DE102007003565A1 - Device for reducing the synchronization of neuronal brain activity and suitable coil - Google Patents

Abstract

The invention relates to a method for reducing the desynchronization of neuronal brain activity and a device and coil suitable for this purpose. The device comprises a sensor for measuring a physiological feature and, according to the invention, at least one magnetic coil (2) which applies magnetic pulses to the brain which either reduces or completely suppresses pathological brain activity.

Description

The The invention relates to a device for desynchronizing neuronal Brain activity and a suitable coil.

at Patients with neurological or psychiatric disorders such as for example Parkinson's disease, essential tremor, dystonia or obsessive-compulsive disorder are nerve cell associations in circumscribed areas of the Brain, z. B. of the thalamus and the basal ganglia, pathologically active, for Example overclocked synchronously. In this case forms a large number of neurons sync action potentials that is, the neurons involved are firing excessively synchronous. In healthy patients, the neurons fire in these Brain areas qualitatively different, for example, in an uncorrelated way.

At the Parkinson's disease alters the pathologically synchronous activity the neuronal activity in areas of the cerebral cortex, such as in the primary motor cortex by For example, she imposes her rhythm on them, so that finally the muscles controlled by these areas phatological activity, z. B. a rhythmic trembling unfold.

at Patients who are no longer treated by medication can, depending on the disease and depending on whether the disease occurs unilaterally or bilaterally, a deep electrode implanted on one or both sides. Under the skin leads thereby a cable from the head to the so-called generator, which is a control unit with a battery, and for example in the area of the collarbone implanted under the skin. About the depth electrodes becomes a continuous stimulus with a high-frequency periodic sequence (pulse train with a frequency of> 100 Hz) of single pulses, z. B. rectangular pulses, carried out. The aim of this method is to fire the Suppress neurons in the target areas. The mechanism of action, which is based on the standard depth stimulation is not yet sufficiently clarified. The results of several studies speak that the standard deep stimulation is like a reversible Lesioning, d. H. like a reversible elimination of the Tissue, acts: The standard deep stimulation is suppressed the firing of the neurons in the target areas and / or related Brain areas.

adversely in this form of stimulation is that the energy consumption of the generator is very high, so the generator including battery often be exchanged operationally after about one to three years got to. Even more disadvantageous is that the high-frequency continuous stimulation as an unphysiological (unnatural) input in the field of the brain, z. As the thalamus or basal ganglia, in the course from a few years to the adaptation of the affected nerve cell associations can lead. To achieve the same stimulation success, must then due to this adaptation with higher stimulus amplitude be stimulated. The greater the stimulus amplitude is, the greater the probability that there are side effects due to the irritation of neighboring areas - such as Dy sarthrie (speech disorders), dysesthesia (zum Part of very painful sensations), cerebellar ataxia (Inability to be safe without outside help) or Schizophrenia-like symptoms etc. - comes. These side effects can not be tolerated by the patient. The treatment loses therefore in these cases after a few years their effectiveness.

Therefore, another method was proposed, as described in the DE 102 11 766.7 "Device for the treatment of patients by brain stimulation, an electronic component and the use of the device and the electronic component in medicine" is described, are applied in the demand responsive stimuli in each target area, which desynchronize morbidly synchronized neuronal activity. This device is not simply to suppress morbidly synchronous firing, as in standard depth stimulation, but to bring it closer to the physiological, uncorrelated firing pattern Increasing the stimulation amplitude can lead to side effects, be prevented.

The German patent application 103 18 071 discloses a method and an apparatus in which a demand-controlled application of stimuli takes place in the respective target area. The aim of these methods and device is not simply to suppress the morbid synchronous firing, but bring closer to the physiological, unkor relierte fire pattern. As a result, on the one hand the power consumption is reduced and on the other hand adaptation processes of the nerve tissue which require an increase of the stimulation amplitude are prevented.

The main disadvantage of the mentioned stimulation methods is that they require an operative placement of the stimulation electrodes in the brain and that in the case of the standard deep stimulation - due to the power consumption - the generator including the battery often has to be exchanged operationally after one to three years. The short time available for calibration during an operation prevents the calculation of frequency-dependent phase resetting maps, with the help of which the pathological synchronization processes with changing main frequency component can be effectively desynchronized. The use of these Desynchronostionsverfahren occurs only in the late stages of the disease, which means that here the healing aspect of the stimulation, for example because of the advanced cell degeneration in the target area can not be fully exploited.

From the WO 03/85546 A1 There is known a method and a device with which the brain activity can be influenced. The method and the device serve to achieve a predetermined behavioral goal. The device described there employs electromagnetic fields using various algorithms, but it is not possible to derive an explicit therapeutic effect from these algorithms for the purpose of reducing the synchronization of neuronal activity. Furthermore, this text does not include the therapeutically relevant component of changing coupling topologies nor does it provide an algorithm for reducing the synchronization of neuronal populations.

