ライフサイエンスコーパス: analytical chemistry

1 survey the state of open-source research in analytical chemistry.

2 nium esters (AE) has found widespread use in analytical chemistry.

3 dies is subject to all the usual criteria of analytical chemistry.

4 all-scale NMR detection is a growing area in analytical chemistry.

5 eralize the application of this technique in analytical chemistry.

6 optical or mass spectra is a common need in analytical chemistry.

7 n have numerous applications in clinical and analytical chemistry.

8 ping biosensors for Cu(2+) is a key topic in analytical chemistry.

9 on of low-temperature plasma technologies in analytical chemistry.

10 eir monitoring is of paramount importance in analytical chemistry.

11 m in mass spectrometry and more generally in analytical chemistry.

12 r analyzing mixing paths in biomolecular and analytical chemistry.

13 tation of the nanoparticle-protein corona in analytical chemistry.

14 strated to show its potential application in analytical chemistry.

15 has recently been established as a tool for analytical chemistry.

16 is certainly an interesting application for analytical chemistry.

17 ors has become a growing area of interest in analytical chemistry.

18 iagnostics, as well as wider applications in analytical chemistry.

19 presence of oxygen is of high importance for analytical chemistry.

20 chemistry and, more broadly, to the field of analytical chemistry.

21 as also found very promising applications in analytical chemistry.

22 f new materials are having a major impact on Analytical Chemistry.

23 ience is a constantly growing area of modern analytical chemistry.

24 cience, from supramolecular to materials and analytical chemistry.

25 Research in Russian analytical chemistry (AC) is carried out on a significan

26 d methodology could be classified as a green analytical chemistry alternative, combining the low orga

27 Analytical chemistry and biochemical methods were used t

28 ween the resolving power of current forensic analytical chemistry and biological responses of keyston

29 , despite its many promising applications in analytical chemistry and biology, remains an experimenta

30 Advances in analytical chemistry and computational modeling detail t

31 sults indicate high application potential in analytical chemistry and diagnostics.

32 (-) in materials science, electrochemistry, analytical chemistry and geochemistry are used to illust

33 ule detection is the ultimate sensitivity in analytical chemistry and has been largely unavailable in

34 uantitative in vitro toxicological data with analytical chemistry and human epidemiologic outcomes fo

35 al of fluorescent probes for applications in analytical chemistry and imaging.

36 n remain one of the most important topics of analytical chemistry and material science.

37 We combined analytical chemistry and metabolic computational modelli

38 are two of the most important techniques in analytical chemistry and noninvasive medical imaging, re

39 cusing (IEF) have become instrumental within analytical chemistry and proteomics, cell separations pr

40 the results suggest that this combination of analytical chemistry and statistical approaches can be a

41 In this report, using molecular genetics, analytical chemistry, and mass spectrometry analysis, we

42 l processing method as broadly applicable in analytical chemistry, and we advocate that advanced sign

43 Relative to many other areas in chemistry, analytical chemistry appears singularly lagging behind i

44 The object of this review is to summarise analytical chemistry applications and the tools currentl

45 pectra and demonstrates the capabilities for analytical chemistry applications by comparing electroni

46 oils, it was superior to the widely utilized analytical chemistry approach in revealing the adulteran

47 Chagas disease pathogenesis and presents an analytical chemistry approach that can be broadly applie

48 We demonstrate how high-resolution analytical chemistry approaches can be used effectively

49 tions of this technology to several areas of analytical chemistry are considered.

50 ive mass spectrometric methods developed for analytical chemistry are employed to measure limited set

51 , microbiology, ecology, biogeochemistry and analytical chemistry are enhancing our understanding of

52 trometry (AMS) has been an important area of analytical chemistry because of its capability to rapidl

53 A combination of polymer and analytical chemistry, biological assays and computationa

54 This new interface advances the field of analytical chemistry by introducing a practical modifica

55 Measurements with sensor techniques in field analytical chemistry can be considerably affected by var

56 ctions of research in microbiology, physics, analytical chemistry, cell physiology and ecology.

57 e and engineering including several areas in analytical chemistry, deconvolution needs to be performe

58 propose that a more traditional and rigorous analytical chemistry definition of the detection capabil

59 trins are utilized in many diverse fields of analytical chemistry, due to their propensity to form re

60 sis technique has potential for wider use in analytical chemistry (e.g., in the rapid direct detectio

61 cations including single molecule detection, analytical chemistry, electrochemistry, medical diagnost

62 a potential application to biochemistry and analytical chemistry especially for sample preparation s

63 ion of noisy signals is an important task in analytical chemistry, examples being spectral deconvolut

64 In 2002, we wrote an Analytical Chemistry feature article describing the Phys

65 at ppb levels remains a challenge within the analytical chemistry field.

66 ic mapping tools to visualize the history of analytical chemistry from the 1920s until the present.

67 ic solvent consumption, FPSE meets all green analytical chemistry (GAC) criteria.

