Cyclotech - contribution to solve the Technetium shortage by using low energy medical cyclotrons

This paper presents work in progress, to develop an efficient and economic way to directly produce Technetium 99metastable (99mTc) using low-energy cyclotrons. Its importance is well established and relates with the increased global trouble in delivering 99mTc to Nuclear Medicine Departments relying on this radioisotope. Since the present delivery strategy has clearly demonstrated its intrinsic limits, our group decided to follow a distinct approach that uses the broad distribution of the low energy cyclotrons and the accessibility of Molybdenum 100 (100Mo) as the Target material. This is indeed an important issue to consider, since the system here presented, named CYCLOTECH, it is not based on the use of Highly Enriched (or even Low Enriched) Uranium 235 (235U), so entirely complying with the actual international trends and directives concerning the use of this potential highly critical material. The production technique is based on the nuclear reaction 100Mo (p,2n) 99mTc whose production yields have already been documented. Until this moment two Patent requests have already been submitted (the first at the INPI, in Portugal, and the second at the USPTO, in the USA); others are being prepared for submission on a near future. The object of the CYCLOTECH system is to present 99mTc to Nuclear Medicine radiopharmacists in a routine, reliable and efficient manner that, remaining always flexible, entirely blends with established protocols. To facilitate workflow and Radiation Protection measures, it has been developed a Target Station that can be installed on most of the existing PET cyclotrons and that will tolerate up to 400 μA of beam by allowing the beam to strike the Target material at an adequately oblique angle. The Target Station permits the remote and automatic loading and discharge of the Targets from a carriage of 10 Target bodies. On other hand, several methods of Target material deposition and Target substrates are presented. The object was to create a cost effective means of depositing and intermediate the target material thickness (25 - 100μm) with a minimum of loss on a substrate that is able to easily transport the heat associated with high beam currents. Finally, the separation techniques presented are a combination of both physical and column chemistry. The object was to extract and deliver 99mTc in the identical form now in use in radiopharmacies worldwide. In addition, the Target material is recovered and can be recycled.

IEEE 802.15.4: a Federating Communication Protocol for Time-Sensitive Wireless Sensor Networks

Wireless Sensor Networks (WSNs) have been attracting increasing interests for developing a new generation of embedded systems with great potential for many applications such as surveillance, environment monitoring, emergency medical response and home automation. However, the communication paradigms in WSNs differ from the ones attributed to traditional wireless networks, triggering the need for new communication protocols. In this context, the recently standardised IEEE 802.15.4 protocol presents some potentially interesting features for deployment in wireless sensor network applications, such as power-efficiency, timeliness guarantees and scalability. Nevertheless, when addressing WSN applications with (soft/hard) timing requirements some inherent paradoxes emerge, such as power-efficiency versus timeliness, triggering the need of engineering solutions for an efficient deployment of IEEE 802.15.4 in WSNs. In this technical report, we will explore the most relevant characteristics of the IEEE 802.15.4 protocol for wireless sensor networks and present the most important challenges regarding time-sensitive WSN applications. We also provide some timing performance and analysis of the IEEE 802.15.4 that unveil some directions for resolving the previously mentioned paradoxes.

Metodologias e Ferramentas da Gestão da Manutenção e da Metrologia numa Unidade Hospitalar

A metrologia na saúde tem um elevado grau de importância no quotidiano hospitalar dado que muitas decisões são tomadas com base em medições. Além disso, a constante evolução tecnológica na área da saúde e o número crescente de parâmetros fisiológicos dos equipamentos médicos exige a constante preocupação com o controlo metrológico. Assim, o funcionamento eficiente destes poderá contribuir para a segurança, uma melhor e mais rápida recuperação do doente e, consequentemente, um aumento do tempo de vida do equipamento, o que por sua vez se reflete numa maior economia de custos. A otimização de protocolos de metrologia em saúde, a elaboração de planos de controlo para validação de equipamentos médicos-hospitalares, a sensibilização de profissionais de saúde para o controlo metrológico, assim como o conhecimento das aplicações informáticas da organização são essenciais para uma eficaz gestão da manutenção hospitalar. O Serviço de Instalações e Equipamentos do Centro Hospitalar do Tâmega e Sousa, trabalha no sentido de assegurar uma resposta rápida, otimizada e eficiente para satisfazer as necessidades hospitalares através da aplicação de metodologias e ferramentas da qualidade destinadas à metrologia em saúde. Assim, o objetivo principal deste trabalho é apresentar metodologias e ferramentas aplicadas no controlo de parâmetros de equipamentos médico-hospitalares tais como, dispositivos de infusão, monitores de sinais vitais, eletrocardiógrafos, cardiotocógrafos, desfibrilhadores, incubadoras, aparelhos de fototerapia, bem como, o processo de gestão da manutenção aplicado pelo Serviço de Instalações e Equipamentos. Neste sentido foi possível demonstrar que o controlo metrológico é de extrema importância para uma instituição hospitalar.

Performance Analysis of IEEE 802.15.6 Contention-based MAC Protocol

IEEE International Conference on Communications (IEEE ICC 2015). 8 to 12, Jun, 2015, IEEE ICC 2015 - Communications QoS, Reliability and Modeling, London, United Kingdom.

Energy-efficient MAC protocols for WBANs: Opportunities and challenges

Wireless body area networks (WBANs) are expected to play a significant role in smart healthcare systems. One of the most important attributes of WBANs is to increase network lifetime by introducing novel and low-power techniques on the energy-constrained sensor nodes. Medium access control (MAC) protocols play a significant role in determining the energy consumption in WBANs. Existing MAC protocols are unable to accommodate communication requirements in WBANs. There is a need to develop novel, scalable and reliable MAC protocols that must be able to address all these requirements in a reliable manner. In this special issue, we attracted high quality research and review papers on the recent advances in MAC protocols for WBANs.