From the WO 03/098268 A1 is a magnetic field stimulation is known, which is used for diagnostic purposes. The WO 03/082405 shows a method for increasing the performance. One method of suppressing brain activity is from the scriptures WO 00/74777 and WO 01/012236 A1 known. The font US 03/082507 A1 discloses methods for treating psychiatric and developmental diseases, such as stuttering or depression, using various stimulation protocols, e.g. B. single pulse, paired pulse, triple stimulation and low or high frequency repetitive stimulation, which are applied by means of one or more stimulation coils. Two main forms of coils are known, namely the simple O-shape and the shape of an eight ∞.

The Up to now known stimulation solenoids can at most in two directions stimulate the brain and thus at most Stimulate two target populations or subpopulations.

It the object of the invention is a method and a device with which patients can be treated without a costly, high-risk and cost-intensive Brain surgery must be performed. Preferably should Patients can be treated who have a permanent or transient oscillatory component but is based on a Operation can not be performed or where the suffering of the patients so far was not so strong that they take the risks and costs of brain surgery, that is, an operation should be superfluous become. It should also be possible to treat patients which uses complex and prolonged calibration procedures need to be or where the main frequency component the pathological rhythmic activity is subject to fluctuations so that the physiologically relevant coupling topologies of physiological relevance due to long-lasting desynchronization internally or decoupled from other brain regions, that is, the diseased brain areas are brought to the healthy state. It should be created the possibility of frequency-dependent To create phase resetting maps, with the help of which the pathological Synchronization processes with changing main frequency component can be effectively reduced. The term diminished or reduced thereby also includes the complete elimination of Synchronization. It should be a treatment of patients in one be possible earlier in the disease. It should not only decoupling of the affected neurons, but it should be a physiological change of the neurons be brought about, for example, a Recluster or a dephosphorylation of the ion channels. It's supposed to be a coil be created with a stimulation of more than two Directions is possible.

outgoing of the preamble of claim 1, the object is achieved according to the invention with the features specified in the characterizing part of claim 1.

With the method and the device according to the invention, it is now possible to treat patients without the need for elaborate, high-risk and cost-intensive brain surgery. Preferably, patients may be treated who are underpinned by a permanent or transient oscillatory component, but who can not undergo surgery, or who have not experienced enough patient suffering to take the risks and costs of brain surgery , Patients may also be treated for which complex and prolonged calibration procedures must be used, or where the major frequency component of pathological rhythmic activity may vary, such that the physiologically relevant coupling topologies of physiological relevance are due to prolonged reduction in synchronization internally or by other brain regions are decoupled, that is, the diseased brain areas are brought to the healthy state. It provides the ability to create frequency-dependent phase resetting maps that can effectively reduce pathological synchronization processes as the main frequency component changes. It is according to the invention a treatment of patients in an earlier stage of the disease possible. It will a physiological change of the neurons brought about, for example, a Reclustern or a dephosphorylation of the ion channels. Brain surgery can be dispensed with and the coil of the invention can be stimulated in more than two directions. For example, a stimulation in four directions is possible. Diseases can be successfully treated that are based on a pathologically synchronous oscillatory component. By way of example, but not limitation, epilepsy, Parkinson's disease, depression, obsessive-compulsive disorder may be mentioned. Tumor patients with synchronous high-amplitude neuronal population near the tumor can be treated.

advantageous Further developments of the invention are in the subclaims specified.

The in the description given process characteristics are in the Device according to the invention by a controller embodied that is the device to execute the method features controls. Each specified Process step thus reveals a device that a Having control that performs the method. On this Way, disclosed method features are also to be construed as device features.

The Figures show exemplary embodiments of the device and the coil according to the invention.

It shows:

1 : A device according to the invention

2a -e .: coils

3 : Representation of excited subpopulations

4a : Stochastic multi-channel excitation by means of a pair of coils wound in a figure-of-eight form

4b : Stochastic multi-channel excitation with a coil wound in a figure-eight.

5a : Multi-channel excitation, where the randomness of the pulses is reduced by means of a pair of eight coils.

5b : Multi-channel excitation, where the randomness of the pulses is reduced by means of an eight-coil.

6 : Multi-channel excitation, where the randomness of the pulses is reduced by means of a coil in figure-of-eight shape.

7 : Multi-channel excitation, where the randomness of the pulses is reduced by means of a simple coil

8th : Simulation results for the stimulation of a synchronous Neuronenpopula tion by means of a four-coil and stochastic multi-channel excitation.

9 : Temporal evolution of coupling among neurons.

The device according to 1 includes a buffer amplifier 1 , to the at least one magnetic coil 2 as well as sensors 3 connected to the detection of physiological measuring signals. The isolation amplifier is still connected to a unit 4 for signal processing and control connected to a stimulator unit 8th is connected to the signal generation. The stimulator unit 8th for the signal generation is available with at least one solenoid coil 2 in connection. At the entrance of the sensors 3 in the isolation amplifier 1 there is a relay 9 or transistor. The relay 9 is controlled by the stimulation unit. The unit 4 is over a line 10 with a telemetry transmitter 11 which is connected to a telemetry receiver 12 communicating, which in this example is outside the device and to which a means of visualizing, processing and storing the data 13 connected. As sensors 3 For example, epicortical electrodes, deep electrodes, brain electrodes or peripheral electrodes can be used. The magnetic coils 2 are attachable to the patient's head.

2a A simple solenoid known in the art.

