Body worn physiological sensor device having a disposable electrode module
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
A61N-001/00
A61B-005/04
출원번호
US-0591619
(2006-11-01)
등록번호
US-8214007
(2012-07-03)
발명자
/ 주소
Baker, Steven D.
McAdams, Eric T.
Welch, James P.
Ohlenbusch, Norbert
Blackadar, Thomas P.
출원인 / 주소
Welch Allyn, Inc.
대리인 / 주소
Zhan, Sonny Z.
인용정보
피인용 횟수 :
102인용 특허 :
77
초록▼
A body worn patient monitoring device includes at least one disposable module including a plurality of electrical connections to the body. The body worn patient monitoring device also includes at least one communication-computation module, the communication-computation module having at least one mic
A body worn patient monitoring device includes at least one disposable module including a plurality of electrical connections to the body. The body worn patient monitoring device also includes at least one communication-computation module, the communication-computation module having at least one microprocessor to actively monitor the patient and to perform a real-time physiological analysis of the physiological signals. A radio circuit communicates a raw physiological signal or a result of the physiological analysis at a predetermined time or on the occurrence of a predetermined event, via a radio transmission to a remote radio receiver, wherein the at least one disposable module is mechanically and electrically coupled directly to the at least one communication-computation module. The body worn patient monitoring device, including the at least one disposable module and the at least one communication-computation module, is directly non-permanently affixed to the skin surface of the patient.
대표청구항▼
1. A body worn patient monitoring device comprising: a disposable module including a plurality of electrical connections, said electrical connections adapted to be couplable to a skin surface to measure physiological signals, at least one of said electrical connections comprising a half cell, the di
1. A body worn patient monitoring device comprising: a disposable module including a plurality of electrical connections, said electrical connections adapted to be couplable to a skin surface to measure physiological signals, at least one of said electrical connections comprising a half cell, the disposable module including a disposable module connector;a power source to power the body worn patient monitoring device;a communication-computation module being removable and reusable, having a communication-computation module connector to receive physiological signals from the disposable module via said disposable module connector, the communication-computation module including: a microprocessor to actively monitor the patient and to perform a real-time physiological analysis of the physiological signals, said analysis determining an occurrence of a predetermined physiological event, anda radio circuit to communicate, upon determination of the predetermined physiological event, a result of the physiological analysis on the occurrence of the predetermined physiological event, via a radio transmission to a remote radio receiver, wherein the disposable module is mechanically and electrically coupled directly to the communication-computation module and the body worn patient monitoring device including the disposable module and the communication-computation module is adapted to be directly non-permanently affixed to the skin surface of the patient; andat least one series current-limiting resistor configured to protect the communication-computation module, the at least one series current-limiting resistor being screened on a flexible substrate, the at least one series current-limiting resistor being in the form of resistive traces. 2. The body worn device of claim 1, wherein the plurality of electrical connections to the body comprise at least one of direct electrical connections to the body and indirect electrical connections to the body. 3. The body worn device of claim 2, wherein the indirect electrical connections to the body comprise capacitive connections to the body. 4. The body worn device of claim 1, wherein the body worn patient monitoring device comprises an ECG monitor and at least two of the electrical connections are ECG electrodes. 5. The body worn device of claim 4, wherein the ECG electrodes comprise a material screened onto the flexible substrate. 6. The body worn device of claim 5, wherein the at least one series current-limiting resistor protects the communication-computation module during a patient defibrillation event. 7. The body worn device of claim 4, wherein the mechanical interface from the at least one series current-limiting resistor to the EGG electrode includes a filleted edge. 8. The body worn device of claim 4, wherein the mechanical interface from the at least one series current-limiting resistor to the EGG electrode comprises overlapped layers. 