Impaired neural coordination in hippocampus of diabetic rat / 生理学报

In vitro electrical neurophysiological and behavioural studies have shown that diabetes mellitus negatively affects hippocampal function. In this study, by using in vivo extracellular recording, the spontaneous neural activity was obtained from hippocampus of anaesthetized rats in both streptozotocin-induced diabetes group and normal control group. Temporal relationship between neuronal firing and slow oscillation (1-4 Hz) of local field potentials (LFPs) in hippocampus was analyzed using coherence and phase locking measurement. Lower coherence value (0.617+/-0.028) was observed in diabetic rats than that in control rats (0.730+/-0.024) (P=0.005). Furthermore, phase-locking measurement using von Mises fitting parameterized by a concentration parameter kappa showed a lower degree (kappa= 0.347+/-0.113) of temporal coordination between neuronal spiking and slow oscillation of LFPs in the hippocampus of diabetic rats than that of normal ones (kappa= 1.174+/-0.134) (P<0.001). Both approaches demonstrated that diabetes can indeed impair the temporal coordination between neuronal spiking and slow oscillation of population activity in hippocampus. This observed neural coordination impairment may serve as a network level mechanism for diabetes-induced memory deterioration.

In vivo extracellular neural recording for the study of cortical plasticity / 生理学报

Neural network plasticity is fundamental for learning and memory. Its abnormal change underlies some neural diseases. Measurement of the plasticity of cortex can help understand the mechanism of plasticity, and provide a quantitative way to observe the neural process of natural aging and neurodegenerative diseases, which may lead to a new approach for evaluation of anti-aging drugs and new medical treatments for neurodegenerative diseases. In this study, a systematic method was established based on whisker pairing (WP) experiment to measure the network plasticity in the barrel cortex in rat. WP experiment is a classical experiment to study the effect of innocuous bias of the flow of sensory activity from the whiskers for certain periods in awake and behaving rats on the receptive field organization in S1 barrel cortex neurons. In the experiment, one pair of adjacent whiskers D2 and D3 remained intact while others were being trimmed throughout a certain period. After that, receptive fields of single cells in the contralateral barrel were analyzed by post-stimulus time histogram after certain days of WP and compared with the controls. In the control group, response magnitudes to surrounding whiskers D1 and D3 deflection were not significantly different. However, after WP, a bias occurred in response to paired surrounding whisker D3 relative to the opposite trimmed surrounding whisker D1. In this study, by comparing the bias degree in rats in different groups after WP, a quantitative method was established to compare cortical plasticity. Example of corical plasticity comparison between adolescent and mature rats was employed in this paper to illustrate our method. The key techniques of this method such as the identification of D2 barrels, supragranular (L2-3) and barrel layer (L4) in real-time were described in details. The feasibility of this approach was further verified by compendious report of results and our previous study regarding cortical plasticity comparison between adolescent and mature rats.

Neural engineering and neural prostheses / 中国医疗器械杂志

The motivation of the brain-computer interface (BCI) research and its potential applications are introduced in this paper. Some of the problems in BCI-based medical device developments are also discussed.

Advances in medical ultrasonic instrumentation / 中国医疗器械杂志

Recent advances in medical ultrasonic instrumentation are introduced in this review, including the progresses in transducer, diagnostic and therapeutic applications. Future development is also discussed.