OBJECTIVE:To study the safety and efficacy of Neuroform self-expanding stent for symptomatic intracranial artery stenosis.METHODS:A total of 37 patients with symptomatic intracranial artery stenosis received treatment at the Department of Neurosurgery,Affiliated Hospital of Behua University and Xuanwu Hospital were selected,who were ineffective to anticoagulation and antiplatelet treatment,including 24 males and 13 females,aged from 49 to 72 years,mean aged 64 years.All patients were received Neuroform self-expanding stent following angiography.RESULTS:All patients underwent PTAS with mean preoperative stenosis were reduced from 64% to 24% after percutaneous transluminal angioplasty (PTAS).The technically successful rate was 100%.All the patients were received a 6-22 month follow-up (average 13 months).The average artery stents was retrieved by 50%-90% after stent deployment.There was no arterial dissection,acute occlusion of the target artery or symptomatic distal emboli.Within the follow-up period,1 patient endured asymptomatical artery full occlusion.Two stents were implanted simultaneously in 3 patients,1 of them suffered bilateral vertebral artery stenosis,and 2 had right vertebral arterial and basilar artery stenosis.One patient suffered acute in-stent thrombosis and recovered after thrombolytic therapy.No pathogenetic condition was aggravated in the follow-up.CONCLUSION:The application of Neuroform self-expanding stent can alleviate the ischemic symptoms of patients with vertebrobasilar stenosis and elevate the operative safety and effectiveness.However,further study is needed to evaluate the long-term therapeutic effect.

Objective To develop a simplified phantom for the calibration of whole-body counters. Methods A simplified phantom design method for the calibration of whole-body counters was established based on the process and method of calibrating whole-body counters. By using the established method and Monte Carlo method, a simplified phantom including the total body, thyroid, lungs, and gastrointestinal tract was designed to calibrate the ORTEC-Stand FAST II whole-body counter. The simplified phantom was compared with the BOMAB phantom through experimental measurements. Results Within the range of 50 keV to 2 MeV, for rays of the same energy in the same organ of the simplified phantom and BOMAB phantom, the simulated data of detection efficiency by whole-body counting showed an error within 5%, and the experimental measurements showed an error within 10%. Conclusion We developed a simplified phantom for the calibration of the whole-body counter, demonstrating the feasibility of using the simplified phantom instead of a physical body phantom for whole-body counter calibration, which can greatly facilitate whole-body counter calibration for internal radiation monitoring.

Objective To address the radioactive contamination of wounds caused by transuranic nuclides, wound radiation imaging based on coded aperture imaging technology was investigated. Methods By simulating multiple source terms using Monte Carlo method, the differences in imaging performance between two image reconstruction algorithms under near-field conditions were compared. The effects of detector pixels and detection plane pixels on image resolution were investigated. Results The imaging system was simulated based on the designed dimensions. The simulated imaging field of view was 89.4 mm × 89.4 mm and the simulated angular resolution was 1.98°. Based on the comparison of the average width at half height of the reconstructed point sources under different conditions, it was found that increasing the number of pixels in the detector and detection plane optimized the angular resolution but significantly prolonged the Monte Carlo simulation time. Conclusion According to the simulation results, the parameters of the imaging system can be used to effectively image radioactive contamination. Our results provide methodological support for the measurement of wound contamination caused by transuranic nuclides, and lay the foundation for the development of wound contamination imaging detection systems in the future.