9. The body worn device of claim 8, wherein the overlapped layers comprise a carbon resistive layer screened over a conductive surface, the carbon resistive layer having substantially the same shape as the conductive surface. 10. The body worn device of claim 1, further comprising an insulating material overlaying the at least one series current-limiting resistor to prevent arcing. 11. The body worn device of claim 5, wherein the EGG electrodes are formed substantially in the shape of an annulus. 12. The body worn device of claim 11, wherein the annulus comprises a conductive link. 13. The body worn device of claim 5, wherein the substrate is shaped to allow placement on the patient to monitor at least one of a set of standard ECG vectors while simultaneously reducing motion and muscle artifact in the corresponding ECG vector signal. 14. The body worn device of claim 1, wherein the power source is a renewable power source internal to the body worn device. 15. The body worn device of claim 1, wherein the power source comprises a rechargeable battery or a one time use battery. 16. The body worn device of claim 1, wherein the power source is a battery contained within said disposable module. 17. The body worn device of claim 1, wherein the power source is a Seebeck device. 18. The body worn device of claim 1, wherein one of the electrical connections is a reference electrode that can be used to improve common mode rejection (CMR). 19. The body worn device of claim 1, further comprising a virtual electrode as a reference electrode to improve CMR. 20. The body worn device of claim 19, wherein the virtual electrode is an electrode adapted to be situated near the skin of the patient, but not directly connected to the skin. 21. The body worn device of claim 19, wherein the virtual electrode is adapted to include a capacitive coupling of a body of the communication-computation module to the skin surface of the patient to reduce power line frequency interference. 22. The body worn device of claim 19, including a reference electrode switch for selectively choosing between using the virtual electrode as the reference electrode and a directly connected electrode as the reference electrode and wherein when the reference electrode switch selects the virtual electrode, the directly connected electrode can be used as an additional ECG electrode. 23. The body worn device of claim 19, wherein the reference electrode is a passive electrical connection or the reference electrode is actively driven. 24. The body worn device of claim 1, wherein the communication-computation module includes a pacer detection circuit. 25. The body worn device of claim 24, wherein the pacer detection circuit generates a microprocessor interrupt to inform the microprocessor that a pacer event occurred. 26. The body worn device of claim 25, wherein the microprocessor interrupt is used to mark a corresponding physiological signal in time as related to a pacer event. 27. The body worn device of claim 25, wherein the device automatically determines if a patient has a pacemaker and only enables the pacer detect circuit when a pacemaker is present. 28. The body worn device of claim 25, wherein the device is configured by an external input to enable or disable the pacer detect circuit. 29. The body worn device of claim 1, wherein the body worn device includes circuit protection to allow the device to survive multiple defibrillation cycles of at least 360 joules. 30. The body worn device of claim 29, wherein the circuit protection comprises a gas discharge tube or a plurality of diodes to clamp or limit the signals from the electrical connections. 31. The body worn device of claim 29, wherein a plurality of components of the circuit protection are distributed between the disposable module and the communication-computation module. 32. The body worn device of claim 1, further comprising a high pass filter with a selectable corner frequency to filter the physiological signals. 33. The body worn device of claim 32, wherein the corner frequency is selected by a switch selectable resistance. 34. The body worn device of claim 32, wherein the corner frequency is selected by one or more switching capacitors switched a rate higher than the corner frequency of a low pass anti-aliasing filter. 35. The body worn device of claim 32, wherein the high pass filter is implemented in software running on the microprocessor. 36. The body worn device of claim 1, wherein the body worn device self checks a pacer detection circuit by injecting a simulated pacer pulse into a front end amplifier to stimulate the pacer detection circuit by simulating the presence of a patient's pacemaker. 37. The body worn device of claim 1, wherein the communication-computation module includes circuit components configured to detect failure of contact of one or more of the electrical connections with the skin surface of the patient. 38. The body worn device of claim 1, wherein the communication-computation module is protected from external high energy signals by electro-surgical isolation suppression circuits. 