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キーワード:
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要旨:
MRI systems are traditionally engineered to produce close to idealized performance, enabling a simplified pulse sequence design philosophy. An example of this is control of eddy currents produced by gradient fields; usually these are compensated by pre-emphasizing demanded waveforms. This process typically happens invisibly to the pulse designer, allowing them to assume the achieved gradient waveform will be as desired. Whilst convenient, this imposes stricter limits on the sequence design than the hardware can handle (for example, pre-emphasis adds an additional overhead to amplifiers). This strategy can be undesirable particularly for lower performance or resource-limited hardware. Instead we explore the use of a 'digital twin' (i.e. an end-to-end model of the scanner system) to optimize control inputs, resulting in sequences that inherently compensate for known imperfections. We explore digital twin optimization specifically for gradient system imperfections as an exemplar. This is first explored in simulations using a simple exponential eddy current model, then experimentally using an empirical gradient impulse response function on a 7T MRI system. When unconstrained, digital twin optimization reproduces classic pre-emphasis. When strict hardware constraints are imposed (simulating lower performance hardware), it identifies novel sequences for scenarios where classic pre-emphasis would be unachievable. Experimentally, the optimization approach was demonstrated to substantially reduce ghosting effects in echo planar images on a 7T system. Digital twin optimization may allow more efficient use of hardware by taking a whole system approach. Ultimately this could enable the use of cheaper hardware without loss of performance.
