METHOD AND DEVICE FOR STUDYING FUNCTIONAL STATE OF BRAIN AND METHOD FOR MEASURING SUBELECTRODE RESISTANCE Russian patent published in 2005 - IPC

Abstract RU 2252692 C2

FIELD: medicine; medical engineering.

SUBSTANCE: method involves recording multichannel electroencephalogram, electrocardiogram record and carrying out functional test and computer analysis of electrophysiological signals synchronously with multichannel record of electroencephalogram and electrocardiogram in real time mode. Superslow brain activity is recorded, carotid and spinal artery pools rheoelectroencephalogram is recorded and photopletysmogram of fingers and/or toes is built and subelectrode resistance of electrodes for recording bioelectrical cerebral activity is measured. Physiological values of bioelectrical cerebral activity are calculated and visualized in integrated cardiac cycle time scale as absolute and relative values of alpha-activity, pathological slow wave activity in delta and theta wave bandwidth. Cerebral metabolism activity dynamics level values are calculated and visualized at constant potential level. Heart beat rate is determined from electrocardiogram, pulsating blood-filling of cerebral blood vessels are determined from rheological indices data. Peripheral blood vessel resistance level, peripheral blood vessel tonus are determined as peripheral photoplethysmogram pulsation amplitude, large blood vessel tonus is determined from pulse wave propagation time data beginning from Q-tooth signal of electrocardiogram to the beginning of systolic wave of peripheral photoplethysmogram. Postcapillary venular blood vessels tonus is determined from constant photoplethysmogram component. Functional brain state is determined from dynamic changes of physiological values before during and after the functional test. Device for evaluating functional brain state has in series connected multichannel analog-to-digital converter, microcomputer having galvanically isolated input/output ports and PC of standard configuration and electrode unit for reading bioelectric cerebral activity signals connected to multichannel bioelectric cerebral activity signals amplifier. Current and potential electrode unit for recording rheosignals, multichannel rheosignals amplifier, current rheosignals generator and synchronous rheosignals detector are available. The device additionally has two-frequency high precision current generator, master input of which is connected to microcomputer. The first output group is connected to working electrodes and the second one is connected to reference electrodes of electrode unit for reading bioelectrical cerebral activity signals. Lead switch is available with its first input group being connected to potential electrodes of current and potential electrodes unit for recording rheosignals. The second group of inputs is connected to outputs of current rheosignals oscillator. The first group of outputs is connected to current electrodes of current and potential electrodes unit for recording rheosignals. The second group of outputs is connected to inputs of synchronous detector of rheosignals. Demultiplexer input is connected to output of synchronous detector of rheosignals and its outputs are connected to multichannel rheosignals amplifier inputs. Outputs of multichannel bioelectrical cerebral activity signals amplifier, multichannel rheosignals amplifier and electrophysiological signal amplifier are connected to corresponding inputs of multichannel analog-to-digital converter. Microcomputer outputs are connected to control input of lead switch, control input of multichannel demultiplexer, control input of multichannel analog-to-digital converter and synchronization inputs of current rheosignals oscillator and synchronous detector of rheosignals. To measure subelectrode resistance, a signal from narrow bandwidth current generator of frequency f1 exceeding the upper frequency fup of signals under recording is supplied. A signal from narrow bandwidth current generator of frequency f2≠ f1>fup is supplied to reference electrode. Voltages are selected and measured at output of each amplifier with frequencies of f1, f2 - Uf1 and Uf2 using narrow bandwidth filtering. Subelectrode resistance of each working electrode is determined from formula Zj=Ujf1 :(Jf1xKj), where Zj is the subelectrode resistance of j-th electrode, Ujf1 is the voltage at output from j-th amplifier with frequency of f1, Kj is the amplification coefficient of the j-th amplifier. Subelectrode resistance of reference electrode is determined from formula ZA=Ujf2 :(Jf2xKj), where ZA is the subelectrode resistance of reference electrode, Ujf2 is the voltage at output from j-th amplifier with frequency of f2, Jf2 is the voltage of narrow bandwidth current oscillator with frequency of f2.

EFFECT: wide range of functional applications.

15 cl, 10 dwg

Similar patents RU2252692C2

Title Year Author Number
METHOD AND DEVICE FOR STUDYING FUNCTIONAL STATE OF BRAIN 2003
  • Zakharov S.M.
  • Skomorokhov A.A.
  • Smirnov B.E.
RU2248745C1
EPILEPSY MANAGEMENT 2007
  • Butukhanov Vladimir Vasil'Evich
  • Sorokovikov Vladimir Alekseevich
RU2353411C2
DEVICE FOR EXAMINATION OF BRAIN BIOLOGICAL ACTIVITY 1993
  • Zakharov Sergej Mikhajlovich
  • Smirnov Boris Evgen'Evich
  • Skomorokhov Anatolij Aleksandrovich
  • Tsyganok Vasilij Fedorovich
RU2076625C1
METHOD FOR TREATING CEREBRAL TRAUMATIC DISEASE 2003
  • Butukhanov V.V.
  • Sorokovikov V.A.
  • Butukhanova E.V.
  • Sorokovikova A.V.
RU2263521C2
DRUG-FREE METHOD FOR PREVENTION OF HYPOXIC BRAIN CONDITION 2011
  • Baranova Tat'Jana Ivanovna
  • Mitrofanova Alla Vladislavovna
  • Janvareva Ideja Nikolaevna
RU2465820C1
METHOD OF EARLY DIAGNOSTICS OF CHRONIC DISORDERS OF CEREBRAL CIRCULATION CAUSED BY ARTERIAL HYPOTENSION 2010
  • Dolgova Irina Nikolaevna
RU2462182C2
METHOD FOR TREATMENT OF INITIAL MANIFESTATION OF INJURY IN CEREBRAL BLOOD SUPPLY 0
  • Brodovskaya Alla Mechislavovna
  • Ezhova Viktoriya Aleksandrovna
SU1813463A1
METHOD OF CARRYING OUT EXAMINATION IN CASE OF HEADACHE SYNDROME IN CHILDREN 2010
  • Mitrokhin Andrej Nikolaevich
  • Fastykovskaja Elena Dmitrievna
RU2427313C1
METHOD OF REOCAROTID CEREBROGRAPHY 2008
  • Gervaziev Viktor Borisovich
  • Mikhajlov Aleksej Gennad'Evich
RU2376931C1
METHOD FOR ESTIMATING VEGETATIVE TONE AND RESPONSIVENESS OF CEREBRAL BLOOD VESSELS 2004
  • Vajnshenker Julija Isaakovna
  • Ivanov Aleksej Jur'Evich
RU2292844C2

RU 2 252 692 C2

Authors

Zakharov S.M.

Skomorokhov A.A.

Smirnov B.E.

Dates

2005-05-27Published

2003-07-25Filed