ライフサイエンスコーパス: chemical sense

1 agents, their toxicity and their utility in chemical sensing.

2 widely used in environmental, biological and chemical sensing.

3 k-polystyrene (SSEBS) thin polymer films for chemical sensing.

4 otential applications in optoelectronics and chemical sensing.

5 ication (RFID) tag that has been adapted for chemical sensing.

6 rsatile approaches for thermal, acoustic and chemical sensing.

7 s ranging from datacommunication to lidar to chemical sensing.

8 of field-effect transistors in biofluids for chemical sensing.

9 and the application of CNT-based devices in chemical sensing.

10 d and critiqued in reference to their use in chemical sensing.

11 functional materials, biological imaging and chemical sensing.

12 ively utilized for molecular recognition and chemical sensing.

13 imetic mammalian color-detection approach to chemical sensing.

14 n new opportunities for MIR spectroscopy and chemical sensing.

15 ory receptors widely studied in invertebrate chemical sensing.

16 ns to nanolithography, data storage, and bio-chemical sensing.

17 mbling of new materials or in the context of chemical sensing.

18 idly collect low-noise colorimetric data for chemical sensing.

19 delivery of target samples for colorimetric chemical sensing.

20 ered the broad acceptance of bulk optodes in chemical sensing.

21 a promising methodology in bioanalytical and chemical sensing.

22 ractive index in regimes relevant to bio and chemical sensing.

23 find numerous applications in biological and chemical sensing.

24 response that will find wide applications in chemical sensing.

25 lenging issue to many applications including chemical sensing.

26 important issues in advanced biological and chemical sensing.

27 ant route for high-throughput biological and chemical sensing.

28 ss is restricted, opening up new horizons in chemical sensing.

29 echnology for plant root environment in situ chemical sensing), a real-time chemical phenotyping syst

30 Chemical sensing aims to detect subtle changes in the ch

31 urce with a residual capacity to accommodate chemical sensing and biosensing capabilities.

32 suited for applications such as separations, chemical sensing and catalysis.

33 frameworks (MOFs) has led to applications in chemical sensing and electrical energy storage, among ot

34 ems for applications such as photocatalysis, chemical sensing and entangled photon generation.

35 mains of life entrust RNAs to make important chemical sensing and gene control decisions without the

36 w it can facilitate electrical, optical, and chemical sensing and modulation with high spatial and te

37 es prepared by LPNE may have applications in chemical sensing and optical signal processing, and as i

38 ed platform for integrated waveguide - based chemical sensing and photodetection.

39 e door to deploying NV centers as a tool for chemical sensing and single-molecule spectroscopy.

40 ponsive architectures, which can find use in chemical sensing and tunable light sources.

41 aved sensor for simultaneous sweat sampling, chemical sensing and vital-sign monitoring.

42 vanced applications in nanomedicine, energy, chemical sensing, and colloidal plasmonics in general.

43 e in electromagnetic interference shielding, chemical sensing, and energy storage.

44 energy conversion and storage, gas storage, chemical sensing, and many other applications closely re

45 act on many disciplines including photonics, chemical sensing, and medical diagnostics.

46 kinds of application in biological research, chemical sensing, and medical study.

47 replication, transcription and translation, chemical sensing, and morphogenesis.

48 tform for light manipulation, biological and chemical sensing, and nonlinear optics.

49 contribute to variations in flight ability, chemical sensing, and pathogen interactions among EGM an

50 ations such as photocatalysis, luminescence, chemical sensing, and photovoltaics.

51 d much interest for nucleic acid sequencing, chemical sensing, and protein folding at the single mole

52 m high-power fiber lasers, to bioimaging and chemical sensing, and to intriguing physics phenomena.

53 These transducers are attractive for chemical sensing applications for several key reasons.

54 ) based cantilevered device for portable bio-chemical sensing applications is presented.

55 device sensitivity when used in liquid-phase chemical sensing applications.

56 which makes this system very attractive for chemical sensing applications.

57 sic building blocks for novel electronic and chemical sensing applications.

58 ure development toward molecular imaging and chemical sensing applications.

59 tonic crystals for molecular recognition and chemical sensing applications.

60 generation photocatalytic, photovoltaic, and chemical-sensing applications.