39. The body worn device of claim 1, wherein an algorithm running on a microprocessor in the body worn device causes the body worn device to enter a low power mode that disables at least one circuit of the body worn device, from the end of a “T wave” at the end of one heart beat to the beginning of a “P wave” at the beginning of the next heart beat, to save power. 40. The body worn device of claim 4, including an ESIS filter having a low enough corner frequency such that the energy from a pacer pulse is recorded by at least one sample, even though the pacer pulse itself is of small duration compared to the sample rate and the pacer pulse occurs between samples. 41. The body worn device of claim 1, wherein neon bulbs connected from the physiological sensors to an electronics common (ground) protect one or more internal circuits of the communication-computation module from a defibrillation pulse. 42. The body worn device of claim 1, wherein a plurality of diodes disposed between the physiological sensors and an electronics common (ground) protect one or more internal circuits of the communication-computation module from a defibrillation pulse. 43. The body worn device of claim 1, wherein the radio circuit communicates an unprocessed physiological signal. 44. The body worn device of claim 1, wherein the radio circuit communicates a result of the physiological analysis at a predetermined time. 45. A body worn patient monitoring device comprising: a disposable module including a plurality of electrical connections, the electrical connections adapted for electrical coupling to a skin surface to receive physiological signals, the disposable module including a disposable module connector;a power source to power the body worn patient monitoring device;a communication-computation module, having a communication-computation module connector to receive the physiological signals from the disposable module via the disposable module connector, the communication-computation module including: a microprocessor to actively monitor a patient and to perform a real-time physiological analysis of the physiological signals, the analysis determining an occurrence of a predetermined ECG event,a radio circuit to communicate an unprocessed physiological signal or a result of the physiological analysis, at a predetermined time or on an occurrence of a predetermined event, via a radio transmission to a remote radio receiver, andwherein the disposable module has a mechanical and electrical coupling to the communication-computation module, forming the body worn patient monitoring device as a single unit that is adapted to be directly and non-permanently affixed to the skin surface of the patient; andat least one series current-limiting resistor configured to protect the communication-computation module, the at least one series current-limiting resistor being screened on a flexible substrate, the at least one series current-limiting resistor being in the form of resistive traces.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (77)
Cooper Russ (Chandler AZ) Mitra Sumit (Tempe AZ), A/D converter with zero power mode.
Kwun Hegeon ; Teller Cecil M. ; Meyer Roy C. ; Swenson Kendall R., Apparatus and method for monitoring engine conditions, using magnetostrictive sensors.
Unger John David (Windham NH) Kolnsberg Mark Edward (Beverly MA) Scholz Wolfgang (Beverly MA), Apparatus and method for providing dual output signals in a telemetry transmitter.
Miyata Takashi,JPX ; Matsuo Noriyoshi,JPX ; Uchida Hitoshi,JPX ; Sawada Naomi,JPX ; Tomita Yutaka,JPX, Apparatus and system for measuring electrical potential variations in human body.
Darley Jesse ; Gaudet Paul J. ; Joffe Sam ; Ohlenbusch Norbert ; Costello John ; Bates Mark ; Blackadar Thomas, Detachable foot mount for electronic device.
Jesse Darley ; Paul J. Gaudet ; Sam Joffe ; Norbert Ohlenbusch ; John Costello ; Mark Bates ; Thomas Blackadar, Detachable foot mount for electronic device.
Dempsey Michael K. (Acton MA) Kotfila Mark S. (Chelmsford MA) Snyder Robert J. (Westford MA), Flexible patient monitoring system featuring a multiport transmitter.
Weiner,Herbert S.; Adams,Douglas S.; Fo,Jon K. F.; Lee,Koo; Baker,Steven D.; Petersen,Eric G., Health care patient status event processing and reporting.
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.
Zhang Zuoying L. ; Kar Barun K. ; Li Guang X. ; Gutteridge Ronald J. ; Joseph Eric D., Monolithic semiconductor device having a microstructure and a transistor.
Welch, James P.; Baker, Steven D.; Guilak, Farzin G.; Sampath, Anand; Williams, Daniel L., Personal status physiologic monitor system and architecture and related monitoring methods.
Welch, James P.; Baker, Steven D.; Guilak, Farzin G.; Sampath, Anand; Williams, Daniel L., Personal status physiologic monitor system and architecture and related monitoring methods.
Welch,James P.; Baker,Steven D.; Guilak,Farzin G.; Sampath,Anand; Williams,Daniel L., Personal status physiologic monitor system and architecture and related monitoring methods.
