Clinical Plasma Medicine: State and Perspectives of in Vivo Application of Cold Atmospheric Plasma

Driven by extensive basic research on plasma effects on living cells and microorganisms, plasma medicine has been developed as innovative medical research field during the last years. Besides partially established applications of plasma to treat materials or devices to allow effective medical applications with respect to biocompatibility or microbiological safety, respectively, the primary focus of plasma‐medical research is the direct application of plasma as part of therapeutic concepts. Even if a huge number of atmospheric pressure plasma sources for biomedical applications are described in the literature and characterized by in vitro microbiology and cell biology, there is only a limited number of in vivo experience with animals or human beings up to now. Research in plasma medicine has been mainly focused on applications in dermatology and aesthetic surgery with the aim to support tissue regeneration to improve healing of infected and/or chronic wounds as well as to treat infective and inflamed skin diseases. In general, there are four cold atmospheric plasma sources which were tested comprehensively in animals as well as human beings with respect both to its therapeutic potential and the safety of its application. Three clinical trials with cold atmospheric pressure plasma sources have been carried out yet. All three studies realized in Germany are focused on ulcer treatment. Two cold atmospheric pressure plasma sources got a CE marking as medical device in 2013. This marks a very important step to bring plasma medicine into the clinical daily routine! In future, it will become a general practical requirement to adapt special plasma sources to specific medical applications. Consequently, it is one of the main requirements for the physical and technical field of research and development in plasma medicine to find solutions for modular and flexible plasma devices which are adaptive to some extent e.g. to variable target areas. Based on this as well as together with comprehensive basic research to get much more insight into detailed mechanisms of plasma‐induced effects on living structures and the particular role of single plasma components, further fields of plasma application in vivo will be opened or extended, respectively, with both new targets like cancer treatment or new application sites like teeth, lung, eyes, nasal cavity or gastrointestinal tract. (© 2014 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Plasma Applications: A Dermatological View

The ability to produce cold plasma at atmospheric pressure conditions was the basis for the rapid growth of plasma related application areas in biomedicine. Plasma comprises a multitude of active components such as charged particles, electric current, UV radiation, and reactive species which can act synergistically. The antiitch, antimicrobial, and anti‐inflammatory effect was already demonstrated in in vivo and in vitro experiments and until now no resistance of pathogens against plasma treatment was observed. The combination of the different active agents and their broad range of positive effects on various diseases, especially easily accessible skin diseases, render plasma quite attractive for applications in medicine. Hence, plasma medicine as an independent and promising medical field has been emerged recently. For medical applications two different types of cold plasma are suitable; indirect (plasma jet, plasma torch) and direct plasma sources (dielectric barrier discharge ‐ DBD). So far, no standards and norms are defined for any of these plasma sources. Also, no convenient criteria for standardization of the quality rating of plasma in the view of dermatological applications exist. Although various cold plasma studies have been performed the results are hardly comparable, as physical parameters of the plasma devices, experimental conditions, and organisms used vary greatly. Therefore, standardized risk analyses are necessary for the assessment of different plasma sources. In this review two plasma sources are described and possible risk factors are discussed to estimate the safety of plasma used as a therapeutic tool in dermatology. (© 2014 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Nanomedicine, nanotechnology in medicine

