A defibrillator system optimizes the timing and manner of applying a defibrillator charge to a patient based upon data provided to the defibrillator from a utility module or one or more external devices. A parameter module on the utility module provides the defibrillator with patient parameter infor
A defibrillator system optimizes the timing and manner of applying a defibrillator charge to a patient based upon data provided to the defibrillator from a utility module or one or more external devices. A parameter module on the utility module provides the defibrillator with patient parameter information. Devices external to the utility module may provide the utility module with coaching data that the utility module may pass through to the defibrillator as a proxy to the external devices. The utility module may also provide external devices with patient data that the utility module may pass through to the external devices as a proxy to the defibrillator on a scheduled or other basis. The utility module may additionally provide a reserve of power to enable defibrillators to be used where power is unavailable and to enable defibrillators to deliver multiple charges more readily anywhere, anytime.
대표청구항▼
1. A method comprising: deriving, at a utility module, coaching data from a parameter of a patient, the utility module comprising a parameter module to detect the parameter of the patient, a communication module configured to transmit data from the utility module, and a module processor configured t
1. A method comprising: deriving, at a utility module, coaching data from a parameter of a patient, the utility module comprising a parameter module to detect the parameter of the patient, a communication module configured to transmit data from the utility module, and a module processor configured to control the parameter module and the communication module; andproviding, from the utility module, the coaching data to a defibrillator, the defibrillator comprising an energy storage device configured to store an electrical charge, a defibrillation port, a display, and a defibrillator processor configured to control the display and when an electrical charge is applied to the defibrillation port to defibrillate the patient, wherein the defibrillator is configured to use the coaching data to provide coaching to defibrillate the patient. 2. The method of claim 1, wherein the coaching data from the utility module to the defibrillator further comprises patient parameter data from the parameter module. 3. The method of claim 2, wherein the patient parameter data is selected from the group consisting of: a measurement of CO2 exhaled by a patient;an electrical activity of the heart of a patient;an exchange of air between the lungs of a patient and the atmosphere;a pressure of the blood in a patient;a temperature of a patient;an oxygen saturation in the blood of a patient;a measurement of a chest compression of a patient;an image of the internal structure of a patient;an oxygen saturation in the blood in the brain of a patient; andthe acidity or alkalinity of fluids in a patient. 4. The method of claim 2, wherein the defibrillator is configured to render the patient parameter data on the display to coach a user of the defibrillator to defibrillate the patient. 5. The method of claim 1, wherein the defibrillator uses the coaching data to provide coaching on mechanics of CPR techniques to a user of the defibrillator. 6. The method of claim 5, comprising measuring, by the parameter module, a measurement of a chest compression of a patient, wherein the coaching data is derived, at the utility module, from the measurement of the chest compression. 7. The method of claim 1, wherein the defibrillator processor is configured to use the coaching data to control when the electrical charge is applied to the defibrillation port to defibrillate the patient. 8. The method of claim 1, wherein the defibrillator comprises a speaker, and the defibrillator is configured to use the coaching data to output a voice prompt via the speaker to coach a user of the defibrillator to defibrillate the patient. 9. The method of claim 1, wherein the defibrillator is configured to use the coaching data to render a visual prompt on the display to coach a user of the defibrillator to defibrillate the patient. 10. The method of claim 1, wherein the defibrillator comprises a measurement circuit to receive physiological signals from the defibrillation port, and wherein the defibrillator is configured to provide coaching based on the physiological signals. 11. The method of claim 10, wherein the defibrillator processor comprises a detection module to detect ventricular defibrillation in the physiological signals, and wherein the defibrillator is configured to provide coaching based on detection of ventricular defibrillation. 12. The method of claim 10, comprising transmitting, from the utility module, data received from the defibrillator to one or more external devices to use in generating a portion of the coaching data. 13. The method of claim 12, comprising receiving, at the utility module, the portion of the coaching data from the one or more external devices. 14. The method of claim 12, comprising polling the defibrillator from the utility module to determine the existence of the data residing in the defibrillator to be received from the defibrillator. 15. A utility module comprising: a parameter module to detect a parameter of a patient, a communication module configured to transmit data from the utility module, and a module processor configured to control the parameter module and the communication module, wherein: the utility module is configured for connection to a defibrillator that comprises an energy storage device configured to store an electrical charge, a defibrillation port, a display, and a defibrillator processor, wherein the defibrillator processor is configured to control the display and when an electrical charge is applied to the defibrillation port to defibrillate the patient; andthe utility module is configured to derive coaching data from the parameter of the patient, and to provide the coaching data to the defibrillator, wherein the defibrillator is configured to use the coaching data to provide coaching to defibrillate the patient. 