2 B , c: magnetic double coils, which either correspond to two intersecting circles or which are composed of two substantially elliptical shapes.

2d : In 2d is a four-coil, which is composed of four individual coils whose centers mark a square.

2e : In 2e a four-coil is shown, which is composed of four individual coils whose centers mark a parallelogram. The angle between the two axes, which run through the centers of the diagonally lying coil parts is preferably 80 ° 70 °.

3 An exemplary representation of the four excited neural subpopulations ( 4 - 7 ) of a brain substrate ( 2 ) by means of a four-coil ( 1 ). The üb parts of the brain substrate are not excited ( 8th ). Overall, the quad coil can activate up to four separate subpopulations independently. The dashed lines show the induced magnetic field ( 3 ).

4a Stochastic multi-channel excitation by means of a four-coil (here a pair of coils wound in a figure-eight shape). The temporal course of the applied stimuli ( 3 ) over the first coil ( 1 ), and the second coil ( 2 ). The orientation ( 4 ) of the current flow in the coils is marked with the positive and negative values + and - of the pulses. The sequence of pulses ( 3 ) is stochastically distributed in time and the pulses ( 3 ) may not overlap.

4b Stochastic multi-channel excitation by means of a double coil (in this case a coil wound in a figure-eight shape). The temporal course of the applied stimuli ( 2 ) over the coil ( 1 ). The orientation ( 3 ) of the current flow in the coils is marked with the positive and negative values + and - of the pulses. The sequence of pulses ( 2 ) is stochastically distributed in time and the pulses ( 3 ) may not overlap.

5a Reduced stochastic multi-channel excitation by means of a four-coil (here a pair of coils wound in a figure-eight shape). The temporal course of the applied stimuli ( 3 ) over the first coil ( 1 ), and the second coil ( 2 ). The orientation ( 4 ) of the current flow in the coils is marked with the positive and negative values + and - of the pulses. The sequence of pulses ( 3 ) is ordered in time, ie the sequence of pulses is fixed, z. B. the positive pulse of the first channel follows the positive pulse of the second channel, which in turn follows a negative pulse of the first channel, and so on. The time interval of the individual pulses to each other but has a stochastic characteristic. The pulses ( 3 ) may not overlap.

5b Reduced stochastic multi-channel excitation by means of a double coil (in this case a coil wound in a figure-eight shape). The temporal course of the applied stimuli ( 2 ) over the coil ( 1 ). The orientation ( 3 ) of the current flow in the coils is marked with the positive and negative values + and - of the pulses. The sequence of pulses ( 2 ) is ordered in time, ie the sequence of pulses is fixed, z. B. the positive pulse of the first channel follows the positive pulse of the second channel, which in turn follows a negative pulse of the first channel, and so on. The time interval of the individual pulses to each other but has a stochastic characteristic. The pulses ( 3 ) may not overlap.

6 A schematic representation of the streams ( 2 ), the magnetic fields ( 3 ) and the induced currents in the brain ( 5 ) during a simple excitation by means of a coil in figure-of-eight form ( 1 ). The maximum of the induced currents has a focal character ( 5 ).

7 A schematic representation of the streams ( 2 ), the magnetic fields ( 3 ) and the induced currents in the brain ( 5 ) during a simple excitation by means of a simple coil ( 1 ). The maximum of the induced currents has an annular character ( 5 ).

8th The fire density ( 1 ), the extent of synchronization ( 2 ) and the median synaptic coupling ( 3 ) of a neural network (10 x 10 neurons) before, during and after stimulation with reduced stochastic multi-channel excitation. The beginning of the stimulation is indicated by the arrow ( 4 ) and the stochastic pulse sequences are marked with the black bars in the lower part of the graphs ( 5 ).

9 The temporal evolution of the coupling matrix of the network from the 8th before, during and after a stimulation with a reduced stochastic multichannel excitation. For each point in time, the coupling matrix is represented as a gray value column in the figure. The strength of the coupling is coded with a gray value. The beginning of the stimulation is indicated by the arrow ( 1 ) and the end of the stimulation is indicated by the arrow ( 2 ).

In The neurons fire in the pathological state before the stimulation in common mode and have a very strong coupling with each other. After switching on the stimulation, the couplings between reduced to the neurons. After a longer stimulation (over 600 cycles in the simulation) will be no stimulation More needed because the network is permanently in the desynchronous Condition remains and the morbid strong couplings between the neurons were degraded.

The magnetic coil 2 can in principle be present in various embodiments. The term "magnetic coil" is intended to include in the content any body which is capable of inducing a magnetic field which is suitable for the establishment of an electric field which leads to the selective activation of the neuron population.

According to the invention, the device comprises at least one magnetic coil 2 , She can, too 2 . 3 . 4 or more solenoids 2 include.

