The gradient coils of MRI equipment can induce vibrations in implantable medical devices, causing periodic vibrations of implantable medical devices with respect to the surrounding tissue. This not only results in instrument failure but also causes discomfort to the patient. Therefore, studying the vibration characteristics of implantable devices under different scanning sequences and the orientation of the device relative to the magnetic field is crucial for comprehending vibration performance. This study observed the vibration spectra of a full cranial bone-implanted neurostimulator by using laser vibrometry under typical rapid imaging sequences and explored the impact of different magnetic field orientations on vibration. The results demonstrated that the rapid echo sequences induced diverse and rich vibration components, whereas the planar echo sequences caused relatively simple vibrations. Additionally, the strongest vibrations normally occurred in the maximum conductive surface parallel to the phase-coded direction. It revealed the factors influencing the vibrations of skull fixation active implantable devices and provided guidance for enhancing device safety and protecting patient well-being during MR examinations.
Vibration ; Magnetic Resonance Imaging ; Deep Brain Stimulation/instrumentation* ; Magnetic Fields ; Humans

In order to investigate the effect of deep brain stimulation on diseases such as epilepsy, we developed a closed-loop electrical stimulation system using LabVIEW virtual instrument environment and NI data acquisition card. The system was used to detect electrical signals of epileptic seizures automatically and to generate electrical stimuli. We designed a novel automatic detection algorithm of epileptic seizures by combining three features of field potentials: the amplitude, slope and coastline index. Experimental results of rat epileptic model in the hippocampal region showed that the system was able to detect epileptic seizures with an accuracy rate 91.3% and false rate 8.0%. Furthermore, the on-line high frequency electrical stimuli showed a suppression effect on seizures. In addition, the system was adaptive and flexible with multiple work modes, such as automatic and manual modes. Moreover, the simple time-domain algorithm of seizure detection guaranteed the real-time feature of the system and provided an easy-to-use equipment for the experiment researches of epilepsy control by electrical stimulation.
Algorithms ; Animals ; Deep Brain Stimulation ; instrumentation ; Disease Models, Animal ; Electroencephalography ; Epilepsy ; diagnosis ; Equipment Design ; Rats ; Seizures ; diagnosis

Deep brain stimulation (DBS) therapy develops rapidly in clinical application. The structures of deep brain stimulator and magnetic resonance imaging (MRI) equipment are introduced, the interactions are analyzed, and the two compatible problems of radio frequency (RF) heating and imaging artifact are summarized in this paper.
Artifacts ; Deep Brain Stimulation ; instrumentation ; Humans ; Magnetic Resonance Imaging ; instrumentation

We compared the surgical outcome with electrode positions after bilateral subthalamic nucleus (STN) stimulation surgery for Parkinson's disease. Fifty-seven patients treated with bilateral STN stimulations were included in this study. Electrode positions were determined in the fused images of preoperative MRI and postoperative CT taken at six months after surgery. The patients were divided into three groups: group I, both electrodes in the STN; group II, only one electrode in the STN; group III, neither electrode in the STN. Unified Parkinson's Disease Rating Scale (UPDRS), Hoehn and Yahr stage, and activities of daily living scores significantly improved at 6 and 12 months after STN stimulation in both group I and II. The off-time UPDRS III speech subscore significantly improved (1.6 +/- 0.7 at baseline vs 1.3 +/- 0.8 at 6 and 12 months, P < 0.01) with least L-dopa equivalent daily dose (LEDD) (844.6 +/- 364.1 mg/day at baseline; 279.4 +/- 274.6 mg/day at 6 months; and 276.0 +/- 301.6 mg/day at 12 months, P < 0.001) at 6 and 12 months after STN deep brain stimulation (DBS) in the group I. Our findings suggest that the better symptom relief including speech with a reduced LEDD is expected in the patients whose electrodes are accurately positioned in both STN.
Adult ; Aged ; Antiparkinson Agents/adverse effects/*therapeutic use ; Combined Modality Therapy ; *Deep Brain Stimulation/adverse effects/instrumentation/methods ; *Electrodes, Implanted ; Female ; Humans ; Levodopa/adverse effects/therapeutic use ; Magnetic Resonance Imaging ; Male ; Middle Aged ; Parkinson Disease/drug therapy/*therapy ; Severity of Illness Index ; Subthalamic Nucleus/*physiology ; Treatment Outcome

Neural interface technology researches, which constitute the intercross science relating to neurophysiology, computational science, microelectronic technology and so on, are of important value in rehabilitation engineering. In this paper, the concept and significance of neural interface were introduced. The applications and methods of different kinds of neural interface system were expounded. Related animal experiments were citated. The recent studies and trends in neural interface technology were also discussed.
Activities of Daily Living ; Animals ; Communication Aids for Disabled ; Deep Brain Stimulation ; Disabled Persons ; rehabilitation ; Electric Stimulation ; Electric Stimulation Therapy ; instrumentation ; Humans ; Microelectrodes ; Motor Cortex ; physiology ; User-Computer Interface