Abstract: A system is described that continuously measures a patient's blood pressure over a length of time. The system features a sensor assembly featuring a flexible cable configured to wrap around a portion of a patient's arm. The flexible cable features a back surface that includes at least two electrodes that are positioned to contact the patient's skin to generate electrical signals. It additionally features an optical sensor that includes at least one light source and at least one photodetector. These components form an optical sensor that is configured to generate an optical signal by detecting optical radiation emitted by the at least one light source and reflected from a blood vessel underneath the patient's skin.

Abstract: A sensor for monitoring a patient's blood pressure, the sensor including a housing unit with a back surface and which includes: a pair of electrodes mounted on the back surface; an optical system mounted on the back surface and including at least one light source that emits optical radiation near 570 nm and at least one photodetector; a first amplifier which generates an analog electrical waveform from the electrical signals from the electrodes; a second amplifier that generates an analog optical waveform from the optical signal from the photodetector; analog-to-digital converter circuitry configured to receive the analog electrical waveform and generate a digital electrical waveform therefrom and to receive the analog optical waveform and generate a digital optical waveform therefrom; and a processor programmed to receive the digital electrical and optical waveforms and determine a pulse transit time for the patient which is a measure of a separation in time of a first feature of the digital electrical wavef

Abstract: A receiver (100) adjusts its overall gain based on the detected power level of an incoming signal. The receiver is built with two detectors (D1, D2) which operate with different detecting ranges within the dynamic range of the incoming signal. If the actual power level of the incoming signal falls within one of the resolving ranges, an automatic gain control adjusts the gain of the receiver to a corresponding gain value. If not, the resolving range of one of the two detectors is shifted and eventually reduced to cover the portion of the dynamic range in which the power level is comprised. The gain of the receiver is then temporarily adjusted and a new measurement is carried out by the detector using the new resolving range. The AGC then re-adjusts the gain of the receiver based on the measurement given by the modified detector.

Abstract: The invention provides a method for measuring a patient's blood pressure featuring the following steps: 1) measuring a first time-dependent optical signal with a first optical sensor; 2) measuring a second time-dependent optical signal with a second optical sensor; 3) measuring a time-dependent electrical signal with an electrical sensor; 4) estimating the patient's arterial properties using either the first or second time-dependent optical signal; 5) determining a pulse transit time (PTT) from the time-dependent electrical signal and at least one of the first and second time-dependent optical signals; and 6) calculating a blood pressure value using a mathematical model that includes the PTT and the patient's arterial properties.

Abstract: The invention features a vital sign monitor that includes: 1) a sensor component that attaches to the patient and features an optical sensor and an electrical sensor that measure, respectively a first and second signal: and 2) a control component. The control component features: 1) an analog-to-digital converter configured to convert the first signal and second signal into, respectively, a first digital signal and a second digital signal; 2) a CPU configured to operate an algorithm that generates a blood pressure value by processing with an algorithm the first digital signal and second digital signal; 3) a display element; 4) a graphical user interface generated by computer code operating on the CPU and configured to render on the display element the blood pressure value; and 5) a software component that renders video images on the display element. To capture video and audio information, the device further includes both a digital camera and a microphone.

Abstract: The invention features a vital sign monitor that includes: 1) a hardware control component featuring a microprocessor that operates an interactive, icon-driven GUI on an LCD; and, 2) a sensor component that connects to the control component through a shielded coaxial cable. The sensor features: 1) an optical component that generates a first signal; 2) a plurality electrical components (e.g. electrodes) that generate a second signal; and, 3) an acoustic component that generates a third signal. The microprocessor runs compiled computer code that operates: 1) the touch panel LCD; 2) a graphical user interface that includes multiple icons corresponding to different software operations; 3) a file-management system for storing and retrieving vital sign information; and 4) USB and short-range wireless systems for transferring data to and from the device to a PC.

Abstract: The invention provides system for measuring vital signs from multiple patients, typically in an in-hospital setting. The system features a body-worn vital sign monitor that includes: i) a sensor configured as a patch that measures electrical and optical signals from a patient; ii) a controller featuring a microprocessor that receives and processes the electrical and optical signals to determine the patient's vital sign information, including blood pressure; and iii) a first short-range wireless component that wirelessly transmits a packet comprising the vital sign information to an external receiver. A portable, wireless computer (e.g., a PDA, cellular telephone, or a laptop computer) communicates with the body-worn module. The wireless computer includes: i) a second short-range wireless component that receives the vital sign information and displays it; and ii) a long-range wireless transmitter that transmits the vital sign information over a wireless network.

Abstract: The invention features a monitoring device that measures a patient's vital signs (e.g. blood pressure). The device features a first sensor configured to attach to a first portion of the patient's body that includes: i) a first electrode configured to generate a first electrical signal from the first portion of the patient's body; ii) a first light-emitting component; and iii) a first photodetector configured to receive radiation from the first portion of the patient's body after the radiation is emitted by the first light-emitting component and in response generate a first optical waveform. The device also features a second sensor that includes essentially the same components. An amplifier system, in electrical contact with the first and second electrodes, receives first and second electrical signals from the two sensors to generate an electrical waveform.