• a) eine einfache Magnetspule (entspricht 2a),
• b) eine Anordnung vor zwei Spulen, welche in geringem Abstand voneinander sind, so dass sie sich entweder berühren oder fast berühren. Der Abstand kann beispielsweise 1 bis 5 mm betragen. Diese Anordnung wird im Folgenden als Doppelspule bezeichnet. Die Spulen können sich auch berühren, sofern sie isoliert sind. (Entspricht 2b und 2c)
• bb) eine Spule, deren Drähte in einer Achterform gewickelt sind. Auch diese Spulenform wird als Doppelspule bezeichnet. (Entspricht 2b und 2c)
• c) eine Anordnung von drei Spulen, deren Mittelpunkte vorzugsweise die Eckpunkte eines Dreiecks bilden.
• d) in einer besonders bevorzugten Ausführungsform vier Spulen (= Viererspule), entsprechend einem Paar von in Achterform gewickelten Spulen, die im Wesentlichen senkrecht, vorzugsweise senkrecht aufeinander angeordnet sind. (Entspricht 2d)
• dd) Vier im Wesentlichen Ringförmige Spulen (= Viererspule), deren Mittelpunkte im wesentlichen die Eckpunkte eines Vierecks, vorzugsweise eines Quadrates bilden (Entspricht 2d und 2e).

Possible coil forms are, for example:

• a) a simple solenoid coil (corresponds 2a )
• b) an arrangement in front of two coils, which are at a small distance from each other, so that they either touch or almost touch. Of the Distance can be for example 1 to 5 mm. This arrangement is referred to below as a double coil. The coils can also touch, provided they are insulated. (Equivalent 2 B and 2c )
• bb) a coil whose wires are wound in a figure-of-eight shape. This coil shape is referred to as a double coil. (Equivalent 2 B and 2c )
• c) an arrangement of three coils whose centers preferably form the vertices of a triangle.
• d) in a particularly preferred embodiment, four coils (= four-coil), corresponding to a pair of coils wound in a figure eight, which are arranged substantially perpendicular, preferably perpendicular to each other. (Equivalent 2d )
• dd) Four substantially annular coils (= quadruple coil), the centers of which essentially form the vertices of a quadrilateral, preferably of a square (corresponds 2d and 2e ).

The Coils should have an electrical insulation, or it should no short circuits can occur.

in the For the purposes of the invention may be a four-coil of individual coils and / or figure eight-shaped coils.

The Magnetic coils are examples of means for generating a Magnetic field.

The spools 2 be over the control 4 supplied with electricity, which allow the construction of magnetic fields of, for example 1.1 to 2.3 Tesla. The optimal magnetic field strengths can be determined by calibration. Basically, any magnetic field strength is suitable, which still has a physiological effect. Exemplary, lower magnetic field strengths are 0.1 Tesla or 0.01 Tesla. The information is not limiting.

Preferably The coils have an inner diameter of 1 cm to 5 cm.

Of the Outside diameter can be up to 8 cm, for example.

The unit for signal processing and control 4 may comprise means for univariate and / or bivariate and / or multivariate data processing, as described, for example, in US Pat "Detection of n: m Phase Locking from Noisy Data: Application to Magnetoencephalography" by P. Tass, et al in Physical Review Letters, 81, 3291 (1998) is described. The univariate and / or bivariate and / or multivariate data processing preferably originates from statistical physics and preferably from the area of stochastic phase resettings.

According to the invention, the device is equipped with means which detect the signals of the sensors 3 as pathological and in the presence of a pathological pattern on the magnetic coils 2 Give off stimuli that cause the pathological neuronal activity either suppressed short-term or modified so that it is closer to the natural, physiological activity. The pathological activity differs from the healthy activity by a characteristic change of its pattern and / or its amplitude.

The means for recognizing the pathological pattern are a computer which receives the measured signals from the sensor 3 processed and compared with data stored in the computer. The computer has a data carrier, which stores data that was determined during a calibration procedure. By way of example, these data can be determined by systematically varying the stimulation parameters in a series of test stimuli and the success of the stimulation via the sensor 3 by means of the control unit 4 is determined. The determination can be done by uni-, bi-, and multivariate data analysis to characterize the frequency characteristics and the interaction (eg coherence, phase synchronization, directionality and stimulus-response relationship), as described, for example, in US Pat PA Tass: "Phase Resetting in Medicine and Biology. Stochastic Modeling and Data Analysis. "Springer Verlag, Berlin 1999 is disclosed.

The Device according to the invention comprises means for Create frequency-dependent phase resetting maps (FPRK).

in the morbid state, the neurons fire very synchronously. One measures the activity of this neural population, e.g. B. with the Derivation of a local field potential, can be measured in the Signals strong oscillatory components that synchronous Firing of the neurons correspond to be detected. In practice It is common to observe that the frequency of the oscillatory Activity is subject to frequent fluctuations. It therefore can not be assumed that during the oscillations in different frequencies the answers of the neurons to one Stimulation remain constant. Therefore you will not expect that the vulnerable phase, in which stimulating the network to its Desynchronization leads, identical for all frequencies is.

The purpose of the frequency-dependent phase-resetting maps is to increase the vulnerable phase as a function of the instantaneous frequency of the oscillatory activity of the pathological area determine. This makes it possible to perform stimulation in the vulnerable phase even for non-stationary oscillatory processes. Since the determination of the fPRK requires complex measurements, these can only be determined with the non-invasive stimulation method, magnetic field stimulation. Thus, the device according to the invention has egg nen significant advantage over the devices from (the PT double pulse and soft-phase resetting.)

