The application claims the benefit of German Patent Application No. DE 10 2016 203 254.2, filed Feb. 29, 2016, which is hereby incorporated by reference in its entirety.
The present disclosure relates to a method for simulation of an electrical stimulation during the examination of an examination object. The disclosure further relates to the associated magnetic resonance system and to a computer program product and an electronically readable data carrier.
During imaging using magnetic resonance systems a peripheral stimulation of the nerves or heart may occur because of the gradient fields, if an imaging sequence with large magnetic field gradient changes is used. To prevent the stimulation, standardization bodies, for example ISO 60601-2-33, have called for limit values for the stimulation.
U.S. Pat. No. 6,169,403 B1 describes a method for predicting the stimulation value prior to a measurement and for monitoring it during a measurement. In this case, a magnetic flux vector differentiated by time is filtered multiple times per spatial direction, combined in a weighted manner, and evaluated against a limit. Mathematically, the filtering is effected by a convolution of the time characteristic of the time derivative with an e-function. Because of the computation rate, the convolution takes place by an iteration. During the iteration, the current filter value for the further processing is calculated at each time point from the preceding filter value. Because the calculation of whole measuring cycles during imaging has previously taken a very long time, the determination of the stimulation value has been restricted to the gradient sequence which would generate the highest stimulation. For safety reasons, a safety margin may additionally likewise be applied, which reduces the maximally permitted time derivative of the magnetic field gradients.
The scope of the present disclosure is defined solely by the appended claims and is not affected to any degree by the statements within this description. The present embodiments may obviate one or more of the drawbacks or limitations in the related art.
It is an object of the present disclosure to expedite such a simulation of the stimulation limits.
According to the disclosure, a method for simulation of an electrical stimulation during an examination of an examination object is provided, in which the examination object is examined in a magnetic resonance (MR) system to create a MR image using an imaging sequence. A time characteristic of at least one magnetic field gradient used during the imaging sequence is determined. Furthermore, a time derivative of the time characteristic of the at least one magnetic field gradient is determined. Finally, the change time points at which the derivative of the time characteristic changes are determined. The simulation of the electrical stimulation is carried out during the imaging sequence, the simulation being restricted to the determined change time points.
By restricting the simulation to the change time points at which the time derivative of the magnetic field changes, the procedure during most imaging sequences may be significantly expedited, because many fewer simulation steps are performed. In most imaging sequences, many magnetic field gradients are not switched at all over the time span of the whole imaging sequence, or the time derivative of the gradient characteristics is constant over a longer time span, before the time derivative of the gradients changes again. This means the change time points at which the time derivative of the magnetic field changes and is not zero are very few. The changes of the time derivatives are relatively rare, so that during planning for a measurement, a simulation is possible at all change time points.
The simulation may include a calculation of the electrical stimulation. During the calculation, this is restricted to the particular change time points. It is possible for a current stimulation value to be calculated from a preceding stimulation value during the calculation. Here the calculation of the current stimulation value may then be restricted to the determined change time points.
It is possible to perform the simulation for the entire time characteristic of the imaging sequence in all gradient directions. A restriction to regions of the imaging sequence in which the highest simulation values are expected is no longer necessary.
The simulation of the electrical stimulation may be based on the following formula:
Here fn designates the electrical stimulation at the change time point n, Δt is a predefined time step, τ is a predefined time constant, fn−i designates the electrical stimulation at the preceding change time point, and {dot over (B)} describes the time derivative of the magnetic field gradient.
This formula may be simplified by assuming that the exponential function used in the formula is approximated by a first-order function:
This formula may be further simplified by assuming that Δt/τ is significantly smaller than 1, giving the following formula:
The simulation may be performed when setting the imaging parameters that are used during the imaging sequence. Here the simulation may be concluded before adjustment measurements are made, in which an influence of the examination object on a measurement field in which the MR signals are measured may be taken into account.
It is possible for a plurality of imaging parameters to be set during the imaging sequence used. After setting a first imaging parameter, the simulation may be started and performed automatically, it being concluded before the last imaging parameter has been set.
The disclosure further relates to the associated magnetic resonance system that may have a computing unit designed to perform the above-mentioned acts.
The disclosure is explained in greater detail below with reference to the annexed drawings.
The magnetic resonance system also has a MR control unit 13 used for controlling the MR system. The central MR control unit 13 has a gradient controller 14 for controlling and switching the magnetic field gradients, and an RF controller 15 for controlling and irradiating the RF pulses to deflect the magnetization from the equilibrium position. The imaging sequences needed for recording the MR images may be stored in a storage unit 16, along with all program modules needed to operate the MR system. Furthermore, the storage unit may have a program module, with which, as is explained below, the effective simulation or calculation of the stimulation limits is possible.