Asai Toshio (Uchinadamachi JPX) Nakaya Yasuhiro (Futakuchimachi JPX) Onodera Yasuaki (Saitamaken JPX), Radio electrocardiography for a living body moving in the water.
Foerstner Juergen August ; Hughes Henry Guenther ; Mirza Amir Raza, Semiconductor structure having a monocrystalline member overlying a cavity in a semiconductor substrate and process therefor.
Zhou, Peter Y.; Pang, Dexing; Tong, Yiu-Cho Alan; Lin, Ning; Addington, David Ralph; Albanna, Rowena Lampa; Albanna, Amro; Bolton, Keith I., System for localizing and sensing objects and providing alerts.
Peifer John W. ; Hopper Andrew ; Burrow Michael ; Sudduth Barry ; Panchal Samir ; Quay Andy ; Price W. Edward ; Searle John R., Telemedicine system using voice video and data encapsulation and de-encapsulation for communicating medical informatio.
Sooriakumar K. (Scottsdale AZ) Monk David J. (Mesa AZ) Chan Wendy K. (Scottsdale AZ) Goldman Kenneth G. (Chandler AZ), Vertically integrated sensor structure and method.
Hafezi, Hooman; O'Reilly, David; Johnson, Patricia; Hatamkhany, Zahedeh; Robertson, Timothy; Zdeblick, Mark, Communication system incorporated in a container.
Thompson, Todd; Zdeblick, Mark; Behzadi, Yashar; Costello, Benedict; Robertson, Timothy; Hafezi, Hooman; Savage, George, Communication system using an implantable device.
Thompson, Todd; Zdeblick, Mark; Behzadi, Yashar; Costello, Benedict; Robertson, Timothy; Hafezi, Hooman; Savage, George, Communication system using an implantable device.
Hauck, John A.; Schweitzer, Jeffery A.; Koyrakh, Lev A., Correction of shift and drift in impedance-based medical device navigation using measured impedances at external patch electrodes.
Hauck, John A.; Schweitzer, Jeffrey A.; Koyrakh, Lev A., Correction of shift and drift in impedance-based medical device navigation using measured impedances at external patch electrodes.
Kumar, Uday N.; Livingston, Peter H.; Day, Mark J.; Park, Shena H.; Willis, William F.; Righter, William H.; Bahney, Tim, Device features and design elements for long-term adhesion.
Savage, George; Hafezi, Hooman; Colliou, Olivier; Zdeblick, Mark; Strand, Angela, Evaluation of gastrointestinal function using portable electroviscerography systems and methods of using the same.
Quinlan, Thomas J.; Gaudet, Paul J.; Ohlenbusch, Norbert; Zhang, Jianwei; Oliver, Steven R.; Blackadar, Thomas P.; Monahan, David P., Health-monitor patch.
Quinlan, Thomas J.; Gaudet, Paul J.; Ohlenbusch, Norbert; Zhang, Jianwei; Oliver, Steven R.; Blackadar, Thomas P.; Monahan, David P., Health-monitor patch.
Fleming, Robert Alan; Kushner, Cherie Elaine; McAllister, William; Zdeblick, Mark, Method and apparatus for use with received electromagnetic signal at a frequency not known exactly in advance.
Fleming, Robert; Kushner, Cherie; McAllister, William H.; Zdeblick, Mark, Methods, devices and systems for receiving and decoding a signal in the presence of noise using slices and warping.
Fleming, Robert; Kushner, Cherie; McAllister, William H.; Zdeblick, Mark, Methods, devices and systems for receiving and decoding a signal in the presence of noise using slices and warping.
Fleming, Robert; Kushner, Cherie; McAllister, William H.; Zdeblick, Mark, Methods, devices and systems for receiving and decoding a signal in the presence of noise using slices and warping.
Zdeblick, Mark; Stoll, Arna Ionescu; McAllister, William; Au-Yeung, Kit Yee, Mobile device and system for detection and communication of information received from an ingestible device.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.