For The determination of FPRK will be a long sequence of single stimuli applied with constant parameters at different times. In the data analysis, for every stimulus, its initial phase and determines the instantaneous frequency of the oscillation, e.g. B. by means Hilbert transformation and filtering, as well as the course of the phase during and after the stimulus application (the calculation period). Then becomes one for each instantaneous frequency of the oscillation Phase resetting curve for each time point t in the whole Calculation period constructed. A phase resetting curve maps the one for the time t after the stimulation of each value the initial phase, the phase at this time t. In the next Step will curve the number of turns of the phase resetting for determined every time t. The number of turns indicates how often the Phase after stimulation at time t the range between 0 to 2PI goes through during the initial phase goes through this range of values once. This is equivalent to the middle gradient of the phase resetting curve. The determination The vulnerable phase will now begin with the determination of the change the number of turns from 1 to 0 performed. The vulnerable phase is now in the range of the maximum absolute gradient of the last one Phase resetting curve with the number of turns 1 to find. Should be for some instantaneous frequencies this transition between 1 and 0 can not be found, one repeats the stimulus application with a higher stimulation amplitude.

The fPRK are then stored in the device. While For stimulation with single stimuli, the device calculates the phase and the instantaneous frequency and selects from the fPRK the optimal combination of parameters.

The device according to the invention therefore comprises a computer which contains a data carrier which carries the data of the clinical picture, compares with the measured data and, in the case of the occurrence of pathological activity, a stimulus signal to the magnetic coil 2 gives off, so that a stimulation of the brain tissue takes place. The data stored in the data carrier of the clinical picture can be either person-specific, determined by calibration optimal stimulation parameters or a data pattern, which has been determined from a patient collective and typically occurring optimal stimulation parameters. The computer recognizes the pathological pattern and / or the pathological amplitude.

The used for the treatment of pathological findings Stimulus species are known in the art. It can, for example longer periodic episodes of single or more complex ones Stimulus sequences are used. Examples of these complex On the one hand, stimuli are stochastic multichannel stimuli. While stochastic multi-channel excitation, pulses or pulse trains over different coils and not overlapping in different directions and randomly applied at the time of onset. The amplitude and frequency of the individual pulses in pulse trains can be random vary (noise processes / random processes), where the strength of the variations is adapted to the pathological feature. Under An excitation via a channel is understood as influencing the neural activity of a subpopulation in the brain. In a multi-channel excitation, the activity of several Subpopulations influenced. The excited subpopulations can overlap. As a stimulation channel is the stimulation a subpopulation by means of the magnetic field.

Of the stochastic multichannel stimulus causes the excited subpopulations show fire behavior independent of each other in time goes into an uncorrelated firing of the individual populations. Surprisingly you get a significantly reduced synchronization, too if the extent of stochastic variation of time intervals between the pulses in different channels clearly is reduced. Basically, by changing the current direction be achieved in the coil that stimulates different subpopulations become. This means that with a simple coil two subpopulations can be stimulated. This also applies to two Coils or a figure-eight coil.

When using two simple coils or an eight-shaped coil, in addition, the focusing of the resulting electric field can be improved. The use of three coils allows the excitation of 6 different subpopulations. When 4 individual coils are used, arranged to substantially overlap at one point, even 12 different subpopulations can be excited by changing the combination of coils or the direction of current flow. A four-coil coil composed of two 8-row coils makes it possible to excite 4 subpopulations. Since the excitation of the neurons in the target population depends on the angle of the axons to the electric field, with the double coil up to 4 Subpopulations are selectively stimulated. The individual subpopulations differ from each other by the angle they form with the induced electric field.

In The consequence of the applied stimuli is the pathological activity in the case of using longer periodic sequences of Individual stimuli typically briefly suppressed and in the case of the more complex stimulus sequences, typically the natural, not brought close to morbid activity or her perfect equalized.

exemplary the following types of irritation can be cited:

Longer periodic episode of Individual stimuli:

While such a consequence becomes a short single stimulus (single on and off the stimulation) repeatedly applied. Preferably, the individual stimuli applied in the vulnerable phase of oscillations

Complex stimulus sequence:

When a complex stimulus sequence becomes a set of turn-on and turn-off processes the simulation unit refers to only over several Stimulation channels are distributed and in number and parameters (such as duration, amplitude, shape) are variable.

pulse train:

When a pulse train becomes a lot of on and off operations the simulation unit refers to only one Stimulation channel distributed and variable in number and parameters are.

The device according to the invention is preferably designed as it is in the case where the sensor 3 after the irritation detects a loss of pathological activity, the stimulation is interrupted.

For this purpose, the computer determines whether the pathologically increased amplitude or the pathologically increased pronounced pattern is present. This is done by means of the data analysis realized by the electronics. Once these pathological features are detected again, the next stimulation begins in the same way. The stimulation is switched on and off either by a control unit or by two control units communicating with each other, which in 1 as a control unit 4 are summarized.

The control unit 4 For example, it may include a chip or other electronic device with comparable computing power.

The control unit 4 controls the solenoid 2 preferably in the following manner. About the stimulator unit 8th then targeted stimuli on the magnetic coils 2 passed on to the target region in the brain.

