MyShake is a crowdsourcing approach to earthquake early warning that harnesses the sensors in private smartphones.
To overcome the limits of conventional microwave ablation, a new frequency spectrum above 6 GHz has been explored for low-power and low collateral damage ablation procedure. A planar coaxial probe-based applicator, suitable for easy insertion into the human body, was developed for our study to cover a wideband frequency up to 30 GHz. Thermal ablations with small input power (1-3 W) at various microwave frequencies were performed on nude mice xenografted with human breast cancer. Comparative study of ablation efficiencies revealed that 18-GHz microwave results in the largest difference in the temperature rise between cancer and normal tissues as well as the highest ablation efficiency, reaching 20 times that of 2 GHz. Thermal profile study on the composite region of cancer and fat also showed significantly reduced collateral damage using 18 GHz. Application of low-power (1 W) 18-GHz microwave on the nude mice xenografted with human breast cancer cells resulted in recurrence-free treatment. The proposed microwave ablation method can be a very effective process to treat small-sized tumor with minimized invasiveness and collateral damages.Breast cancer is a major threat to women's health psychologically as well as physically. 1 Despite the high potential of fatality, most women show reluctance for large-scale breast removal due to cosmetic concerns, which brings about the need for local surgical control. For this reason, minimally invasive techniques to achieve better local surgical control have collected extensive attention as a possible first-line treatment in lieu of conservative breast surgery procedures such as lumpectomy. 2,3 Among several alternative methods, microwave ablation entails many benefits in comparison with the others such as laser ablation, cryoablation and ethanol ablation. [4][5][6][7][8] Microwave ablation method is much safer and easily manageable 9 and can, in principle, offer material-specific responsiveness, where tissues with high water content such as cancer are preferentially heated and damaged. 10,11 This characteristic of microwaves makes microwave ablation well suited for local treatment of early stage of breast cancer. So far, the frequencies used in the existing microwave ablation systems have been limited to the low-frequency spectrum such as 915 MHz or 2.4 GHz. Because of the inherent low radiation efficiency, very high microwave input power of several tens of Watts is required at these frequencies, thus greatly increasing the cost and size of the equipment. 12 Moreover, because of the self-heating of the applicator by the excessive microwave power, additional means for cooling the applicator are required to avoid the damage of healthy tissues near the passage of the applicator. 13 Besides, the conventional low-frequency spectrum ablation has poor material selectivity when compared to the alternative high-frequency spectrum proposed in our work.To overcome the limitations of the existing microwave ablation methods, we have investigated the properties of microwaves up to 30 GHz wit...
Metastasis is the leading cause of death in breast cancer patients and an appropriate detection of metastasis can provide better prognosis and quality treatments. Microwaves can reveal the unique electromagnetic properties of materials, and this study aims to unleash the electromagnetic properties of breast cancer cells, especially, metastasized cancer cells in the lymph nodes, using broad-band microwaves in attempts to detect metastases. To distinguish the cancer-specific patterns of cancer tissues, three primary microwave parameters were assessed, i.e., permittivity in mid-band frequency (3-5 GHz), conductivity in high-band frequencies (25-30 GHz) and slope changes of permittivity at high-band frequencies (15-30 GHz). An additional parameter, Cancer Metastasis Index (CMI), was developed to effectively represent all parameters. Broadband microwave scanning can reveal cancer specific electromagnetic behaviors in all three parameters, and these were reliably reflected by CMI. CMI effectively magnified the difference of the electromagnetic properties between normal nodal tissues and cancer tissues. immunohistochemistries were performed to verify the origin of electromagnetic changes represented by CMI values.
Abstract-As energy efficiency has become a key consideration in the engineering of mobile applications, an increasing number of perfective maintenance tasks are concerned with optimizing energy consumption. However, optimizing a mobile application to reduce its energy consumption is non-trivial due to the highly volatile nature of mobile execution environments. Mobile applications commonly run on a variety of mobile devices over mobile networks with divergent characteristics. Therefore, no single, static energy consumption optimization is likely to yield across-the-board benefits, and may even turn to be detrimental in some scenarios. In this paper, we present a novel approach to perfective maintenance of mobile applications to reduce their energy consumption. The maintenance programmer declaratively specifies the suspected energy consumption hotspots in a mobile application. Based on this input, our approach then automatically transforms the application to enable it to offload parts of its functionality to the cloud. The offloading is highly adaptive, being driven by a runtime system that dynamically determines both the state-to-offload and its transfer mechanism based on the execution environment in place. In addition, the runtime system continuously improves its effectiveness due to a feedback-loop mechanism. Thus, our approach flexibly reduces the energy consumption of mobile applications behind the scenes. Applying our approach to third-party Android applications has shown that it can effectively reduce the overall amount of energy consumed by these applications, with the actual numbers ranging between 25% and 50%. These results indicate that our approach represents a promising direction in developing pragmatic and systematic tools for the perfective maintenance of mobile applications.
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