Abstract: The invention features a monitoring device that measures a patient's vital signs (e.g. blood pressure). The device features a first sensor configured to attach to a first portion of the patient's body that includes: i) a first electrode configured to generate a first electrical signal from the first portion of the patient's body; ii) a first light-emitting component; and iii) a first photodetector configured to receive radiation from the first portion of the patient's body after the radiation is emitted by the first light-emitting component and in response generate a first optical waveform. The device also features a second sensor that includes essentially the same components. An amplifier system, in electrical contact with the first and second electrodes, receives first and second electrical signals from the two sensors to generate an electrical waveform.

Abstract: The invention provides a monitor for measuring blood pressure and other vital signs from a patient without using a cuff. The invention provides a hand-held device for measuring vital signs (e.g.

Abstract: The invention provides a system for monitoring a patient that includes: 1) a blood test that measures an Apo E genotype or a derivative thereof from the patient to generate Apo B information; 2) a database that receives and stores the patient's Apo E information; and 3) an Internet-based system connected to the database and configured to process the Apo E information with an algorithm that, in response, generates a diet and treatment plan for the patient.

Abstract: A monitoring device, method and system are disclosed herein. The monitoring device is capable of determine when a user's wrist is at rest using a motion sensor disposed within a wrist module that is attached to the user's wrist. When at rest, the monitoring device utilizes a vital sign monitor to determine a plurality of vital signs of the user. The vital sign monitor preferably comprises a light source and photodetector in communication with a pulse-oximetry circuit. The motion sensor is preferably an accelerometer.

Abstract: A receiver (100) adjusts its overall gain based on the detected power level of an incoming signal. The receiver is built with two detectors (D1, D2) which operate with different detecting ranges within the dynamic range of the incoming signal. If the actual power level of the incoming signal falls within one of the resolving ranges, an automatic gain control adjusts the gain of the receiver to a corresponding gain value. If not, the resolving range of one of the two detectors is shifted and eventually reduced to cover the portion of the dynamic range in which the power level is comprised. The gain of the receiver is then temporarily adjusted and a new measurement is carried out by the detector using the new resolving range. The AGC then re-adjusts the gain of the receiver based on the measurement given by the modified detector.

Abstract: The invention provides a system for monitoring a patient that includes: 1) a first database that stores the patient's blood test information; 2) a monitoring device that collects the patient's cardiovascular and exercise information; 3) a second database that receives cardiovascular and exercise information from the monitoring device; and 4) an Internet-based system that displays the blood test, cardiovascular, and exercise information.

Abstract: The invention provides a system that determines if a patient has Metabolic Syndrome, and in response provides a disease-management program that helps reduce medical risks associated with this malady. The system features a device configured to collect glucose information and blood pressure information, and then transmit this information to a central computer system. The system also includes a database configured to receive triglyceride information and cholesterol information from an external blood test, and a central computer system featuring: 1) a communication interface configured to communicate with the device to receive glucose and blood pressure information and with the database to receive triglyceride and cholesterol information; 2) a user interface configured to accept patient information; and 3) a processor configured to operate an algorithm that processes the glucose, blood pressure, triglyceride, cholesterol, and patient information to determine if the patient has Metabolic Syndrome.

Abstract: The invention provides: 1) a monitoring device featuring systems that monitor the patient's vital sign and exercise information; 2) an Internet-based system configured to receive, store, and display vital sign and exercise from the monitoring device, and blood test information from an external blood test; and 3) a messaging system configured to process the vital sign, exercise, and blood test information, and in response send a personalized message to the patient.

Abstract: The invention provides a system for measuring blood pressure from a patient that includes: 1) an optical module configured to be worn on the patient's ear and comprising at least one optical source and a photodetector; 2) a calibration source configured to make a blood pressure measurement; and, 3) a processing module configured to: i) receive a first signal from the optical module; ii) receive a second signal from the calibration source; iii) process the first and second signals to generate a calibration table; and iv) receive a third signal from the optical module and compare it to the calibration table to determine the patient's blood pressure.

Abstract: The invention features a medical device that measures vital signs (e.g., blood pressure, pulse oximetry, and heart rate) from a patient using at least two optical modules. Each optical module typically features two light sources (red, infrared) and a photodetector. Both optical modules are configured to measure time-dependent signals describing the patient's flowing blood. A processor analyzes the time-dependent signals to determine the patient's vital signs. Once the vital signs are measured, a wireless transmitter in the body-worn device transmits them to an external device. Processing signals from least two optical modules compensates for motion-related artifacts and noise normally present in signals used to determine vital signs from a device featuring just a single optical module.

Abstract: The invention provides a system for measuring blood pressure from a patient that includes: 1) an optical module featuring systems for measuring signals from the patient, serial communication, and power management; 2) an external computing device configured to attach to the optical module, supply power to the optical module, and receive information from the optical module through the system for serial communication; and 3) an algorithm, operating on the external computing device, that processes information received through the system for serial communication to determine the patient's blood pressure.

Abstract: A monitoring device (10), method and system are disclosed herein. The monitoring device (10) utilizes a vital sign monitor (16) to determine a plurality of vital signs of the user. The vital sign monitor (16) preferably comprises a light source (3) and photodetector (31) in communication with a pulse oximetry circuit (35).