標(biāo)題: Titlebook: Bioelectronic Nose; Integration of Biote Tai Hyun Park Book 2014 Springer Science+Business Media Dordrecht 2014 bioelectronic nose.biosenso [打印本頁] 作者: Iridescent 時(shí)間: 2025-3-21 16:04
書目名稱Bioelectronic Nose影響因子(影響力)
書目名稱Bioelectronic Nose影響因子(影響力)學(xué)科排名
書目名稱Bioelectronic Nose網(wǎng)絡(luò)公開度
書目名稱Bioelectronic Nose網(wǎng)絡(luò)公開度學(xué)科排名
書目名稱Bioelectronic Nose被引頻次
書目名稱Bioelectronic Nose被引頻次學(xué)科排名
書目名稱Bioelectronic Nose年度引用
書目名稱Bioelectronic Nose年度引用學(xué)科排名
書目名稱Bioelectronic Nose讀者反饋
書目名稱Bioelectronic Nose讀者反饋學(xué)科排名
作者: 狼群 時(shí)間: 2025-3-21 20:44
Mechanisms of Olfaction,tly different between different animal species and even between different olfactory organs of the same species. This chapter includes a description of the anatomy of the mammalian olfactory system and an overview of the receptors. The signaling mechanism and expression pattern of these receptors is 作者: EXPEL 時(shí)間: 2025-3-22 03:09
Olfactory Receptor Proteins,eins. ORs being G protein-coupled receptors (GPCRs) are integral membrane proteins composed of seven transmembrane spanning helices. In mammals, there exist as many as 1,000 OR genes accounting for about 3?% of the genome. Unfortunately, no three-dimensional (3D) structure of OR is available and one作者: ESO 時(shí)間: 2025-3-22 06:18 作者: 金絲雀 時(shí)間: 2025-3-22 11:16 作者: Introduction 時(shí)間: 2025-3-22 15:54 作者: integral 時(shí)間: 2025-3-22 19:26 作者: deficiency 時(shí)間: 2025-3-22 23:54 作者: 2否定 時(shí)間: 2025-3-23 04:06
Production of Olfactory Receptors and Nanovesicles Using Heterologous Cell Systems for Bioelectronie 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作者: 引起 時(shí)間: 2025-3-23 08:10 作者: originality 時(shí)間: 2025-3-23 11:07 作者: 舊式步槍 時(shí)間: 2025-3-23 14:32 作者: 詞匯記憶方法 時(shí)間: 2025-3-23 21:09
Conducting Polymer Nanomaterial-Based Sensor Platform for Bioelectronic Nose,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作者: 抗原 時(shí)間: 2025-3-24 00:33
Applications and Perspectives of Bioelectronic Nose,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 作者: WAIL 時(shí)間: 2025-3-24 05:47
Tai Hyun ParkProvides overview from concept to development and future perspectives.Covers applications in wide variety of areas and industries and up to date overview of advances in olfactory sensing devices.Descr作者: 完全 時(shí)間: 2025-3-24 06:51 作者: 一再遛 時(shí)間: 2025-3-24 11:34
https://doi.org/10.1007/978-3-8350-9022-4hanism in the early 1990s, extensive studies to develop electronic devices that mimic the function of animal noses have been conducted. Most devices have been composed of an array of several sensors that react to chemical compounds. The odor is characterized by analyzing the response patterns genera作者: 大洪水 時(shí)間: 2025-3-24 17:45
Zusammenfassung und Diskussion,tly different between different animal species and even between different olfactory organs of the same species. This chapter includes a description of the anatomy of the mammalian olfactory system and an overview of the receptors. The signaling mechanism and expression pattern of these receptors is 作者: 向外供接觸 時(shí)間: 2025-3-24 21:33
Nutzung kundenbezogener Informationen,eins. ORs being G protein-coupled receptors (GPCRs) are integral membrane proteins composed of seven transmembrane spanning helices. In mammals, there exist as many as 1,000 OR genes accounting for about 3?% of the genome. Unfortunately, no three-dimensional (3D) structure of OR is available and one作者: 擋泥板 時(shí)間: 2025-3-25 01:21 作者: lymphedema 時(shí)間: 2025-3-25 04:07 作者: –FER 時(shí)間: 2025-3-25 10:03 作者: 群居動(dòng)物 時(shí)間: 2025-3-25 11:51 作者: HARD 時(shí)間: 2025-3-25 18:31 作者: 賞錢 時(shí)間: 2025-3-25 23:18
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作者: 下級(jí) 時(shí)間: 2025-3-26 02:11 作者: CHYME 時(shí)間: 2025-3-26 05:49
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 作者: 揭穿真相 時(shí)間: 2025-3-26 08:44
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作者: 前奏曲 時(shí)間: 2025-3-26 14:41
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作者: 表示問 時(shí)間: 2025-3-26 20:51