61 A new all-in-fiber trace-level chemical sensing approach is demonstrated.

62 A cross-reactive chemical sensing array was made from CdSe Quantum Dots (

63 This method could be applied to chemical sensing arrays to increase the discrimination a

64 It can be retrieved by chemical sensing arrays using correlation analysis.

65 trace molecular detection for biological and chemical sensing as well as for food product quality and

66 The mammalian olfactory system detects chemicals sensed as odours as well as social cues that s

67 lectrical, mechanical, optical, thermal, and chemical sensing, as well as wound healing and other tre

68 ties to achieve ultrasensitive and selective chemical sensing at the single-ion and single-molecule l

69 al revision of the current definition of the chemical senses based upon spatial criteria.

70 s) have successfully been used for selective chemical sensing because the shape and size of their imp

71 hes and applications such as intracavity bio/chemical sensing, biocontrolled photonic devices, and bi

72 enter cells and have opened new frontiers in chemical sensing, biodiagnostics and therapeutics.

73 ed carbon nanotubes, have been exploited for chemical sensing, bioimaging, and quantum technologies.

74 plications in the biomedical field including chemical sensing, biological imaging, drug delivery, and

75 icity, catalysis, energy conversion/storage, chemical sensing, biomedical imaging, and drug delivery.

76 potential for transformative applications in chemical sensing, biomedical imaging, spectroscopy and s

77 various fields, such as composite materials, chemical sensing, biomedicine, optoelectronics and nanoe

78 ave found many applications in the fields of chemical sensing, biosensing, bioimaging, nanomedicine,

79 rip waveguides (DSWGs) suitable for advanced chemical sensing/biosensing is demonstrated.

80 of the most serious subjects in the field of chemical sensing, but it remains an enormous challenge.

81 polystyrene (SSEBS) films for the purpose of chemical sensing by examining the selectivity of the sen

82 Deficits in these chemical senses cannot only reduce the pleasure and comf

83 creased electrical conductivity and improved chemical sensing capabilities.

84 recognition, electric and optical materials, chemical sensing, catalysis, and biomedicine.

85 n, optical, electric and magnetic materials, chemical sensing, catalysis, and biomedicine.

86 olecular absorption and storage, separation, chemical sensing, catalytic and optical properties of su

87 This work presents new chemical sensing devices called "membraneless gas-separa

88 uced, low-cost, disposable, multi-parametric chemical sensing diagnostic platforms.

89 arness them for gas storage and separations, chemical sensing, drug delivery, catalysis, and nanoscal

90 r, are widely used in point-of-care bio- and chemical sensing due to their role in enhancing detectio

91 Furthermore, the role of the chemical sensing element (i.e., gelatin) was assessed by

92 nt concentrations of gelatin (i.e., specific chemical sensing element) and trypsin (i.e., analyte), a

93 f these powerful tools motivated us to print chemical sensing elements directly on the surface of the

94 al to affect applications in areas including chemical sensing, environmental monitoring, biomedical d

95 e devices have been tested in biosensing and chemical sensing experiments.

96 o any plasmonic nanostructure for SERS-based chemical sensing for clinical toxicology and therapeutic

97 tituent nanoparticles combine electronic and chemical sensing functions, we term these systems 'chemo

98 micrometers, is of substantial interest for chemical sensing, imaging, and spectroscopy.

99 volving functional groups of the enzyme in a chemical sense in the reaction.

100 "ordinary" odorants to initiate vomeronasal chemical senses in vertebrates, which play important rol

101 Nerve signaling in humans and chemical sensing in bacteria both rely on the controlled

102 Direct chemical sensing in liquid environments using polymer-gu

103 Conductance-based chemical sensing in metal-semiconductor nanostructures a

104 signaling mechanism provide a blueprint for chemical sensing in small compartments, such as olfactor

105 w impedimetric method opens up new vistas in chemical sensing in that the EIS analysis provides an ad

106 We show that chemical sensing in the mammalian GI tract determines th

107 A motion-based chemical sensing involving fuel-driven nanomotors is dem

108 ironments and demonstrated rapid response in chemical sensing is a major hindrance for further develo

109 Real-time chemical sensing is crucial for applications in environm

110 chemicals relative to the cellular limits of chemical sensing is high.

111 Chemical sensing is of critical importance to human heal

112 binds Pb2+ and is used as a photonic crystal chemical sensing material.

