Titlebook: Bioelectronic Nose; Integration of Biote Tai Hyun Park Book 2014 Springer Science+Business Media Dordrecht 2014 bioelectronic nose.biosenso

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賞錢

https://doi.org/10.1007/978-3-8350-9589-2e integral membrane proteins composed of seven transmembrane helices. It is difficult to produce GPCRs including olfactory receptors (ORs) using heterologous cell systems, because of their strong hydrophobicity, and complicated structure. The production of ORs should be a critical process for the de

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https://doi.org/10.1007/978-3-8350-9589-2nds of odorant molecules. Odorant-OR pairs have been characterized using various functional assays, and have provided an understanding of molecular basis in olfaction as well as characterizing specificity between agonist and antagonist. This chapter introduces the most commonly employed, labeled or

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Kundenmanagement & Electronic Commerceon of small molecules. Due to this attribute, CNT-based sensors can detect small molecules with a high sensitivity. Recently, bioelectronic noses based on CNTs have been developed by immobilizing olfactory receptors or nanovesicles on the surface of CNTs. By taking advantages of CNT structures, thes

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Konzeptualisierung des Modells,vices, batteries, and field-effect transistors (FETs). Specifically, well-designed one-dimensional (1D) CP nanostructures have gained attention in various biosensing applications due to their 1D geometry, which can facilitate efficient charge-transfer behavior and signal amplification. Recently, res

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Grundlagen zum Untersuchungsobjekt,try, environmental monitoring, and biomedical diagnosis. For several decades, many efforts have been made to control the process of food production and fragrance and flavor of brands, and to monitor environmental pollutions through the use of comparable technology. There have been several classical