• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    1461077 NMR analysis of local areas of a body K NIWA 2 Nov 1973 [2 Feb 1973] 51127/73 Heading G1N To obtain information about a region within a body, nuclear magnetic resonance signals from that region alone are analyzed. The signals from that region are distinguished from those of surrounding areas by subjecting the region to a magnetic field which differs from that applied to the other areas; the resonant frequency of, e.g. protons in the region is thus different from its value in the other areas and can be extracted by a suitable narrowband detector. The invention is applicable to analysis of internal regions of the human body. For this purpose a uniform main magnetic field Ho is applied to the body and is modified in the selected region by a field # Hs from one or more coils or a permanent magnet or from currents produced by pairs of electrodes on the body. It is also possible to arrange # Hs to be zero in the selected region, but to have a real value elsewhere. The coils or magnets can be external or internal of the body; when coils or electrodes are used their currents and phase can be adjusted to define the size and shape of the region. Alternatively the modification in the region can be provided by ferrite powder, paramagnetic ions or ultrasonic waves. A super-conducting magnet may be used. When ferromagnetic devices are used to provide the magnetic field they may be provided with a short circuit turn to prevent entry of the NMR radio frequency field. The main magnetic field or the detected frequency or the field applied to the region can be scanned through a small value to ease the problem of detecting the very sharp resonances involved. Blood measurements: analysis of the NMR signals allows blood flow velocity to be measured; the size of a blood vessel can also be found and used to find blood flow-rates. Blood flow pulses and respiratory movement also modulate the NMR signals so that pulse rate and respiratory condition can be monitored. In Fig. 7 blood flows along a vessel shown in dotted lines at speed v; the region Op has a magnetic field different from the other areas, and a pulse in coil Cp produces resonance in the flowing blood of that region. The field in Op is scanned along the vessel so that resonance does not immediately cease in the otherwise different field outside Op, and coils C 1 , C 2 pick up signals indicating the magnetization of the flowing blood. The coil signals can be combined to give the velocity of flow, the volume of the magnetized flowing region (and hence the vessel size), and the blood flow-rate. One coil can be used if its coupling with the vessel can be calculated. In another embodiment, Fig. 10, a main field is applied in region 3, and a local field in cylinder 12; the tested body is moved relative to cylinder 1 until modulation of the NMR signal at the blood pulse rate indicates that a blood vessel 2 lies wholly within the cylinder. The cylinder size is reduced until the modulated signal decreases, at which point the cylinder cross-section is the same as that of the blood vessel. Having thus found the vessel size the flow velocity can be found by measuring the blood pulse modulated NMR signals a known distance downstream and seeing how long a modulation pattern takes to occur at the downstream detector after it has occurred at the Fig. 10 detector. Two or more pick-up coils can be used in the NMR signal detector to compensate for signals from unwanted protons or for signals induced by the RF fields.
    公开号:SU852186A3
    申请号:SU731965963
    申请日:1973-09-29
    公开日:1981-07-30
    发明作者:Аби Зенуемон;Танака Кунио;Хотта Масао;Имаи Масааки
    申请人:Кичизо Нива (Фирма);
    IPC主号:
    专利说明:

    This invention relates to methods for obtaining internal information from selected areas of a target by nuclear magnetic resonance (NMR). spin echoes ij. However, this method can be applied only in the case of Moving Protons. The closest in technical essence to the proposed method is the method of acquiring internal information from a dedicated part of the target by the method of dead magnetic resonance, including the operation of applying an additional magnetic field to the target of a constant uniform magnetic field to the allocated part of the target of the high-frequency magnetic field H to the selected part of the target, to detect and process the signal 2. However, due to the heterogeneity of the additional bH itelnogo magnetic field measurement accuracy is low because no odnsch odnoe field reduces the signal / noise ratio. The purpose of the invention is to improve the accuracy of obtaining information. The goal is achieved by the method that in the method of obtaining internal information from a dedicated part of the target by nuclear magnetic resonance, including the imposition of a constant magnetic field HO on the target, an additional magnetic field H on the target site, a high-frequency magnetic field H on the dedicated portion of the target and signal processing, additional field h, H is uniform. FIG. 1 shows a field overlay scheme; in fig. 2 is a curve showing a change in the magnetic field in a dedicated area. A constant magnetic field HO is applied to the target 1 under investigation (Fig. 1) with magnets (not shown). The target to be investigated is scanned with 2 m 3 scanning coils, and the magnetic field b H created by coils 2 and 3 is applied to the extended section 4, being superimposed on the magnetic field H o. Magnetic Nole becomes equal to HO Н (Fig. 2) in the selected area within the interval X4 - except for the adjacent part
    权利要求:
    Claims (1)
    [1]
    Claim
    A method of obtaining internal information from an inserted portion of the '20 target by nuclear magnetic resonance, including the operation of applying to the target a constant uniform magnetic field, an additional magnetic field on the selected target, detecting and processing the signal, characterized in that, in order to increase accuracy, A uniform magnetic field is used as an additional magnetic field.