Nanomedicine is a relatively new field of science and technology. It looks sometimes ill defined and interpretations of that term may vary, especially between Europe and the United States.By interacting with biological molecules, therefore at nanoscale, nanotechnology opens up a vast field of research and application. Interactions between artificial molecular assemblies or nanodevices and biomolecules can be understood both in the extracellular medium and inside the human cells. Operating at nanoscale allows to exploit physical properties different from those observed at microscale such as the volume/surface ratio.The investigated diagnostic applications can be considered for in vitro as well as for in vivo diagnosis. In vitro, the synthesised particles and manipulation or detection devices allow for the recognition, capture, and concentration of biomolecules. In vivo, the synthetic molecular assemblies are mainly designed as a contrast agent for imaging.A second area exhibiting a strong development is “nanodrugs” where nanoparticles are designed for targeted drug delivery. The use of such carriers improves the drug biodistribution, targeting active molecules to diseased tissues while protecting healthy tissue.A third area of application is regenerative medicine where nanotechnology allows developing biocompatible materials which support growth of cells used in cell therapy.The application of nanotechnology to medicine raises new issues because of new uses they allow, for instance: Is the power of these new diagnostics manageable by the medical profession? What means treating a patient without any clinical signs? Nanomedicine can contribute to the development of a personalised medicine both for diagnosis and therapy.There exists in many countries existing regulatory frameworks addressing the basic rules of safety and effectiveness of nanotechnology based medicine, whether molecular assemblies or medical devices. However, there is a need to clarify or to modify these regulations which mobilise many experts.France is a country where the medical development of nanotechnology is significant, like Germany, the United Kingdom or Spain, as regards the European Union. There is an active scientific community and industrial partners of all sizes, even if the technology transfer to industry is not as effective as in North America.     

Thermoelectric materials – Compromising between high efficiency and materials abundance

In the context of CO₂ neutral and regenerative energy production, the field of thermoelectrics has shifted more and more into the focus of scientific research in the last few years. Particularly a lot of research projects were started in the field of energy autarkic sensor technology and the so called energy harvesting, i.e. the recycling of otherwise lost energy. A potentially huge industrial branch for thermoelectric applications is the automotive industry with a main emphasis on generating electricity out of the waste heat of combustion engines with the help of thermoelectric generators or using Peltier cooling to replace conventional air conditioning in the passenger compartment. In addition, many niche applications are possible, e.g. as sensors for measuring the air pressure of tires etc. The applications of thermoelectric devices are very versatile. We analyse the potential of the state‐of‐the‐art thermoelectric materials SiGe, PbTe, Bi₂Te₃, FeSi₂ and potentially ZnO with respect to employment in four types of applications, classified by mobile vs stationary and specialized vs. mass application. The selection criteria comprise efficiency, materials availability, costs, environmental friendliness and toxicity. Based on these criteria, a decision matrix for choosing the appropriate material system for a specific application is defined. (© 2011 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Strained 2D Layered Materials and Heterojunctions

2D layered materials and heterojunctions with excellent ductility and controllable atomic‐layer thicknesses have shown promise for use in advanced electronics and optical functional devices. Tailoring of nanoscale configurations and physical properties is essential and required for bespoke fabrication of advanced devices based on 2D materials. Due to the high strain tolerance of 2D layered materials, strain engineering is an effective method to tune their behaviors of electrons and phonons. A wide variety of 2D materials are available with tunable bandgaps from interface coupling effects, making 2D layered heterojunctions a versatile platform for understanding fundamental physical issues. Most physical properties and functional applications can be tailored by applying strain to 2D layered materials and heterostructures to realize a scheduled target in carrier concentration, mobility, and barrier height. Herein, the latest research on the roles of strain in modulating the physical properties of 2D layered materials and heterojunctions is introduced, focusing on the physical properties behind strain modulation in 2D materials. Understanding and manipulating strain in 2D layered materials and heterojunctions is important and beneficial for creating tunable electronic and optoelectronic constructions with advanced components, including functional flexible and wearable devices.     