Furthermore, the device according to the invention is preferably provided with means for visualization and processing of the signals as well as for data backup 13 via the telemetry receiver 12 in connection. The unit can 13 have the data analysis methods mentioned below.

Furthermore, the device according to the invention via the telemetry receiver 12 with an additional reference database in connection for example to accelerate a calibration process.

The 2a -e show by way of example magnetic coils which are suitable for magnetic stimulation. These are:

2a A simple solenoid known in the art.

2 B , c: magnetic double coils, which either correspond to two intersecting circles or which are composed of two substantially elliptical shapes.

2d : In 2d is a four-coil, which is composed of four individual coils whose centers mark a square.

2e : In 2e a four-coil is shown, which is composed of four individual coils whose centers mark a parallelogram. The angle between the two axes, which run through the center points of the diagonally lying coil parts is preferably 80 ° 70 °.

The spools 2 B . 2c . 2d and 2e are particularly effective. With them, a penetration depth of the magnetic field in the cortex up to 2 cm can be effected.

The spools 2d and 2e are particularly effective in reducing synchronicity and dividing a synchronous neuron population into two or more uncorrelated subpopulations.

In The invention will be described below in its general form become.

According to the invention with the magnetic coils 2 Magnetic fields induce which generate electrical fields in the brain and thus the intracortic currents to apply stimulus patterns in the target areas of the brain.

The respective magnetic field is perpendicular to the current direction.

Will be a simple solenoid 2 after the example 2a ), it induces a simple magnetic field which causes a circular electrical gradient in the brain tissue that can be used for stimulus application.

In the embodiment of the examples 2 B ) and 2c ) forms a very good focus of the magnetic fields below the point of the coils where they come closest, so that a very good stimulation is effected. The current direction in the area of the maximum spatial approach of the coils must have the same direction, so that the currents and thus the magnetic field do not cancel each other or reduce Depending on the direction of current flow, the magnetic field has an orientation in one of two opposite directions.

In the embodiments of the example 2d ) and 2e ) training of current flow in a brain in four directions is possible. In each case two opposite directions are generated by two double coils, which preferably form the diagonal vertices of a quadrangle. The formed by this coil shape temporally not overlapping trained electric fields preferably include an angle of 90 °. This can cause a special decoupling of the neural activity. In a less preferred embodiment, the arrangement of the coils differs from that of an ideal symmetry and / or overlaps of the coils, so that an angle can be formed between the two electric fields which is different from 90 °. The angle can reach 75 °, for example. However, the best healing and treatment successes are achieved when an angle of 90 ° is formed. Good results are also achieved with a deviation of 90 ° ± 5 °.

in principle Other coil shapes are possible.

With the electric fields generated by the magnetic coils or their Timing and alignment, it is possible in defined Brain regions produce stimuli that cause desynchronization and even cure the diseased regions. With the electric fields can also be electrical applied electromagnetic stimulus pattern that determines one temporal sequence and spatial extent and / or spatial Have alignment.

It Different stimulus patterns can be applied.

When Stimuli are single pulses in question, a duration in the sub-millisecond range of, for example, 200-500 μs.

With These individual pulses can be a low-frequency stimulation of a Frequency of less than one Hz. It can also high-frequency stimulus sequences of a frequency of over one Hz are applied to 200 Hz, for example.

With the method and the device according to the invention becomes a desynchronization of neural activity technically achieved differently than with the devices used by stimulating electrodes Make use. Instead of a stimulation electrode in the morbid placing a synchronous nerve cell dressing, a magnet coil is about positioned in the area, so that the maximum of the magnetic coil in the brain induced electrical gradient in the target population lies. (= Induction of electric fields in the brain) can with different stimulation methods. these can be chosen depending on the disease: Single stimulus, compound stimuli, stochastic and deterministic Multi-channel stimulation. The device is not on a specific Stimulation technique determines, but can as needed the algorithms vary to reduce synchronization. An essential component the operation of the device is the change of Coupling topologies within or between neuronal populations. The change of the coupling technologies becomes essentially produced by an uncorrelated activity in brain tissue and leads to a minimization of stimulation after Achieving the treatment goal, that is, no stimulation after the healing process more is needed.

Example: Reduction of synchronization by means of stochastic multichannel excitation:

For example, by means of a double coil 2d For example, the following stimuli can be delivered via two stimulation coils: a set of pulse trains is applied via each coil, whereby the stimulation phases must not overlap and two of the pulse trains are applied by means of the same coil, only with the reverse Polarity.

In 8th For example, the stochastic multi-channel excitation is shown. In the morbid state before the stimulation, the neurons fire in common mode and have a very strong coupling with each other. This can be seen in the high fire density and the high degree of synchronization. To switching on the stimulation by means of the stochastic multichannel excitation ( 4 ), the synchronous activity in the network is significantly reduced. In addition, as a result of continuous desynchronization, the couplings between the neurons are reduced. This leads to a weakening of the synchronization tendency in the network and a reduction in the frequency of the stimulation application. After prolonged stimulation (over 600 cycles in the simulation), stimulation is no longer needed because the network remains permanently in the desynchronized state, ie the network is healed. A four-coil with α = 90 ° ( 2d ) used.