    类似技术:
    公开号 | 公开日 | 专利标题
    SU852186A3|1981-07-30|Method of producing inner data from given target portion
    US4608991A|1986-09-02|Method for in-vivo NMR measurements in the human breast to screen for small breast cancer in an otherwise healthy breast
    US6023636A|2000-02-08|Magnetic resonance apparatus and method for determining the location of a positionable object in a subject
    US6704594B1|2004-03-09|Magnetic resonance imaging device
    US5289127A|1994-02-22|Correction of signal distortion in an NMR apparatus
    EP0727050B1|1998-07-29|Nuclear magnetic resonance imaging rheometer
    JPH0658399B2|1994-08-03|Non-intrusive device for checking flow
    US20010011889A1|2001-08-09|Magnetic resonance imaging device
    JPH09117435A|1997-05-06|Measuring device of basic magnetic field of magnet of nuclear spin tomography device
    US4697147A|1987-09-29|Blood flow imaging using a CW NMR technique
    US4947837A|1990-08-14|Method of blood flow imaging
    US4626784A|1986-12-02|NMR imaging device
    US6700372B2|2004-03-02|Method for generating measurement signals in magnetic fields
    US4429277A|1984-01-31|Nuclear magnetic resonance apparatus utilizing multiple magnetic fields
    US5068610A|1991-11-26|Mri method and device for fast determination of the transverse relaxation time constant t2
    US5410248A|1995-04-25|Method for the simultaneous detection of velocity and acceleration distribution in moving fluids
    US5436562A|1995-07-25|Methods for the simultaneous detection of multiple components of motion in moving fluids
    Holz et al.1986|Modification of the pulsed magnetic field gradient method for the determination of low velocities by NMR
    Hu et al.1993|Localized real‐time velocity spectra determination
    US5309099A|1994-05-03|Method of determining real-time spatially localized velocity distribution using magnetic resonance measurements
    GB2366387A|2002-03-06|Electron paramagnetic resonance imaging device using microwave bridge translator
    US5541512A|1996-07-30|Method for the prevention of registration artifacts due to motion in magnetic resonance images
    US5469059A|1995-11-21|Method for the simultaneous detection of acceleration and velocity distribution in moving fluids
    US5517116A|1996-05-14|Method for the simultaneous detection of multiple components of velocity in moving fluids
    RU1422807C|1995-03-27|Marking nuclear-magnetic flowmeter
    同族专利:
    公开号 | 公开日
    FR2216580B1|1975-04-11|
    NL166543B|1981-03-16|
    DE2356647A1|1974-08-08|
    JPS49103693A|1974-10-01|
    GB1461077A|1977-01-13|
    NL166543C|1981-08-17|
    US3932805A|1976-01-13|
    NL7315322A|1974-08-06|
    DE2356647C2|1991-04-18|
    FR2216580A1|1974-08-30|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    BE543241A|1954-12-06|
    US2858504A|1955-06-13|1958-10-28|Varian Associates|Means and apparatus for improving the homogeneity of magnetic fields|
    US3419793A|1965-04-02|1968-12-31|Badger Meter Mfg Co|Volumetric flow measuring device employing pulsed paramagnetic resonance|
    DE1673037C3|1967-08-11|1975-04-10|Siemens Ag, 1000 Berlin Und 8000 Muenchen|
    US3789832A|1972-03-17|1974-02-05|R Damadian|Apparatus and method for detecting cancer in tissue|
    US3775671A|1972-07-03|1973-11-27|Chevron Res|Nuclear magnetism well logging method and apparatus|US4015196A|1974-04-05|1977-03-29|National Research Development Corporation|Analysis of materials|
    US4021726A|1974-09-11|1977-05-03|National Research Development Corporation|Image formation using nuclear magnetic resonance|
    DE2501794A1|1975-01-17|1976-07-22|Kraftwerk Union Ag|METHOD OF MEASURING A QUANTITY OF FLUID STREAMING THROUGH A PIPE USING MAGNETIC NUCLEAR RESONANCE|