Intelligent algorithms: new avenues for designing nanophotonic devices [Invited]

The research on nanophotonic devices has made great progress during the past decades. It is the unremitting pursuit of researchers that realize various device functions to meet practical applications. However, most of the traditional methods rely on human experience and physical inspiration for structural design and parameter optimization, which usually require a lot of resources, and the performance of the designed device is limited. Intelligent algorithms, which are composed of rich optimized algorithms, show a vigorous development trend in the field of nanophotonic devices in recent years. The design of nanophotonic devices by intelligent algorithms can break the restrictions of traditional methods and predict novel configurations, which is universal and efficient for different materials, different structures, different modes, different wavelengths, etc. In this review, intelligent algorithms for designing nanophotonic devices are introduced from their concepts to their applications, including deep learning methods, the gradient-based inverse design method, swarm intelligence algorithms, individual inspired algorithms, and some other algorithms. The design principle based on intelligent algorithms and the design of typical new nanophotonic devices are reviewed. Intelligent algorithms can play an important role in designing complex functions and improving the performances of nanophotonic devices, which provide new avenues for the realization of photonic chips.     

磁电子学器件应用原理

本文介绍几种重要的磁电子器件的基本结构和工作原理,包括巨磁电阻与隧穿磁电阻传感器、巨磁电阻隔离器、巨磁电阻与隧穿磁电阻硬盘读出磁头、磁电阻随机存取存储器、自旋转移磁化反转与微波振荡器。自旋晶体管作为未来磁电子学或自旋电子学时代的基本元素,目前大都还处在概念型阶段,本文也将对几种自旋晶体管的大致原理作简要介绍。     

半导体微结构物理效应及其应用讲座第三讲半导体的激子效应及其在光电子器件中的应用

人们对半导体中的电子空穴对在库仑互作用下形成的激子态及其有关的物理性质进行了深入研究.激子效应对半导体中的光吸收、发光、激射和光学非线性作用等物理过程具有重要影响,并在半导体光电子器件的研究和开发中得到了重要的应用.与半导体体材料相比,在量子化的低维电子结构中,激子的束缚能要大得多,激子效应增强,而且在较高温度或在电场作用下更稳定.这对制作利用激子效应的光电子器件非常有利.近年来量子阱、量子点等低维结构研究获得飞速的进展,已大大促进了激子效应在新型半导体光源和半导体非线性光电子器件领域的应用.     

二维范德瓦尔斯异质结构的制备与物性研究

二维范德瓦尔斯材料(可简称二维材料)已发展成为备受瞩目的材料大家族,而由其衍生的二维范德瓦尔斯异质结构的集成、性能及应用是现今凝聚态物理和材料科学领域的研究热点之一.二维范德瓦尔斯异质结构为探索丰富多彩的物理效应和新奇的物理现象,以及构建新型的自旋电子学器件提供了灵活而广阔的平台.本文从二维材料的转移技术着手,介绍二维范德瓦尔斯异质结构的构筑、性能及应用.首先,依据湿法转移和干法转移的分类,详细介绍二维范德瓦尔斯异质结构的制备技术,内容包括转移技术的通用设备、常用转移方法的具体操作步骤、三维操纵二维材料的方法、异质界面清洁.随后介绍二维范德瓦尔斯异质结构的性能和应用,重点介绍二维磁性范德瓦尔斯异质结构,并列举在二维范德瓦尔斯磁隧道结和摩尔超晶格领域的应用.因此,二维材料转移技术的发展和优化将进一步助力二维范德瓦尔斯异质结构在基础科学研究和实际应用上取得突破性的成果.     

二维材料在生物传感器中的应用

自石墨烯发现以来,大量二维层状材料被相继发现.二维材料中载流子被限制在界面1 nm空间内,使其对化学掺杂非常敏感,有望引起生物传感领域的技术变革.生物传感过程无论基于何种传感机制,都包含了检测物识别和信号转化过程.检测物识别通常依靠传感界面的生物探针来完成,信号转换依靠二维材料来实现信号输出.在传感界面处对生物探针和二维材料进行原子级精准构筑,则可精确调控传感过程中的物理化学过程,优化器件的各项指标.本文综述了二维生物传感界面构筑领域的研究进展,重点介绍了目前几种常见的二维生物传感器的传感机制和不同类型的生物探针精准构筑方法,探讨了未来生物传感界面研究的发展方向.