16. The utility module of claim 15, wherein the coaching data from the utility module to the defibrillator further comprises patient parameter data from the parameter module. 17. The utility module of claim 15, wherein the parameter module generates patient parameter data selected from the group consisting of: a measurement of CO2 exhaled by a patient;an electrical activity of the heart of a patient;an exchange of air between the lungs of a patient and the atmosphere;a pressure of the blood in a patient;a temperature of a patient;an oxygen saturation in the blood of a patient;a measurement of a chest compression of a patient;an image of the internal structure of a patient;an oxygen saturation in the blood in the brain of a patient; andthe acidity or alkalinity of fluids in a patient. 18. The utility module of claim 17, wherein the coaching data is derived from the patient parameter data, and the patient parameter data comprises at least the measurement of the chest compression. 19. The utility module of claim 18, wherein the coaching data comprises at least one of coaching on speed of CPR chest compressions or depth of CPR chest compressions. 20. The utility module of claim 15, wherein the defibrillator is configured to render patient parameter data generated from the parameter of the patient on the display. 21. The utility module of claim 15, wherein the defibrillator processor is configured to use the coaching data to provide coaching on when the electrical charge should be applied to the defibrillation port to defibrillate the patient. 22. The utility module of claim 15, wherein the defibrillator comprises a speaker, and the defibrillator is configured to use the coaching data to output a voice prompt via the speaker to coach a user of the defibrillator to defibrillate the patient. 23. The utility module of claim 15, wherein the defibrillator is configured to use the coaching data to render a visual prompt on the display to coach a user of the defibrillator to defibrillate the patient. 24. The utility module of claim 15, wherein the defibrillator comprises a measurement circuit to receive physiological signals from the defibrillation port, and wherein the defibrillator is configured to provide coaching based on the physiological signals. 25. The utility module of claim 24, wherein the defibrillator processor comprises a detection module to detect ventricular defibrillation in the physiological signals, and wherein the defibrillator is configured to provide coaching based on detection of ventricular defibrillation. 26. The utility module of claim 15, wherein a portion of the coaching data is received, at the utility module, from one or more external devices. 27. The utility module of claim 26, wherein the communication module is configured to transmit data received from the defibrillator to the one or more external devices to use in generating the portion of the coaching data. 28. The utility module of claim 27, wherein the utility module is configured to poll the defibrillator to determine the existence of the data residing in the defibrillator to be received from the defibrillator.
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Schwibner, Barry H.; Schwartz, Brad; Judge, Eric, Adaptation of the common notebook, laptop computer, netbook and tablet PC computer to enable each to be used as an automated external defibrillator (AED) to treat victims of sudden cardiac arrest.
Douglas Joel S. ; Drexler Andrew M. ; Raney Charles C. ; Leung Edward C. ; Yee Edison F., Analyte concentration information collection and communication system.
Tamura, Paul S.; Yerkovich, Daniel; Kelly, Patrick F.; Nova, Richard; Williamson, Joseph Bradley; Johnson, Stephen B.; DeBardi, Gary, Apparatus and method for maintaining a defibrillator battery charge and optionally communicating.
Policastro Charles J. (2122 Old Forde Way Lansdale PA 19446) Dougherty Edmond J. (Philadelphia PA) Dowling Martin J. (Haddonfield NJ), Apparatus for monitoring, storing and transmitting detected physiological information.
Parker William S. ; Splinter Patrick J. ; Lindseth Sarah M. ; Bradley Matthew G., Automatic external defibrillator first responder and clinical data outcome management system.
Johansen Curt C. (Everett WA) Moore Mark P. (Kent WA) Hann Edward H. (Woodinville WA), Communication interface for transmitting and receiving serial data between medical instruments.
Aoyama, David Dean; Bielstein, Matthew Lawrence; Curtin, Barry D.; Drew, Kevin C.; Lim, Mina; McKay, E. Thomas; Merry, Randy L.; Peterson, Ken, Defibrillator network system.
Morgan Carlton B. (Bainbridge Island WA) Powers Daniel (Bainbridge Island WA) Cole Clinton (Seattle WA) Mydynski Steven T. (Bothell WA) Leventhal Michael J. (Palo Alto CA), Defibrillator system using multiple external defibrillators and a communications network.
Martin G. Rockwell ; Gregory D. Brink ; Jonathan N. Andrews ; David L. Burton ; Patricia A. Arand ; Nancy H. Forman ; Kenneth S. Rucker ; John Kent ; Daniel J. Power, Defibrillator test system with wireless communications.
Martin G. Rockwell ; Gregory D. Brink ; Jonathan N. Andrews ; David L. Burton ; Patricia A. Arand ; Nancy H. Forman ; Kenneth S. Rucker ; John Kent ; Daniel J. Powers, Defibrillator with mode changing infrared communications.
Martin G. Rockwell ; Gregory D. Brink ; Jonathan N. Andrews ; David L. Burton ; Patricia A. Arand ; Nancy H. Forman ; Kenneth S. Rucker ; John Kent ; Daniel J. Powers, Defibrillator with wireless communication of ECG signals.
Rockwell Martin G. ; Brink Gregory D. ; Andrews Jonathan N. ; Burton David L. ; Arand Patricia A. ; Forman Nancy H. ; Rucker Kenneth S. ; Kent John ; Powers Daniel J., Defibrillator with wireless communications.
