In Vivo Transcranial Acoustoelectric Brain Imaging of Different Steady-State Visual Stimulation Paradigms

Song, Xizi; Su, Xiuli; Chen, Xinrui; Xu, Minpeng; Ming, Dong

doi:10.1109/tnsre.2022.3196828

Cited by 3 publications

(2 citation statements)

References 24 publications

(27 reference statements)

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“…Besides, we have demonstrated that the pulse repetition frequency (PRF) of FUS is capable of encoding electroencephalography (EEG) signal and decoding AE signal and proved its feasibility through in vivo rat brain AEBI experiments [26][27][28][29][30][31]. Furtherly, based on PRF, living rat steady-state visual evoked potentials activation was mapped and the AE signal processing network of the rat brain was revealed [32][33][34][35]. The above studies made important contributions to optimize AEBI imaging method for further clinical application.…”

Section: Introductionmentioning

confidence: 85%

“…To evaluate AEBI image performance, the spatiotemporal resolution and imaging signal-to-noise ratio (SNR) were quantified. Spatial lateral (axial) resolution was defined as the width at 3 dB attenuation of AE signal peak which was measured along the x or y direction [24,28,34,45]. The SNR was calculated in decibels according to (7).…”

Section: E Evaluation Indicatorsmentioning

confidence: 99%

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In Vivo Transcranial Acoustoelectric Brain Imaging of Different Deep Brain Stimulation Currents

Zhou,

Song,

et al. 2024

IEEE Trans. Neural Syst. Rehabil. Eng.

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Objective. Deep brain stimulation (DBS) is an effective treatment for neurologic disease and its clinical effect is highly dependent on the DBS leads localization and current stimulating state. However, standard human brain imaging modalities could not provide direct feedback on DBS currents spatial distribution and dynamic changes. Acoustoelectric brain imaging (AEBI) is an emerging neuroimaging method that can directly map current density distribution. Here, we investigate in vivo AEBI of different DBS currents to explore the potential of DBS visualization using AEBI. Method. According to the typical DBS stimulus parameters, four types of DBS currents, including time pattern, waveform, frequency, and amplitude are designed to implement AEBI experiments in living rat brains. Based on acoustoelectric (AE) signals, the AEBI images of each type DBS current are explored and the resolution is quantitatively analyzed for performance evaluation. Furtherly, the AE signals are decoded to characterize DBS currents from multiple perspectives, including time-frequency domain, spatial distribution, and amplitude comparation. Results. The results show that in vivo transcranial AEBI can accurately locate the DBS contact position with a millimeter spatial resolution (<2 mm) and millisecond temporal resolution (<10 ms). Besides, the decoded AE signal at DBS contact position is capable of describing the corresponding DBS current characteristics and identifying current pattern changes. Conclusion. This study first validates that AEBI can localize in vivo DBS contact and characterize different DBS currents. Significance. AEBI is expected to develop into a noninvasive DBS real-time monitoring technology with high spatiotemporal resolution.

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Section: Introductionmentioning

confidence: 85%

Section: E Evaluation Indicatorsmentioning

confidence: 99%

In Vivo Transcranial Acoustoelectric Brain Imaging of Different Deep Brain Stimulation Currents

Zhou,

Song,

et al. 2024

IEEE Trans. Neural Syst. Rehabil. Eng.

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The frontooccipital interaction mechanism of high-frequency acoustoelectric signal

Song,

Huang,

Chen

et al. 2023

Cerebral Cortex

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Based on acoustoelectric effect, acoustoelectric brain imaging has been proposed, which is a high spatiotemporal resolution neural imaging method. At the focal spot, brain electrical activity is encoded by focused ultrasound, and corresponding high-frequency acoustoelectric signal is generated. Previous studies have revealed that acoustoelectric signal can also be detected in other non-focal brain regions. However, the processing mechanism of acoustoelectric signal between different brain regions remains sparse. Here, with acoustoelectric signal generated in the left primary visual cortex, we investigated the spatial distribution characteristics and temporal propagation characteristics of acoustoelectric signal in the transmission. We observed a strongest transmission strength within the frontal lobe, and the global temporal statistics indicated that the frontal lobe features in acoustoelectric signal transmission. Then, cross-frequency phase-amplitude coupling was used to investigate the coordinated activity in the AE signal band range between frontal and occipital lobes. The results showed that intra-structural cross-frequency coupling and cross-structural coupling co-occurred between these two lobes, and, accordingly, high-frequency brain activity in the frontal lobe was effectively coordinated by distant occipital lobe. This study revealed the frontooccipital long-range interaction mechanism of acoustoelectric signal, which is the foundation of improving the performance of acoustoelectric brain imaging.

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Ultrasound Pulse Waveform Modulation with Gauss Window for Acoustoelectric Imaging

Song

Han

et al. 2022

2022 IEEE International Ultrasonics Symposium (IUS)

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In Vivo Transcranial Acoustoelectric Brain Imaging of Different Steady-State Visual Stimulation Paradigms

Cited by 3 publications

References 24 publications

In Vivo Transcranial Acoustoelectric Brain Imaging of Different Deep Brain Stimulation Currents

In Vivo Transcranial Acoustoelectric Brain Imaging of Different Deep Brain Stimulation Currents

The frontooccipital interaction mechanism of high-frequency acoustoelectric signal

Ultrasound Pulse Waveform Modulation with Gauss Window for Acoustoelectric Imaging

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