    JPS51127785A|1975-04-30|1976-11-08|Hokkaido Daigaku|Measuring method of information around the surface of the substances t o be measured applying the nucleus magnet resonance phenomenon|
    GB1580787A|1976-04-14|1980-12-03|Mansfield P|Nuclear magnetic resonance apparatus and methods|
    GB1596160A|1976-12-15|1981-08-19|Nat Res Dev|Nuclear magnetic resonance apparatus and methods|
    DE2745039A1|1977-10-06|1979-04-12|Euratom|DEVICE FOR MEASURING THE FLOW RATE BY MEANS OF THE CORE RESONANCE|
    GB1584949A|1978-05-25|1981-02-18|Emi Ltd|Imaging systems|
    GB1584950A|1978-05-25|1981-02-18|Emi Ltd|Imaging systems|
    GB1601970A|1978-05-31|1981-11-04|Nat Res Dev|Methods of deriving image information from objects|
    US4318043A|1978-07-20|1982-03-02|The Regents Of The University Of California|Method and apparatus for rapid NMR imaging of nuclear densities within an object|
    US4297637A|1978-07-20|1981-10-27|The Regents Of The University Of California|Method and apparatus for mapping lines of nuclear density within an object using nuclear magnetic resonance|
    USRE32619E|1978-11-20|1988-03-08|Apparatus and method for nuclear magnetic resonance scanning and mapping|
    US4354499A|1978-11-20|1982-10-19|Damadian Raymond V|Apparatus and method for nuclear magnetic resonance scanning and mapping|
    DE2854774A1|1978-12-19|1980-07-10|Battelle Institut E V|Surface live examination appts. for body tissue etc. - measures nuclide density and both relaxation times using spin echo|
    US4339716A|1979-05-23|1982-07-13|Picker International Limited|Nuclear magnetic resonance systems|
    NL7904986A|1979-06-27|1980-12-30|Philips Nv|METHOD AND APPARATUS FOR DETERMINING A NUCLEAR SPIN DENSITY DISTRIBUTION IN PART OF A BODY.|
    DE2951018A1|1979-12-19|1982-02-11|Wilfried H. Dr. 5483 Bad Neuenahr Bergmann|Spin-echo measurement at eigen temp. of specimen - using superconducting coil screened by second enclosing superconducting coil|
    US4385277A|1980-01-21|1983-05-24|The Oxford Instruments Group Limited|Topical nuclear magnetic resonance spectrometer and method|
    FR2475282B1|1980-02-05|1985-10-04|Radiologie Cie Gle|ELECTROMAGNETIC COIL SYSTEM FOR EXAMINATION OF LARGE BODIES BY NUCLEAR MAGNETIC RESONANCE, AND HUMAN BODY IMAGING APPARATUS USING SUCH A SYSTEM|
    EP0048757A4|1980-04-04|1983-01-14|Meguer V Kalfaian|Field radator for curing cancer and other ailments.|
    FI64282C|1981-06-04|1983-11-10|Instrumentarium Oy|DIAGNOSISPARATUR FOER BESTAEMMANDE AV VAEVNADERNAS STRUKTUR OC SAMMANSAETTNING|
    DE3129906C3|1981-07-24|1996-12-19|Schering Ag|Paramagnetic complex salts, their preparation and agents for use in NMR diagnostics|
    US4957939A|1981-07-24|1990-09-18|Schering Aktiengesellschaft|Sterile pharmaceutical compositions of gadolinium chelates useful enhancing NMR imaging|
    DE3233050C2|1981-09-09|1997-04-24|British Tech Group|Process of high-resolution pulse nuclear magnetic resonance spectroscopy|
    US4528985A|1981-12-21|1985-07-16|Albert Macovski|Blood vessel imaging system using nuclear magnetic resonance|
    DE3209264A1|1982-03-13|1983-09-22|Bruker Medizintechnik Gmbh, 7512 Rheinstetten|METHOD FOR MEASURING THE MAGNETIC CORE RESONANCE FOR NMR TOMOGRAPHY|
    US4496907A|1982-05-06|1985-01-29|Dickey-John Corporation|Method and apparatus for non-destructively determining ingredients of a sample|
    EP0103372A3|1982-08-11|1986-05-07|Picker International Limited|Nuclear magnetic resonance method and apparatus|
    DE3378495D1|1982-08-19|1988-12-22|Picker Int Ltd|Nuclear magnetic resonance methods and apparatus|
    JPS5940843A|1982-08-31|1984-03-06|Tokyo Shibaura Electric Co|Nuclear magnetic resonance apparatus for diagnosis|
