Apparatus and method for measuring biologic parameters
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
A61B-005/00
A61B-005/103
A61B-005/117
A61B-005/01
A61B-005/0205
G01K-013/00
G02C-011/00
A61B-005/0476
A61B-005/053
G08B-005/36
출원번호
US-0622284
(2015-02-13)
등록번호
US-9301719
(2016-04-05)
발명자
/ 주소
Abreu, Marcio Marc
출원인 / 주소
GEELUX HOLDING, LTD.
대리인 / 주소
Studebaker & Brackett PC
인용정보
피인용 횟수 :
0인용 특허 :
137
초록▼
Support structures for positioning sensors on a physiologic tunnel for measuring physical, chemical and biological parameters of the body and to produce an action according to the measured value of the parameters. The support structure includes a sensor fitted on the support structures using a speci
Support structures for positioning sensors on a physiologic tunnel for measuring physical, chemical and biological parameters of the body and to produce an action according to the measured value of the parameters. The support structure includes a sensor fitted on the support structures using a special geometry for acquiring continuous and undisturbed data on the physiology of the body. Signals are transmitted to a remote station by wireless transmission such as by electromagnetic waves, radio waves, infrared, sound and the like or by being reported locally by audio or visual transmission. The physical and chemical parameters include brain function, metabolic function, hydrodynamic function, hydration status, levels of chemical compounds in the blood, and the like. The support structure includes patches, clips, eyeglasses, head mounted gear and the like, containing passive or active sensors positioned at the end of the tunnel with sensing systems positioned on and accessing a physiologic tunnel.
대표청구항▼
1. A medial canthal pad for measuring biological parameters in a brain temperature tunnel, said medial canthal pad comprising a head mounted structure, a housing, a temperature sensor in said housing, said temperature sensor is configured to measure temperature signals produced on the skin at an end
1. A medial canthal pad for measuring biological parameters in a brain temperature tunnel, said medial canthal pad comprising a head mounted structure, a housing, a temperature sensor in said housing, said temperature sensor is configured to measure temperature signals produced on the skin at an end of the brain temperature tunnel, an extension arm projecting from the head mounted structure, said housing being located on said extension arm, said extension arm locating said housing to be positioned adjacent to a medial corner of an eye above a medial canthal tendon and in a medial third of an upper eyelid when the head mounted structure is worn by an individual, a power source in said housing, and a reporting device in said housing, said reporting device is configured to transmit temperature signals measured by said temperature sensor, said sensor, said power source and said reporting device being electrically connected to produce and report a signal. 2. The medial canthal pad as claimed in claim 1, wherein said housing is secured to an eyeglass frame by said extension arm. 3. The medial canthal pad as claimed in claim 1, wherein said housing measures greater than 0 mm and less than 11 mm at a greatest dimension. 4. A nose pad of a support structure for measuring biological parameters in a brain temperature tunnel of a patient, said nose pad comprising: a housing, a temperature sensor contained in the housing configured to measure temperature signals produced on the skin at an end of the brain temperature tunnel, and an eyeglass frame to be worn by the patient, an extension arm projecting from said eyeglass frame, said housing being mounted on the eyeglass frame extension arm, said eyeglass frame including a positioning device said extension arm for mounting the temperature sensor adjacent to a medial corner of an eye above a medial canthal tendon and in a medial third of an upper eyelid at the brain temperature tunnel when the eyeglass frame is worn by an individual. 5. The eyeglasses for measuring biological parameters as claimed in claim 4, wherein the temperature sensor is a contact sensor. 6. The eyeglasses for measuring biological parameters as claimed in claim 4, wherein the temperature sensor is non-contact sensor. 7. Eyeglasses for measuring biological parameters, said eyeglasses comprising three separate pieces, a first one of the three separate pieces including a right lens rim and a right temple assembly, a second one of the three separate pieces including a left lens rim and left temple assembly, and a third one of the three separate pieces including a medial connector piece including a support bridge and nose pad portions, said support bridge releasably connecting said right lens and right temple assembly to said left lens rim and left temple assembly, said medial connector piece containing a temperature sensor located on an extension projecting from at least one of the nose pad portions configured to measure temperature signals produced on the skin at a medial corner of an eye above a medial canthal tendon and in a medial third of an upper eyelid at an end of the brain temperature tunnel when the eyeglasses are worn by an individual. 8. The eyeglasses for measuring biological parameters as claimed in claim 7, wherein said support bridge and said nose pad portions are releasably mounted on said right lens rim and said left lens rim. 9. The eyeglasses for measuring biological parameters as claimed in claim 7, wherein said medial connector piece includes a power source. 10. The eyeglasses for measuring biological parameters as claimed in claim 7, said medial connector piece includes a microprocessor. 11. The eyeglasses for measuring biological parameters as claimed in claim 7, said medial connector piece includes a wireless transmitter. 12. The eyeglasses for measuring biological parameters as claimed in claim 11, wherein said wireless transmitter transmits a signal by at least one of a radio frequency, light, sound and electromagnetic energy.