Fincke Randall W. (Winchester MA) Lopin Michael L. (Newton MA) Faller Frederick W. (Burlington MA), Detachable power supply for supplying external power to a portable defibrillator.
Daniel, Arthur A.; McKelvey, Mark A.; Modry, John A.; Roubal, Eric G.; Sandstrom, Andrew E.; Wildt, Patrick M., Event handling mechanism having a process and an action association process.
Powers Daniel J. ; Cameron David ; Cole Clinton S. ; Lyster Thomas D. ; Mydynski Steven T. ; Morgan Carlton B., External defibrillator with automatic self-testing prior to use.
Hossack John A. (Palo Alto CA) Eaton John W. (Palo Alto CA) Cooper Thomas G. (Menlo Park CA) Ikeda Michael H. (San Jose CA) Rosa David J. (San Jose CA), Flexible ultrasonic transducers and related systems.
Todd D. Alleckson ; Energy Cruse, II ; Karyn Grant ; Robert C. Leichner ; Gaurang C. Mehta ; James M. Rueter ; Thomas A. Shoup ; Alexander L. Tudor ; Ronald T. Yamada, Home hub for reporting patient health parameters.
Michael Kraus DE; Martin Lang DE; Berhard Lang DE; Johannes Neudecker DE; Klemens Beetz DE; Axel Nagelschmidt DE; Jens Potschadtke DE, Implant with close and long-range telemetry.
Reyes Rey S. (26784 Via San Jose Mission Viejo CA 92691), Interface cable for connecting bedside electrocardiograph monitor to portable defibrillator/electrocardiograph machine.
Schwibner, Barry H.; Schwartz, Brad; Judge, Eric, Kits and methods for retrofitting and adapting common notebooks, laptop computers, and tablets, to enable each to be used as an automated external defibrillator (AED), and as a manual defibrillator.
Morgan Carlton B. (Bainbridge Island WA) Cole Clinton (Seattle WA) Powers Daniel J. (Issaquah WA), Method and apparatus for gathering event data using a removable data storage medium and clock.
Cyrus Judith L. ; Gordon Garry R. ; Cole Clinton S. ; Grimley Justin ; Bell Leona, Method and apparatus for recording and replaying time-correlated medical event data.
Cyrus Judith L. ; Gordon Garry R. ; Cole Clinton S. ; Grimley Justin ; Bell Leona, Method and apparatus for recording and replaying time-correlated medical event data.
Vaynberg,Boris; Zimmerman,Yotam; Iger,Yoni; Aharonowitz,Gal, Method, a system, and a device for detecting and for reducing energy leakage from an energy treatment devices.
Lebel, Ronald J.; Shahmirian, Varaz; Bowman, IV, Sam W.; Starkweather, Timothy J.; Morgan, Wayne A., Microprocessor controlled ambulatory medical apparatus with hand held communication device.
Schwibner, Barry H.; Schwartz, Brad; Judge, Eric, Pocket kits and methods for retrofitting and adapting common notebook computers, laptop computers, and tablet computers, to enable each to be used as an automated external defibrillator (AED), and as a manual defibrillator.
Heilman Marlin S. (Sarver PA) Brandt Arlan J. (Gibsonia PA) Bowling Larry D. (Pittsburgh PA) Russial Joseph F. (Pittsburgh PA), Portable device for sensing cardiac function and automatically delivering electrical therapy.
Smith ; David B. ; Benson ; James A., Portable electronic physiological instrument having separable first and second components, and improved mechanical conn.
Robinson, Scott W.; Slotty, Eric R.; Clapp, Alan E.; Van Ryzin, Patrick Allen; Frangesch, Richard J., Portable patient monitor with alarm light integrated into handle.
Alan E. Clapp ; Eric R. Slotty ; Michael P. Cornelson ; Scott W. Hoelscher ; John P. Tennessen, Portable patient monitor with antenna integrated into handle.
Palmer, Michael J.; Gray, James M.; Schieble, David L.; Clapp, Alan E.; Bayer, Brian; Loehning, Wilfried; Schulz, Andreas; Schlosser, Horst, Portable patient monitor with defibrillator/pacemaker interface and battery power management.
Morgan Carlton B. (Bainbridge Island WA) Cole Clinton (Seattle WA) Powers Daniel J. (Issaquah WA), Quality assurance method for a care delivery system.
Smith Kathy K. ; Medero Richard ; Cruz Edward V. ; Hoard David W. ; Pate Brian L. ; Wallace ; III Robert S., Reconfigurable user interface for modular patient monitor.
Surwit Richard S. ; Allen ; III Lyle M. ; Cummings Sandra E., Systems, methods and computer program products for monitoring, diagnosing and treating medical conditions of remotely located patients.
Wood Michael A. ; Roncalez Pascal ; Pflugrath Lauren S. ; Souquet Jacques, Ultrasonic diagnostic imaging system with universal access to diagnostic information and images.
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