    US4594550A|1982-09-07|1986-06-10|Utsunomiya University|Method of scanning specifying magnetic field for nuclear magnetic resonance imaging|
    EP0106472B1|1982-09-17|1988-12-07|Picker International Limited|Nuclear magnetic resonance method and apparatus|
    DE3339192A1|1982-11-01|1984-07-05|Joachim Dr.rer.nat. 6645 Beckingen Nagel|Arrangement for determining the flow pattern in an object under investigation|
    JPH0243493B2|1982-11-08|1990-09-28|
    GB2135059B|1983-01-26|1986-09-03|Univ Gifu|A method for non-destructively grading fruits and other foodstuffs|
    US4556848A|1983-02-01|1985-12-03|The United States Of America As Represented By The United States Department Of Energy|Point sensitive NMR imaging system using a magnetic field configuration with a spatial minimum|
    US4590427A|1983-03-28|1986-05-20|The United States Of America As Represented By The United States Department Of Energy|Nuclear magnetic resonance apparatus having semitoroidal rf coil for use in topical NMR and NMR imaging|
    US4516582A|1983-05-02|1985-05-14|General Electric Company|NMR blood flow imaging|
    JPS60549U|1983-06-15|1985-01-05|
    US4613818A|1983-06-20|1986-09-23|The Medical College Of Wisconsin, Inc.|Nuclear magnetic resonance blood flowmeter|
    US4595879A|1983-11-14|1986-06-17|Technicare Corporation|Nuclear magnetic resonance flow imaging|
    US5618514A|1983-12-21|1997-04-08|Nycomed Imaging As|Diagnostic and contrast agent|
    JPH0211110B2|1983-12-22|1990-03-12|Nippon Electron Optics Lab|
    GB8401550D0|1984-01-20|1984-02-22|Picker Int Ltd|Nuclear magnetic resonance apparatus|
    FI73320C|1984-01-20|1987-09-10|Instrumentarium Oy|NMR SPOLARRANGEMANG.|
    JPH0617089Y2|1984-03-26|1994-05-02|日本電子株式会社|Nuclear magnetic resonance probe|
    FI75428C|1984-11-21|1988-06-09|Instrumentarium Oy|Procedure for mapping the nuclear magnetic properties of an object to be investigated.|
    PT81498B|1984-11-23|1987-12-30|Schering Ag|METHOD FOR PREPARING COMPOSITIONS FOR DIAGNOSTICS CONTAINING MAGNETIC PARTICLES|
    US4656026A|1984-12-10|1987-04-07|University Of Iowa Research Foundation|Magnetic resonanceimage enhancement compounds for specific areas of the brain|
    US4866387A|1985-05-08|1989-09-12|Mcw Research Foundation, Inc.|NMR detector network|
    US4724389A|1985-05-08|1988-02-09|Medical College Of Wisconsin, Inc.|Loop-gap resonator for localized NMR imaging|
    US4714886A|1985-07-16|1987-12-22|President And Fellows Of Harvard College|Magnetic resonance analysis of substances in samples that include dissipative material|
    US5720939A|1985-08-15|1998-02-24|Nycomed Imaging As|Method of contrast enhanced magnetic resonance imaging using magnetically responsive-particles|
    US4769601A|1985-08-22|1988-09-06|Amoco Corporation|Method of and apparatus for determining cement strength and extent of setting with a pulsed nuclear magnetic resonance spectrometer|
    GB8527021D0|1985-11-01|1985-12-04|Picker Int Ltd|Nuclear magnetic resonance imaging|
    US4697147A|1985-11-14|1987-09-29|Metriflow, Inc.|Blood flow imaging using a CW NMR technique|
    US5219554A|1986-07-03|1993-06-15|Advanced Magnetics, Inc.|Hydrated biodegradable superparamagnetic metal oxides|
    US4703272A|1986-08-29|1987-10-27|The Regents Of The University Of California|Apparatus and method for decoupling MRI RF coil from selected body portions using passive components|
    JPS63189134A|1987-02-02|1988-08-04|Toshiba Corp|Magnetic resonance imaging apparatus|
    JP2721839B2|1987-04-10|1998-03-04|財団法人新世代研究所|Magnetic resonance measurement device|
    FI874419A|1987-10-08|1989-04-09|Instrumentarium Oy|ANORDNING OCH FOERFARANDE FOER UNDERSOEKNING AV ETT OBJEKTS EGENSKAPER.|