The stimulation of the four subpopulations happens randomly or randomized with a randomization factor RF = K + S · epsilon with (K = T / 4, S = 0.2) ie the individual subpopulations are separated by a distance of A = T / 4 + S Epsilon is excited, where Epsilon is a normally distributed random process with the expected value 0 and the variance is equal to 1, and T is the period of the rhythm to be desynchronized. After a pulse train with duration D is switched on at time t ₁ , the turn-on point t _{2 of} the next pulse train t ₂ = t ₁ + T / 4 + S · epsilon is calculated. If the turn-on time t _{2 is} less than (t ₁ + D), ie the pulse trains would overlap, additional factors (T / 8 + S * epsilon) are added until t _{2 is} greater than (t ₁ + D). The individual subpopulations are successively stimulated one after the other. During the stochastic multichannel excitation the pathological synchronization is clearly suppressed ( 8a , b), that is, the firing of the neuronal population shows a clearly reduced amplitude ( 8a ) and also a reduction of synchronization indices ( 8b ) If the stochastic multichannel stimulation is applied over a longer period of time, it leads to a recovery / coupling reduction of the target area ( 8th . 9 ), where the decoupling has a much slower dynamics than the synchronization behavior. The healthy target area no longer needs stimulation.

In an alternative embodiment of the stochastically reduced Multi-channel excitation, pulse trains are temporally offset by T / 4 applied, where T is the mean period to be desynchronized Rhythm is.

These Stimulation method is a mild noninvasive procedure that exploits that the neurons in the affected areas plastic processes subject, depending on the strength of synchronicity of firing. A high synchronicity leads to strengthen the coupling between neurons and / or neuron polulations and low synchronicity builds the coupling between neurons and / or neuron populations.

Example:

According to the pathological neuronal activity A) via a sensor such as a) brain electrode, z. B. a depth electrode, a b) epicortical electrode or c) measured a muscle electrode and serves as a feedback signal, ie control signal, for an on-demand stimulation B). The feedback signal from the sensor 3 is via a line to the isolation amplifier 1 transmitted. Alternatively, the feedback signal can also be transmitted telemetrically without the use of an isolation amplifier. In the case of telemetric transmission is sensor 3 connected to an amplifier via a cable. The amplifier 9 is with a telemetry transmitter 11 connected via a cable. In this case are sensor 3 and amplifiers 9 and telemetry transmitter, for example, implanted in the area of an affected limb, while the telemetry receiver via a cable with the control unit 4 connected is. This means that, unlike the standard continuous stimulus, the activity is measured and the measurement signal is used as the trigger for on-demand stimulation.

• I. Messung über den Sensor 3, beispielsweise Messung von neuronaler Aktivität, die aus der Hirnrinde stammt, entweder über eine implantierte Elektrode b) oder vorzugsweise eine atraumatische epikortikale Elektrode b) (Sensor 3), d. h. eine Elektrode die auf dem Gehirn aufliegt und fixiert ist, aber nicht in das Gewebe eindringt und auf diese Weise ein lokales Elektroencephalogramm von einem betroffenen Areal der Hirnrinde, z. B. dem primären motorischen Cortex, ableitet.
• II. Bei Patienten, die primär an einem Tremor leiden, kann auch die Messung von muskulärer Aktivität durch Elektroden c) (Sensor 3, vorzugsweise telemetrisch mit Steuereinheit 4 verbunden) im Bereich der betroffenen Muskulatur erfolgen.

For the measurement A) of the neuronal activity, there are the following different possibilities:

• I. Measurement via the sensor 3 for example, measurement of neuronal activity originating from the cerebral cortex, either via an implanted electrode b) or preferably an atraumatic epicortical electrode b) (sensor 3 ), ie an electrode which rests on the brain and is fixed, but does not penetrate into the tissue and in this way a local electroencephalogram of an affected area of the cerebral cortex, z. B. the primary motor cortex derived.
• II. In patients with primary tremor, the measurement of muscular activity by electrodes may also be c) (Sensor 3 , preferably telemetric with control unit 4 connected) in the area of the affected musculature.

The pathological neuronal activity can in principle also occur in different neuron populations. That's why several, via sensors 3 Measured signals can be used to control the stimulation. Whenever a pathological feature of the activity is detected in at least one of the neuron polypulations, an irritation is triggered.

The measuring signal or the measuring signals serve or serve as feedback signals. This means that stimulation takes place as a function of the activity detected via the measuring signal. Whenever a pathological feature of neuronal activity (that is, pathologically increased amplitude or pathologically increased pronounced activity pattern) begins and increases, is stimulated.

there the stimulation B) can take place in different ways.

