Defibrillation is the most effective method of treating ventricular fibrillation(VF), this paper introduces wearable automatic external defibrillators based on embedded system which includes EGG measurements, bioelectrical impedance measurement, discharge defibrillation module, which can automatic identify VF signal, biphasic exponential waveform defibrillation discharge. After verified by animal tests, the device can realize EGG acquisition and automatic identification. After identifying the ventricular fibrillation signal, it can automatic defibrillate to abort ventricular fibrillation and to realize the cardiac electrical cardioversion.
Animals ; Defibrillators ; Electric Countershock ; Electric Impedance ; Equipment Design ; Heart ; Humans ; Monitoring, Physiologic ; instrumentation ; Ventricular Fibrillation ; therapy

Objective To explore the establishment of a rabbit model of atrial fibrillation by wireless telemetering and stimulation technology.Method An implantable telemetering stimulator which was independently designed and devel-oped was hypodermically implanted in New Zealand rabbits.The implantable telemetering stimulator was made with the core development and design of MSP single-chip microcomputer of TI Corporation ( Texas Instruments) and RF wireless trans-ceiver chip CC2250 of TI Corporation.The design of the implantation system was optimized to cater to the exploratory ex-periment to establish atrial fibrillation model of New Zealand rabbits.The implanter was implanted into the abdominal sub-cutaneous tissue of the New Zealand rabbits, the collecting electrodes were placed in the oxter subcutaneous tissues of the left and the right upper extremities, and the two stimulating electrodes were sutured at the left auricle and the left atrium. The signals were collected and stimulated by the wireless transceiver.The I-lead ECG electrical signals were continuously monitored on the body surface by a Powerlab physiological recorder.High frequency ( >20 Hz) suprathreshold stimulus ( intensity 2 mA, pulse width 1 ms) was emitted by specialized stimulation software of a computer program by the interval ( stimulating for 2 s and pausing for 2 s) .In case of atrial fibrillation during intervals, the stimulation could be stopped by hand.In case of sinus rhythm, the stimulation could be continued.Results The implantable telemetering stimulator can work stably in vivo ( including collecting stimulated electrocardio signal and emitting stimulations) for 30 days.Atrial fibril-lation can be induced after stimulating in vivo of the New Zealand rabbits for 3 weeks, with a duration of >48 h.Conclu-sions Applying implantable telemetering stimulator can build a New Zealand istead of beagles model of atrial fibrillation which is more consistent with welfare optimization and substitution principle for laboratory animals.

The rapid atrial pacing model is one of the most popular atrial fibrillation animal models. In this paper, a novel implementation of wireless implantable stimulating and ECG monitoring system is described based on the requirements of rapid atrial pacing model. Hardware circuits and software structure of the system are introduced. And test outcomes through in-vitro simulation and in-vivo animal models are presented. After verified by animal tests, the system can be used to initiate and monitor chronic atrial fibriation in real time.
Animals ; Atrial Fibrillation ; diagnosis ; Electrocardiography ; instrumentation ; Heart Atria ; physiopathology ; Models, Animal ; Monitoring, Physiologic ; instrumentation ; Prostheses and Implants ; Software

Objective To explore the clinical outcome of perforator flaps for reconstruction of limb soft tissue defects. Methods In this case series, from 2007 July to 2009 May, 108 cases of perforator flap to reconstruct the defects of the extremities were performed, of these, 98 were free perforator flaps, 10 were pedicled flaps. The perforator flaps included deep inferior epigastric artery perforator flap, anterolateral thigh perforator flap, thoracodorsal artery perforator flap, lateral thigh perforator flap, posterior interosseous artery perforator flap, collateral radial artery perforator flap, medial sural artery perforator flap, posterior tibial artery perforator flap, deep circumflex iliac artery perforator flap and peroneal artery perforator flap. The maximum size of the perforator flap was 44 cmx 9 cm, the minimum size of the perforator flap was 4 em x 2 cm.The donor defect was closed directly. Results Venous congestion occurred in 5 flaps, in 1 case venous congestion was overcomed after released the dressing, 4 flaps requiring reexploration for venous insufficiency,2 had a successful outcome, the other 2 flaps failed . The other 103 flaps were successful. The wounds healed without any infection complications. The follow-up ranges from 6-24 months( 10 months on average). The flaps were of good appearance and not bulky; there were only linear scars on the donor sites, the cosmesis and function of the donor sites were satisfying. Conclusion The muscle, deep fascia and motor nerve are not contained in the flap, the advantages of this type of flap is reducing morbidity of the donor site and its reliable blood supply and suitable thickness for resurfacing, no secondary debuiking is necessary. The perforator flaps can be chosen as the first option to deal with superficial extremity wounds.

In this paper, we described an ultra-low power, wearable ECG system capable of long term monitoring and mass storage. This system is based on micro-chip PIC18F27J13 with consideration of its high level of integration and low power consumption. The communication with the micro-SD card is achieved through SPI bus. Through the USB, it can be connected to the computer for replay and disease diagnosis. Given its low power cost, lithium cells are used to support continuous ECG acquiring and storage for up to 15 days. Meanwhile, the wearable electrodes avoid the pains and possible risks in implanting. Besides, the mini size of the system makes long wearing possible for patients and meets the needs of long-term dynamic monitoring and mass storage requirements.
Electrocardiography, Ambulatory ; instrumentation ; Signal Processing, Computer-Assisted ; instrumentation