A recording unit 17 controls the image recording and thus controls the sequence of magnetic field gradients and RF pulses as a function of the selected imaging sequence. Thus, the recording unit 17 also controls the gradient controller 14 and the RF controller 15. MR images that may be displayed on a display 18 may be calculated in a computing unit 20, wherein an operator may operate the MR system by way of an input unit 19. The computing unit 20 is further designed, as is described in detail below, to perform a simulation of the electrical stimulation.
The calculation produces stimulation values and act S27 checks whether predefined limit values have been adhered to. If so, act S28 checks whether the parameter processing is concluded. If not, the method returns to act S22. If so, the preparation for the measurement is performed in act S29, e.g., among other things adjustment measurements are performed, in which the polarization field is adjusted to the examination object. After the measurement preparation has been performed, act S30 checks whether the stimulation limit values are still adhered to. If not, then in act S31, the critical imaging parameters are processed and the method returns to act S23.
If the check in act S30 depicts that the limit values have been adhered to, the measurement may be performed in act S32. The method finally ends in act S33.
With reference to
Following the formation of the time derivative in the various spatial directions of the magnetic field gradients used, a calculation may be performed, as is described in greater detail in U.S. Pat. No. 6,169,403 B1, herein incorporated by reference in its entirety. There filtering takes place using two filters, once for the simulation of the presynaptic phase and once for the simulation of the postsynaptic phase. The following function, which is subsequently derived, may now be used in this filtering, while the other calculation steps of the simulation may correspond to the steps as are described in U.S. Pat. No. 6,169,403 B1.
The simulation of the stimulation is based on filtering using an e-function via an iteration. Here the function at the time point of the imaging sequence at the time point zero is equal to 0:
f0=0 (1)
The filter value at the time point n·Δt is as follows:
f
n
=d{dot over (B)}+cf
n−1 (2)
As shown in
gives the following equation:
f
n
=d{dot over (B)}+cf
n−1. (3)
τ is here a preset constant describing the filtering. With further considerations, the above equation (3) may be reformulated as follows:
f
n
=d{dot over (B)}+c(d{dot over (B)}+cfn−2) (4)
f
n=(1+c)d{dot over (B)}+c2fn−2 (5)
f
n=(1+c)d{dot over (B)}+c2(d{dot over (B)}+cfn−3) (6)
f
n=(1+c+c2)d{dot over (B)}+c3fn−3 (7)
This results generally in the following equation:
Assuming that the time derivative {dot over (B)} is constant, as may be seen in equation (8), {dot over (B)} may be moved in front of the sigma sign.
The following also applies:
This results in the following equation for the filter value at the time point n:
This may be simplified still further as follows, using an approximation for the function:
If Δt/τ is small enough, a further simplification of the exponential expression yields the following equation:
Referring to
Using the above derived formula, the errors that have hitherto arisen by rounding are reduced, so that the algorithm used becomes more accurate overall. In the current, iterative approach the result of the n−1 time point is used. By reference to the preceding values, small errors arising as a result of the finite computation/variable accuracy are added up over time. In the new approach proposed here, the value at the next change time point is calculated directly, rather than all small interim acts. Thus, if appropriate, e.g., 50 interim multiplications are avoided. Alternatively, any number of values of the exponential function may be calculated and stored at once:
is not sequence-dependent and may be stored for use in the calculation.
Overall the processing speed is increased so much that it is possible to calculate the entire gradient sequence. Thus, the permissible parameter space for the setting of the imaging parameters may be restricted prior to the measurement such that the stimulation value does not exceed a preset limit. This in turn expedites the operating procedure, because if a limit is exceeded it is no longer necessary to calculate suggestions from which a person has to select the most appropriate one. This work step may now be omitted.
It is to be understood that the elements and features recited in the appended claims may be combined in different ways to produce new claims that likewise fall within the scope of the present disclosure. Thus, whereas the dependent claims appended below depend from only a single independent or dependent claim, it is to be understood that these dependent claims may, alternatively, be made to depend in the alternative from any preceding or following claim, whether independent or dependent, and that such new combinations are to be understood as forming a part of the present specification.
While the present disclosure has been described above by reference to various embodiments, it may be understood that many changes and modifications may be made to the described embodiments. It is therefore intended that the foregoing description be regarded as illustrative rather than limiting, and that it be understood that all equivalents and/or combinations of embodiments are intended to be included in this description.
Number | Date | Country | Kind |
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102016203254.2 | Feb 2016 | DE | national |