[Progress in the application of neural oscillations cross-frequency coupling in cognitive function research].

Neural oscillations cross-frequency coupling (CFC) refers to the effect of the cross modulation between the electrophysiological oscillation rhythm in different ensembles of neurons. The CFC can reflect the mechanism of information transfer and exchange of local field potentials, electroencephalograph (EEG) and other neural electrophysiological activities at different spatial and temporal scales and plays an important role in the study of cognitive function. This paper introduces the basic phenomenon and classifications of neural oscillation CFC briefly, and reviews the typical applications in the study of the animal cognition model and human cognitive function in recent years, respectively. The main problems are also summarized and the future research is prospected in order to provide new ideas to promote the study and application of the CFC.

[Research on the progress of neuroprosthesis for the limb motor system].

This paper reviews the current developing situation of neuroprostheses which are based on the functional electrical stimulation (FES) technique and are used to provide limb movements. It also discusses the major challenges of neuroprostheses, which will be faced in the future development and in the clinical applications for the rehabilitation of spinal cord injury and stroke.

A novel technique for phase synchrony measurement from the complex motor imaginary potential of combined body and limb action.

In this study, we proposed and evaluated the use of the empirical mode decomposition (EMD) technique combined with phase synchronization analysis to investigate the human brain synchrony of the supplementary motor area (SMA) and primary motor area (M1) during complex motor imagination of combined body and limb action. We separated the EEG data of the SMA and M1 into intrinsic mode functions (IMFs) using the EMD method and determined the characteristic IMFs by power spectral density (PSD) analysis. Thereafter, the instantaneous phases of the characteristic IMFs were obtained by the Hilbert transformation, and the single-trial phase-locking value (PLV) features for brain synchrony measurement between the SMA and M1 were investigated separately. The classification performance suggests that the proposed approach is effective for phase synchronization analysis and is promising for the application of a brain-computer interface in motor nerve reconstruction of the lower limbs.

Theoretical modeling study of the necrotic field during high-intensity focused ultrasound surgery.

BACKGROUND: High-intensity focused ultrasound (HIFU) is a type of micro-invasive treatment of tumor. It is important to create a guideline for the volume and position of the necrotic field by means of a theoretical model, this being one of the key problems in the clinic application of HIFU. MATERIAL/METHODS: Based on cellular thermo-necrotic theory, a computational model of temperature distribution and, therefore, the necrotic field was developed. A multi-transducer system with non-interferential and self-focused property was devised to provide experimental verification of the theoretical model. RESULTS: The necrotic field resulting from the modeling simulation did not show any evident difference from that of the experiment. The necrotic field of the same heating duration (4 seconds) was found with both modeling and experiment to be spheroid, with its center at the system's geometric focus and a volume of 1x1x2 cm3. CONCLUSIONS: The model of this study may predict the practical volume of the necrotic field as well as the time needed for it to form.