    JPH0721471B2|1987-10-28|1995-03-08|アドヴァンスド・テクトロニクス・インコーポレーテッド|Nuclear magnetic resonance apparatus for testing constituents of body fluids|
    US4975644A|1989-03-29|1990-12-04|Kabushiki Kaisha Toshiba|Coil system for a magnetic resonance imaging system|
    US5144236A|1990-08-17|1992-09-01|Strenk Scientific Consultants, Inc.|Method and apparatus for r.f. tomography|
    GB9106686D0|1991-03-28|1991-05-15|Hafslund Nycomed As|Improvements in or relating to contrast agents|
    US5645065A|1991-09-04|1997-07-08|Navion Biomedical Corporation|Catheter depth, position and orientation location system|
    US5425367A|1991-09-04|1995-06-20|Navion Biomedical Corporation|Catheter depth, position and orientation location system|
    GB9200388D0|1992-01-09|1992-02-26|Nycomed As|Improvements in or relating to contrast agents|
    US5530355A|1993-05-13|1996-06-25|Doty Scientific, Inc.|Solenoidal, octopolar, transverse gradient coils|
    US5365172A|1992-08-07|1994-11-15|Brigham And Women's Hospital|Methods and apparatus for MRI|
    US5468467A|1993-04-23|1995-11-21|Bracco International B.V.|Methods for the in vivo measurement of the concentration of non-imaging nmr-detectable xenobiotic compounds|
    US5517992A|1994-12-27|1996-05-21|General Electric Company|Magnetic resonance imaging of shear-rate within mechanically vibrated materials|
    US6241671B1|1998-11-03|2001-06-05|Stereotaxis, Inc.|Open field system for magnetic surgery|
    US6208142B1|1998-12-07|2001-03-27|Transurgical, Inc.|Magnetic resonance apparatus and methods with shim adjustment|
    JP4090722B2|2001-10-23|2008-05-28|純一 小川|Magnetic fluid detection device|
    EP1454158A1|2001-11-23|2004-09-08|Koninklijke Philips Electronics N.V.|Method and system for acquiring spin labeled images by means of adiabatic flow criterion|
    GB0427686D0|2004-12-17|2005-02-02|Univ Basel|Method for detection and imaging of synchronous spin and charged particle motion|
    US7976518B2|2005-01-13|2011-07-12|Corpak Medsystems, Inc.|Tubing assembly and signal generator placement control device and method for use with catheter guidance systems|
    GB0508890D0|2005-04-29|2005-06-08|Oxford Instr Plc|Magnetic resonance apparatus and method|
    SG135077A1|2006-02-27|2007-09-28|Nanyang Polytechnic|Apparatus and method for non-invasively sensing pulse rate and blood flow anomalies|
    US8197494B2|2006-09-08|2012-06-12|Corpak Medsystems, Inc.|Medical device position guidance system with wireless connectivity between a noninvasive device and an invasive device|
    DE102007013564B4|2007-03-21|2017-11-09|Siemens Healthcare Gmbh|Method and device for automatic determination of radiation-attenuating objects by means of a magnetic resonance system|
    EP2410347A1|2010-07-23|2012-01-25|Universitätsklinikum Freiburg|Volume selective MRI by means of a spatially non-linear phase preparation and a windowed acquisition|
    WO2013036772A1|2011-09-08|2013-03-14|Corpak Medsystems, Inc.|Apparatus and method used with guidance system for feeding and suctioning|
    RU2619430C2|2015-05-26|2017-05-15|Федеральное государственное бюджетное образовательное учреждение высшего образования "Московский государственный университет имени М.В. Ломоносова" |Magnetic resonance imaging |
    US10602957B2|2015-06-30|2020-03-31|Varuna Biomedical Corporation|Systems and methods for detecting and visualizing biofields with nuclear magnetic resonance imaging and QED quantum coherent fluid immersion|
    CN105445307B|2015-12-08|2017-06-30|大连工业大学|The low-field nuclear magnetic resonance detection method of texture quality in a kind of sea cucumber salting process|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    JP48013508A|JPS49103693A|1973-02-02|1973-02-02|
    [返回顶部]