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 作者: 上流社會(huì) 時(shí)間: 2025-3-26 23:42
https://doi.org/10.1007/978-94-017-8613-3bioelectronic nose; biosensors; olfactory receptor作者: 阻擋 時(shí)間: 2025-3-27 01:19 作者: Conquest 時(shí)間: 2025-3-27 09:20
Concept of Bioelectronic Nose, such as olfactory receptors and odorant-binding proteins. The secondary transducer is a highly sensitive optical or electrical sensor platform that converts biological events into measurable signals. In this chapter, the basic concept and principles of bioelectronic noses are described. In addition作者: monologue 時(shí)間: 2025-3-27 11:11 作者: 鄙視讀作 時(shí)間: 2025-3-27 14:42 作者: misanthrope 時(shí)間: 2025-3-27 21:39
Conducting Polymer Nanomaterial-Based Sensor Platform for Bioelectronic Nose, olfactory receptors (hORs), a so-called “bioelectronic nose” (B-nose), through an immobilization process. The sensing platforms using 1D CP nanomaterials were integrated into a liquid-ion gated FET system, resulting in the development of a high-performance FET-type B-nose. Real-time responses from 作者: 混雜人 時(shí)間: 2025-3-28 01:49 作者: contrast-medium 時(shí)間: 2025-3-28 02:45
ry biological elements, and nanotechnology for the development of various sensing devices. The purpose of this book is to provide the reader with a concept, basic sciences, fundamental technologies, applications, and perspectives of the bioelectronic nose..978-94-024-0180-6978-94-017-8613-3作者: AUGER 時(shí)間: 2025-3-28 07:04
https://doi.org/10.1007/978-3-8350-9022-4 such as olfactory receptors and odorant-binding proteins. The secondary transducer is a highly sensitive optical or electrical sensor platform that converts biological events into measurable signals. In this chapter, the basic concept and principles of bioelectronic noses are described. In addition作者: NEEDY 時(shí)間: 2025-3-28 13:35 作者: boisterous 時(shí)間: 2025-3-28 16:11 作者: 貪婪性 時(shí)間: 2025-3-28 21:00
Konzeptualisierung des Modells, olfactory receptors (hORs), a so-called “bioelectronic nose” (B-nose), through an immobilization process. The sensing platforms using 1D CP nanomaterials were integrated into a liquid-ion gated FET system, resulting in the development of a high-performance FET-type B-nose. Real-time responses from 作者: BACLE 時(shí)間: 2025-3-29 02:55 作者: Sigmoidoscopy 時(shí)間: 2025-3-29 03:55 作者: 斗志 時(shí)間: 2025-3-29 07:44
Production of Olfactory Receptors and Nanosomes Using Yeast System for Bioelectronic Nose,ne and produce ORs in cells, to allow the screening of their response to odorants. During the last decade, various ORs were successfully expressed in ., and many improvements achieved. This chapter reviews the latest developments of yeast-based technologies to produce ORs and test their functional response.作者: recession 時(shí)間: 2025-3-29 14:33 作者: DIKE 時(shí)間: 2025-3-29 16:59 作者: 咆哮 時(shí)間: 2025-3-29 21:23
https://doi.org/10.1007/978-3-322-84467-5pment of olfactory cell cultivation methods and the application of cultivated olfactory cells and bio-engineered cells to various types of bioelectronic devices. These applications may ultimately facilitate the development of biomimetic artificial noses.作者: 哺乳動(dòng)物 時(shí)間: 2025-3-30 02:26 作者: averse 時(shí)間: 2025-3-30 05:37
Kundenmanagement & Electronic Commerce on to suitable transducers. Using a quartz crystal microbalance platform as a transduction element, it is possible to detect and measure quantitatively concentrations of volatile analytes at parts per million concentrations in air.作者: 下級(jí) 時(shí)間: 2025-3-30 10:50
https://doi.org/10.1007/978-3-8350-9589-2binding assays to ORs with optical methods such as Ca. imaging, reporter-gene technology, surface plasmon resonance (SPR) and so on. For OR and GPCR study, a set of optical technologies including—but not limited to—Raman spectroscopy, photonic crystal, and total internal reflection (TIR) are also discussed in an analytical science point of view.作者: Trabeculoplasty 時(shí)間: 2025-3-30 15:27 作者: 胎兒 時(shí)間: 2025-3-30 17:18 作者: consent 時(shí)間: 2025-3-31 00:13
