Body-worn sensor for characterizing patients with heart failure

What is claimed is: 1. A system worn entirely on a body of a patient for measuring parameters determined from heartbeat-induced impedance pulses, ECG signals, and motion signals exclusively from the patient's chest, comprising: a monitoring housing supporting electrical circuit components, the monitoring housing configured to rest on the patient's chest and not wrap around the patient's chest; an impedance-measuring system integrated within the monitoring housing, the impedance-measuring system comprising an impedance circuit in electrical contact with at least a first set of impedance electrodes and configured to receive a first set of electrical signals from the patient's chest and process them to determine heartbeat-induced impedance pulses exclusively from the patient's chest; an ECG-measuring system integrated within the monitoring housing, the ECG-measuring system comprising an analog ECG circuit in electrical contact with at least an ECG electrode and configured to receive a second set of electrical signals from the patient's chest and process them to determine ECG signals, wherein the ECG electrode is disposed between the first set of impedance electrodes to ensure a gap exists between each impedance electrode and ECG electrode; a motion-measuring system connected to the monitoring housing, the motion-measuring system comprising a motion-detecting circuit and configured to generate motion signals in response to the patient's movements; a data-processing system connected to the monitoring housing and in electrical contact with the impedance-measuring system, the ECG-measuring system, and the motion-measuring system, the data-processing system comprising a microprocessor configured to operate a set of computer algorithms configured to process the heartbeat-induced impedance pulses, the ECG signals, and the motion signals; a wireless transmitter integrated connected to the monitoring housing and in electrical contact with the data-processing system, the wireless transmitter configured to transmit the parameters determined from the heartbeat-induced impedance pulses, the ECG signal, and the motion signal; and a battery system comprising a battery in electrical contact with and configured to power the impedance-measuring system, the ECG-measuring system, the motion-measuring system, the data-processing system, and the wireless transmitter. 2. The system of claim 1 , wherein the monitoring housing comprises at least one rigid circuit board electrically connected to a flexible substrate comprising an electrical system including at least one of the impedance-measuring system and the ECG-measuring system. 3. The system of claim 2 , wherein the flexible substrate comprises Kapton®. 4. The system of claim 1 , wherein the monitoring housing comprises at least two rigid circuit boards connected by a flexible substrate. 5. The system of claim 4 , wherein the flexible substrate supports an electrical system including at least one of the impedance-measuring system and the ECG-measuring system. 6. The system of claim 5 , wherein the flexible substrate comprises Kapton®. 7. The system of claim 5 , wherein the flexible substrate further includes a cable. 8. A system worn entirely on a body of a patient for measuring heartbeat-induced impedance pulses, ECG signals, and motion signals from the patient, comprising: a monitoring housing supporting electrical circuit components, the monitoring housing configured to rest on the patient's chest but not wrap around the patient's chest; an impedance-measuring system integrated within the monitoring housing, the impedance-measuring system comprising an impedance circuit in electrical contact with at least a first set of impedance electrodes and configured to receive a first set of electrical signals from the patient's chest and process them to determine heartbeat-induced impedance pulses exclusively from the patient's chest; an ECG-measuring system integrated within the monitoring housing, the ECG-measuring system comprising an analog ECG circuit in electrical contact with at least an ECG electrode and configured to receive a second set of electrical signals from the patient's chest and process them to determine ECG signals, wherein the ECG electrode is disposed between the first set of impedance electrodes to ensure a gap exists between each impedance electrode and ECG electrode; a motion-measuring system integrated within the monitoring housing, the motion-measuring system comprising a motion-detecting circuit and configured to generate motion signals in response to the patient's movements; and a data-processing system connected to the monitoring housing and in electrical contact with the impedance-measuring system, the ECG-measuring system, and the motion-measuring system, the data-processing system comprising a microprocessor configured to operate a set of computer algorithms configured to process the impedance signals, the ECG signals, and the motion signals. 9. The system of claim 8 , wherein the monitoring housing comprises at least one rigid circuit board electrically connected to a flexible substrate. 10. The system of claim 9 , wherein the flexible substrate comprises Kapton®. 11. The system of claim 9 , wherein the flexible substrate further includes a cable. 12. A system worn entirely on a body of a patient for measuring parameters determined from heartbeat-induced impedance pulses, ECG signals, and motion signals from the patient, comprising: a monitoring housing supporting electrical circuit components, the monitoring housing configured to rest on the patient's chest but not wrap around the patient's chest; an impedance-measuring system integrated within the monitoring housing, the impedance-measuring system comprising an analog impedance circuit in electrical contact with at least a first set of electrodes and configured to receive a first set of electrical signals from the patient's chest and process them to determine heartbeat-induced impedance pulses; an ECG-measuring system integrated within the monitoring housing, the ECG-measuring system comprising an analog ECG circuit in electrical contact with at least an ECG electrode and configured to receive a second set of electrical signals from the patient's chest and process them to determine ECG signals, wherein the ECG electrode is disposed between the first set of impedance electrodes to ensure a gap exists between each impedance electrode and ECG electrode; a motion-measuring system integrated within the monitoring housing, the motion-measuring system comprising a motion-detecting circuit and configured to generate a set of motion signals in response to the patient's movements; a location-measuring system integrated within the monitoring housing, the location-measuring system configured to wirelessly receive signals and, in response, determine a set of location coordinates describing the patient's geographic location; a data-processing system integrated within the monitoring housing and in electrical contact with the impedance-measuring system, the ECG-measuring system, the motion-measuring system, and the location-measuring system, the data-processing system comprising a microprocessor configured to operate a set of computer algorithms configured to process the heartbeat-induced impedance pulses, the ECG signals, the set of location coordinates, and the motion signals; a wireless transmitter integrated within the monitoring housing and in electrical contact with the data-processing system, the wireless transmitter configured to transmit the parameters determined from the impedance signals, the ECG signals, the set of location coordinates, and the motion signals; and a battery