Demand-driven stimulation for reduction the synchronization:

These procedures are used when pathologically synchronized nerve cell activity in the target area (eg, in epilepsy disease in areas of the cortex) or in another area or muscle relevant to the disease (via sensors 3 derived) is present. This is for example determined by the fact that the sensors 3 measured signals in the frequency range which is characteristic of the pathological activity. As soon as a band-pass filtered measurement signal exceeds a threshold determined in the calibration procedure, it is transmitted via the control unit 4 the next control pulse to the stimulator unit 8th passing over the magnetic coil 2 Generates or passes on stimuli. The goal here is not simply to suppress the firing of the neurons as with the standard continuous stimulation. Instead, only the morbidly increased synchronization of the Nerver cells should be remedied as needed. That is, the nerve cell groups in the target area are uncorrelated, while they are still active, so form action potentials. This is to bring the affected nerve cells closer to their physiological - ie uncorrelated firing - state, rather than simply that their activity is completely suppressed. For this, several different synchronization reduction methods based on the principle of "stochastic phase resetting" can be used, taking advantage of the fact that a synchronized neuron population can be desynchronized by applying an electrical stimulus of the correct intensity and duration, provided that The stimulus is administered in a vulnerable phase of the abnormal rhythmic activity.These optimal stimulation parameters (intensity, duration and vulnerable phase) are, for example, through the systematic variation of these parameters and comparison with the stimulation success (eg attenuation of the amplitude of the band-pass filtered feedback In case of using the telemetry device 11 - 13 the calibration can be improved by using the above-mentioned frequency-dependent phase resetting curves. Single-pulse stimulation is only efficient if the stimulus is applied at or close enough to the vulnerable phase of the activity to be stimulated. Alternatively, complex forms of stimulation can be used. These consisted of a resetting (controlling the dynamics of the neuron subpopulation to be stimulated, for example restarting). The advantage of these more complex procedures is that the complex forms of stimulation, regardless of the dynamic state of the neuron population to be stimulated, cause a reduction in synchronization.

In the case of the use of individual stimuli must control unit 4 when the threshold value determined by the calibration is exceeded by means of the electronics (control unit 4 ) standard prediction algorithms predict the temporal occurrence of the vulnerable phase to make it precise enough. In the case of the use of complex stimuli must control unit 4 if the threshold value established by the calibration is exceeded, it will only give rise to a new complex stimulus of the same kind.

• a) Einzelpuls-Stimulationen.

Simple stimuli are for example

• a) single-pulse stimulations.

• b) Doppelpuls-Stimulation,
• c) stochastische Mehrkanalstimulation

Complex stimuli are for example

• b) double pulse stimulation,
• c) stochastic multichannel stimulation

Him In a preferred embodiment, the device is with Means for wireless transmission of data, such as equipped with measuring signals and stimulation control signals, Thus, a data transfer from the patient to an external Receiver for example for the purpose of therapy monitoring and optimization can take place. This way can be early be recognized whether the stimulation parameters used no longer are optimal. In addition, through a wireless transmission of data to a reference database and early on typical changes in the Irritability in the target tissue will be responded.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 10211766 [0006]
• - DE 10318071 [0007]
• WO 03/85546 A1 [0009]
• WO 03/098268 A1 [0010]
• WO 03/082405 [0010]
• WO 00/74777 [0010]
• WO 01/012236 A1 [0010]
• - US 03/082507 A1 [0010]

Cited non-patent literature

• - "Detection of n: m Phase Locking from Noisy Data: Application to Magnetoencephalography" by P. Tass, et al in Physical Review Letters, 81, 3291 (1998) [0054]
• - PA Tass: "Phase Resetting in Medicine and Biology. Stochastic Modeling and Data Analysis. "Springer Verlag, Berlin 1999 [0056]

Claims (16)

An apparatus for reducing neuronal brain activity desynchronization comprising means for stimulating brain regions and a sensor for measuring a pathological feature, characterized in that the means for stimulating neuronal brain activity is a means for generating a magnetic field. Apparatus according to claim 1, characterized in that the means for generating a magnetic field at least one magnetic coil ( 2 ). Apparatus according to claim 2, characterized in that the means for generating a magnetic field ( 2 ) is an array of two or three coils. Apparatus according to claim 2, characterized in that the means for generating a magnetic field ( 2 ) comprises four coils. Device according to claim 4, characterized in that that the centers of the coils are essentially the vertices of a Forming squares. Device according to one of claims 3 or 4, characterized in that the two or four coils by a or two in the form of an 8 guided coils are given. Device according to one of claims 1 to 6, characterized in that the means for generating a magnetic field form a magnetic field strength of 1.1 to 2.3 Tesla. Device according to one of claims 1 to 7, characterized in that it has a control unit ( 4 ), which applies magnetic fields. Apparatus according to claim 8, characterized in that the control unit ( 4 ) includes univariate and / or bivariate and / or multivariate data analysis. Device according to claim 9, characterized in that that at least one of the univariate, bivariate and multivariate Data processing using methods of statistical physics works. Device according to claim 10, characterized in that that the method of statistical physics from the field of stochastic Phase resetting dates. Device according to one of claims 1 to 11, characterized in that the control of the occurrence of a pathological feature, which from the sensor ( 3 ) is detected, and at the onset of the physiological feature at least one pulse on the magnetic coil. Device according to one of claims 1 to 12, characterized in that the controller ( 4 ) detects the disappearance of a pathological feature and shuts off the magnetic pulse. Means for generating a magnetic field, characterized characterized in that it comprises at least three coils through which a current is passed. Means for generating a magnetic field according to claim 14, characterized in that it comprises four coils through which a current is passed. Means for displaying a magnetic field after a of claims 14 or 15, characterized in that It generates magnetic fields between 1.1 and 2.3 Tesla.