ライフサイエンスコーパス: electronic nose

1 ted, and breathprints were assessed using an electronic nose.

2 mbined application of gas-chromatography and electronic nose.

3 aracteristics that can be identified with an electronic nose.

4 ory and learning process of the brain to the electronic nose.

5 ng an array of gas sensors, also known as an electronic nose.

6 lves the use of multi-sensory devices called electronic noses.

7 fingerprinting for potential construction of electronic noses.

8 chieved in terms of selective and sensitive "electronic noses."

9 ormance; however, the custom-built, low-cost electronic nose also achieved high accuracy, with 94 % u

10 Radar plot of the electronic nose analysis showed that the sensors P30/2,

11 An electronic panel formed by an electronic nose and an electronic tongue has been used t

12 Herein, we utilized an electronic nose and computer vision to check the cooking

13 he effectiveness of flash gas chromatography electronic nose and multivariate data analysis to perfor

14 rated that a combined system formed from the electronic nose and the electronic tongue provides infor

15 The electronic nose and the electronic tongue showed particu

16 registered (seven replicas) by means of the electronic nose and the electronic tongue using partial

17 erating principle of the assay is similar to electronic nose and tongue systems, which combine nonspe

18 pproaches, including electrical sensors like electronic noses and tongues, further enhance detection

19 In addition, electronic-nose- and electronic-tongue systems for the d

20 Electronic noses are successfully used in commercial app

21 Vapor sensors, aka electronic noses, are becoming an increasingly popular a

22 llected for a carbon black-polymer composite electronic nose array during exposure to homologous seri

23 hese results imply the possibility to use an electronic nose as a tool for a quick, effective and non

24 otential of a metal oxide sensor (MOS)-based electronic nose, as a non-destructive method to discrimi

25 rant into each of the polymeric films of the electronic nose at a constant fraction of the odorant's

26 space solid-phase microextraction coupled to electronic nose based on mass spectrometry (HS-SPME/MS-e

27 our knowledge it has not yet been used in an electronic nose based on MS.

28 Herein, we propose an electronic nose based on the programable surface chemist

29 Here, we introduce a miniaturized high-speed electronic nose, characterized by high-bandwidth sensor

30 The results indicated that an electronic nose could distinguish the odor profile of th

31 We hypothesized that the electronic nose could identify and discriminate between

32 The mean response intensity of the electronic nose detectors and the response intensity of

33 intensity of the most strongly driven set of electronic nose detectors were essentially constant for

34 gy and inspiration for the second-generation electronic nose development toward the performance of de

35 layers can operate at room temperature as an electronic nose, disclosing the possibility of using the

36 eath samples were collected using a portable electronic nose (e-nose) device, which analyzed the VOCs

37 An electronic nose (E-nose) serves as a solution by rapidly

38 E-monitoring using electronic nose (e-nose), biosensors, wearable sensors,

39 tudy of headspace of white truffles by using Electronic nose (E-nose), gas chromatography-mass spectr

40 An electronic nose (e-nose), having 18 metal oxide semicond

41 volatile metabolites and the response of an electronic nose (E-nose).

42 Electronic noses (e-nose) and optical noses (o-nose) are

43 re has been a growing interest in the use of electronic noses (e-noses) in detecting volatile organic

44 ulia and Emilia Romagna, were analysed using electronic nose (EN) and isotope ratio mass spectrometry

45 nd, we have investigated the potential of an electronic nose (EN) to diagnose infection of cattle or

46 evious studies on exhaled breath analysis by electronic nose (eNose) technology could discriminate be

47 bility of the exhaled VOC analysis, using an electronic nose (eNose), to identify individuals with un

48 ic fingerprints obtained from a composite of electronic noses (eNoses) and (2) to assess the stabilit

49 Electronic noses (eNoses) are emerging point-of-care too

50 The "bio-electronic nose" fabricated by LIFT is tested in nitroge

51 Electronic nose fluctuations rapidly increase after a RV

52 vide feasibility to the concept of using the electronic nose for managing and detecting lung cancer.

53 order to improve the sensitivity of our bio-electronic nose for specific chemical targets.

54 In this work, a "bio-electronic nose" for vapour phase detection of odorant m

55 In the validation study, the electronic nose had 71.4% sensitivity and 91.9% specific

56 The bio-electronic nose has a comparable sensitivity to the trai

57 We demonstrate an electronic nose in a portable device form, distinguishin

58 paves the way for ubiquitous application of electronic noses in toxic gas detection, food quality co

59 ental techniques, such as mass spectrometry, electronic nose, infrared spectroscopy, etc., have demon

60 ed to test whether a device consisting of an electronic nose inspired by a dog's olfactory system and

61 A new electronic nose instrument was developed at the Universi

62 An electronic nose is a bio-inspired instrument capable aft

63 Electronic nose is a bionic technology that uses sensor

64 The electronic nose is a reliable practical sensor device th

65 the RTIL-coated quartz crystal array as an "electronic nose", it was applied to the analysis of head

66 iO2 surface chemistries to construct a 'nano-electronic nose' library, which can distinguish acetone

67 Using DHS-GC-MS and an electronic nose (MOS), 18 samples of olive oil flavored

68 The data obtained with the electronic nose (MOS), processed statistically, was able

69 pid and non-invasive mass spectrometry-based electronic nose (MS-eNose) method, combined with chemome

70 S-SPME) coupled with mass spectrometry-based electronic nose (MS-eNose), in combination with multivar

71 sreactive sensor arrays (also referred to as electronic noses or tongues in the literature), their cu

72 Our bio-electronic nose outperforms current methods in terms of

73 ed and untreated animals mainly due to three electronic nose's parameters, 24 h carcass temperature a

74 ur score classification system comprising an electronic nose sensor array, a sensor readout interface

75 The "bio-electronic nose" showed low detection limits for the tes

76 The electronic nose strategy was confirmed to be versatile w

77 pheric concentrations by means of a low-cost electronic nose strategy where the readings of a few sen

78 Recent studies of electronic nose system tend to waste significant amount

79 The discrimination accuracy achieved by the electronic nose system was 100% for cystic echinococcosi

80 se films were employed in gas sensors and an electronic nose system, which showed improved responsivi

81 s spectrometry, and a specifically developed electronic nose system.

82 rmal desorption-photoionization ion mobility-electronic nose (TD-PIM-Nose) system, employing thermal

83 of flavour peptides using chromatography and electronic nose techniques have been done.

84 f-concept studies with mass spectrometry and electronic nose technologies have provided independent s

85 ategies, such as solid-state gas sensors and electronic nose technologies, along with their applicati

86 line monitoring with Mass Spectrometry-based electronic nose technology (MS-nose).

87 orescence, and emission of radiation or from electronic noses that detect volatile organic compounds

88 re we propose an alternative strategy, a bio-electronic nose, that capitalizes on the superior capabi

89 This study evaluates the potential of the electronic nose to reliably predict EA contamination in

90 Application of "electronic noses" typically involves recognition of "pre

91 infrared (NIR) spectrometers, as well as an electronic nose, were compared to distinguish between au