third motion signals to determine a blood pressure calibration value compensating for hydrostatic forces due to arm height;
iii) the first motion signal to determine the patient'"'"'s torso orientation with respect to gravity;
iv) the ECG signal, oscillometric blood pressure signal, and at least one of the first and second signals to determine a patient specific relationship between mean arterial blood pressure and pulse transit time; and
v) the blood pressure calibration value, the patient'"'"'s torso orientation, the patient specific relationship, the ECG signal, and at least one of the first and second signals to determine a blood pressure measurement for the patient. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
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Specification
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Current AssigneeSotera Wireless Incorporated
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Original AssigneeSotera Wireless Incorporated
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InventorsMoon, Jim, McCombie, Devin, Dhillon, Marshal, Banet, Matt
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Primary Examiner(s)Winakur, Eric
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Assistant Examiner(s)Liu, Chu Chuan (JJ)
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Application NumberUS14/092,173Publication NumberTime in Patent Office1,770 DaysField of Search600310, 600322, 600323, 600324, 600333, 600334, 600340, 600473, 600476, 600500, 600503, 600508, 600509, 356 41US Class CurrentCPC Class CodesA61B 5/021 Measuring pressure in heart...A61B 5/02125 of pulse wave propagation timeA61B 5/022 by applying pressure to clo...A61B 5/02225 using the oscillometric methodA61B 5/0245 by using sensing means gene...A61B 5/1116 Determining posture transit...A61B 5/1118 Determining activity levelA61B 5/14551 for measuring blood gasesA61B 5/14552 Details of sensors speciall...A61B 5/349 Detecting specific paramete...A61B 5/681 Wristwatch-type devicesA61B 5/6824 Arm or wristA61B 5/6826 FingerA61B 5/6838 Clamps or clipsA61B 5/721 using a separate sensor to ...A61B 5/7239 using differentiation inclu...A61B 5/746 Alarms related to a physiol...