Sinha Dipen N. (Los Alamos NM) Wray William O. (Los Alamos NM), Apparatus and method for non-contact, acoustic resonance determination of intraocular pressure.
Lakowicz Joseph R. (Columbia MD) Maliwal Badri P. (Baltimore MD) Koen Peter A. (Hillsborough NJ), Determination and quantification of saccharides by luminescence lifetimes and energy transfer.
Penn, Richard D.; Miesel, Keith Alan; Stylos, Lee; Christopherson, Mark A.; Nagavarapu, Sudha; Roline, Glenn M., Device and method to measure and communicate body parameters.
Glynn Christopher J. (Bridge Farmhouse Appleford ; Oxon OX14 4NU GBX) Hill Adrian R. (Brewers ; Sheepstead Abingdon ; Oxon ; OX13 6QG GBX), Device for use in real-time monitoring of human or animal bodily function.
James Tony (Fukuoka JPX) Sandanayake Saman (Fukuoka JPX) Shinkai Seiji (Fukuoka JPX), Fluorescent compound suitable for use in the detection of saccharides.
Barney George M. (Dallas TX), Instrument for measuring and computing heart beat, body temperature and other physiological and exercise-related paramet.
John D. G. Rather ; H. John Caulfield ; Richard D. Doolittle ; Peter J. Littrup ; Glenn W. Zeiders, Method and apparatus for high-resolution detection and characterization of medical pathologies.
James Paul (Marietta GA) Kuemmel Theodore J. (Waukesha WI) Wurm Michael G. (Franklin WI) Banach James D. (Milwaukee WI) Fulton David (Pickering CAX), Method and apparatus for monitoring personal core temperature.
Chick William L. (Wellesley MA) Wolf David E. (Hudson MA) Cardullo Richard A. (Milford MA), Method and device for detecting and quantifying glucose in body fluids.
Kaye David B. (2469 W. Roberts Fresno CA 93711) Melville Charles D. (10559 N. Armstrong Ave. Fresno CA 93612), Method for sensing pressure in an object.
Buchert Janusz (265 Cabrini Blvd. ; #6E New York NY 10040), Method, apparatus and procedure for non-invasive monitoring blood glucose by measuring the polarization ratio of blood l.
Clarke Richard H. (Big Sky MT) Wang Qian (Boston MA), Non-invasive blood analysis by near infrared absorption measurements using two closely spaced wavelengths.
Kramer Charles E. ; Sterling Bernhard B. ; Braig James R. ; Goldberger Daniel S. ; Shulenberger Arthur M. ; Trebino Rick ; King Richard A., Non-invasive infrared absorption spectrometer for the generation and capture of thermal gradient spectra from living tissue.
Aubry, Jean-François; Fink, Mathias; Tanter, Mickaël, Non-invasive method of obtaining a pre-determined acoustic wave field in an essentially uniform medium which is concealed by a bone barrier, imaging method and device for carrying out said methods.
Paul D. Haines GB; Andrea J. Harry GB; Harpal S. Kumar GB; John D. Place GB; Susan B. Riley Earl ; Neil J. Sheehan ; David A. Sheraton, Physiological sensor device.
Kaye David B. (2469 W. Roberts Fresno CA 93711) Melville Charles D. (10559 N. Armstrong Ave. Fresno CA 93612), Pressure sensing device having transducer overlying and deforming eye.
Goodman David E. (San Francisco CA) Corenman James E. (Menlo Park CA) New ; Jr. William (Woodside CA) Yelderman Mark (Menlo Park CA), Sensor having cutaneous conformance.
Friauf Walter S. (Bethesda MD) Smith Paul D. (Annapolis MD) Cole John W. (Rockville MD) Fessler Joseph F. (Walkersville MD) Solomon Roger E. (Manassas VA) Bernstein Eric F. (Philadelphia PA), Surface fluorescent monitor.
Teller, Eric; Stivoric, John M.; Kasabach, Christopher D.; Pacione, Christopher D.; Moss, John L.; Liden, Craig B.; McCormack, Margaret A., System for monitoring health, wellness and fitness.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.