113 ld vast potential for near-infrared imaging, chemical sensing, materials engineering, and quantum inf

114 Chemical sensing may be a general mechanism used by comm

115 Here we report a simple optical chemical sensing method that utilizes the colour change

116 Traditional chemical sensing methodologies have typically relied on

117 Chemical sensing methodology based on electrochemical im

118 elopment of plasmonic circuitry for bio- and chemical sensing, nanoscale optical information processi

119 ls perceive a multitude of odorants by their chemical sense of olfaction, a high-dimensional stimulus

120 Thus, direct chemical sensing of crude oil IR signatures without any

121 The limit of detection for chemical sensing of Crystal Violet and Rhodamine 6G by t

122 Rapid chemical sensing of these compounds can be of great impo

123 create point-of-care biosensors that combine chemical sensing on a biocompatible platform with a broa

124 Highly promising photonics-based chemical sensing opened up by the new guest@MOF composit

125 The chemical sensing performances of these OBP modified tran

126 From a chemical sensing perspective, glycerides are challenging

127 l open a door to a new catalytic-laser-based chemical sensing platform for detecting a wide range of

128 orts a highly sensitive and selective remote chemical sensing platform for surface-adsorbed trace che

129 However, it is unclear if chemical sensing plays a role in establishing mammalian

130 crom widths and were filled partially with a chemical sensing (polymer + dye) layer to produce a micr

131 tes a new concept of self-amplification of a chemical sensing process and can potentially increase th

132 ion and charge transport, photoreception and chemical sensing processes could be a touchstone for rev

133 omote recruitment of coactivators, such that chemical sensing, receptor activation, and transcription

134 The chemical senses, smell and taste, are the most poorly un

135 The chemical senses-smell and taste-allow animals to evaluat

136 drive developments in critical areas such as chemical sensing, soft robotics, and additive manufactur

137 ies are of great interest for fields such as chemical sensing, solid-state light emitters, photocatal

138 Reported herein is a novel heterogeneous chemical sensing strategy based on functionalization of

139 e catalysts; and carbon-based electrodes for chemical sensing, supercapacitors, and batteries.

140 tal cation models representing the substrate chemical sensing surface.

141 atinum site was tested as part of a complete chemical sensing system that included a platinum counter

142 herichia coli (EHEC) relies on inter-kingdom chemical sensing systems to regulate virulence gene expr

143 ave been increasingly used as transducers in chemical-sensing systems.

144 We have developed a novel chemical sensing technique termed high asymmetric longit

145 Optical filter-based chemical sensing techniques provide a new avenue to deve

146 ut for inexpert readers and reviews emerging chemical sensing technologies for the GI tract from an a

147 We introduce a chemical sensing technology, named ChIMES (Chemical Iden

148 EG/ENaC family of genes play a wider role in chemical senses than previously suspected.

149 Taste is a chemical sense that aids in the detection of nutrients a

150 ecify which brain structures are involved in chemical sensing that occurs below a threshold of consci

151 This provides a high dimensionality to chemical sensing that permits high sensitivity (often do

152 ghts the advances in electrically-transduced chemical sensing that rely on 2D materials.

153 light emission is an attractive modality for chemical sensing, the effect of charged surfactant adsor

154 gestion suggests that SARS-CoV-2 targets the chemical senses through mechanisms distinct from those u

155 our planet, however, predominantly use their chemical senses to navigate a rich landscape.

156 uce light, vision may supplement thermal and chemical senses to orient postlarval settlement at vent

157 tinylated reagents, an approach that enables chemical sensing to be performed in specified microenvir

158 lack advanced eyes and thus rely largely on chemical sensing to perceive their surroundings.

159 lications, ranging from nonlinear optics and chemical sensing, to quantum information processing and

160 uch technology requires the integration of a chemical sensing unit combined with an insulin infusion

161 frared spectroscopic sensing to serve as the chemical sensing unit is explored by demonstrating the a

162 With the first demonstration of chemical sensing using on-chip MCT waveguides, monolithi

163 ve photonic crystals have been developed for chemical sensing using the variation of optical properti

164 ared transparent waveguides for liquid-phase chemical sensing utilizing evanescent field absorption s

165 A MCA prepared for chemical sensing was exposed to the samples made of head

166 ented, highlighting examples in the areas of chemical sensing, white light emission, biological imagi

167 tocatalysis, solid-state light emitters, and chemical sensing will be addressed.

168 This provides chemical sensing with high sensitivity (often down to pa

169 molecules that can allow noninvasive/remote chemical sensing with minimal sample preparation.