68 ve these two forms of chemical communication.Analytical chemistry has an important role to play in de

69 A classic problem in analytical chemistry has been determination of individua

70 direct application to biology, medicine, and analytical chemistry have been so developed, reliance on

71 Recent advances in analytical chemistry have begun to reveal an unexpected

72 Developments in synthetic and analytical chemistry have provided the tools to differen

73 Remote sensing and analytical chemistry identified exposures, which were li

74 This study opens avenues for analytical chemistry in attoliter volumes of fluids for

75 has become one of the most growing areas of analytical chemistry in recent years.

76 n mammalian cells represents a challenge for analytical chemistry in the context of current biomedica

77 Research & Development & Transfer (R&D&T) in Analytical Chemistry in the form of advances that are pr

78 of social responsibility and its relation to analytical chemistry in undergraduate or graduate chemis

79 d results in three different applications in analytical chemistry including (a) multivariate calibrat

80 vestigated whether a combination of targeted analytical chemistry information with unsupervised, data

81 The Division of Analytical Chemistry is celebrating the 75th anniversary

82 ver, achieving anaerobic conditions in field analytical chemistry is difficult.

83 Analytical chemistry is key to the functioning of a mode

84 One major challenge in analytical chemistry is multiplex sensing of a number of

85 ed by adoption of a theragnostic strategy if Analytical Chemistry is to enjoy a better future.

86 stry that herein is entitled "Supramolecular Analytical Chemistry" is emerging, and is predicted to u

87 gas-phase technique, with its foundations in analytical chemistry, it is perhaps counter-intuitive to

88 point-and-shoot" stand-alone technique in an analytical chemistry laboratory to an integrated quantit

89 st eight of twelve recommendations for green analytical chemistry, making TIE a promising tool for ro

90 couraging a broader range of applications in analytical chemistry, materials and biomedicine.

91 s at electrodes, early-stage applications in analytical chemistry, mature applications in disciplines

92 Characterization of these mixtures with analytical chemistry measurements is an important step w

93 This top-down hypothesis-free approach uses analytical chemistry methods, coupled to statistical ana

94 Emerging tools in analytical chemistry, microbiology, and informatics are

95 fluids for potential applications related to analytical chemistry, molecular diagnostics, environment

96 In the field of analytical chemistry, much of their value is in the abil

97 podcast about this feature, please go to the Analytical Chemistry multimedia page at pubs.acs.org/pag

98 podcast about this feature, please go to the Analytical Chemistry multimedia page at pubs.acs.org/pag

99 podcast about this feature, please go to the Analytical Chemistry multimedia page at pubs.acs.org/pag

100 podcast about this feature, please go to the Analytical Chemistry multimedia page at pubs.acs.org/pag

101 podcast about this article, please go to the Analytical Chemistry multimedia page at pubs.acs.org/pag

102 podcast about this feature, please go to the Analytical Chemistry multimedia page at pubs.acs.org/pag

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104 Study designs included analytical chemistry (n = 9), in vitro susceptibility st

105 To develop the analytical chemistry necessary for the identification of

106 presented as structure elucidation tools for analytical chemistry of natural products.

107 st integrated mutagenicity and comprehensive analytical chemistry of spas treated with chlorine, brom

108 n applied (bio)geochemical and environmental analytical chemistry perspective.

109 separation, and detection, point to a viable analytical chemistry platform that encompasses all of th

110 gating applications of nanopore membranes in analytical chemistry-specifically in membrane-based bios

111 From an analytical chemistry standpoint, however, these 'light o

112 e manner in which the established methods of analytical chemistry, such as liquid-liquid extraction a

113 ciplinary approach that integrates genetics, analytical chemistry, synthetic chemistry, biochemistry,

114 Although analytical chemistry techniques are widely used to satis

115 tatively assessed by leveraging a variety of analytical chemistry techniques, including ultraperforma

116 Using a combination of microbiology and analytical chemistry techniques, we have evaluated the e

117 from 100 private drinking water wells using analytical chemistry techniques.

118 and advancement of high-throughput omics and analytical chemistry technologies have reinvigorated the

119 In analytical chemistry, the CCS is approached as a descrip

120 fields ranging from materials processing and analytical chemistry to biology and medicine.

121 The potential of analytical chemistry to predict sensory qualities of foo

122 ns to strengthen the crucial contribution of Analytical Chemistry to progress in Chemistry, Science &

123 These criteria have rarely been used in analytical chemistry to select the adequate calibration

124 ric methods provide a useful addition to the analytical chemistry toolbox of biotechnological starch

125 evelopment of biosensing, bioprocessing, and analytical chemistry tools.

126 ower analyte concentration than conventional analytical chemistry tools.

127 podcast about this feature, please go to the Analytical Chemistry Web site at pubs.acs.org/ancham.).

128 podcast about this Feature, please go to the Analytical Chemistry Web site at pubs.acs.org/journal/an

129 podcast about this feature, please go to the Analytical Chemistry Web site at pubs.acs.org/journal/an

130 podcast about this feature, please go to the Analytical Chemistry website at http://pubs.acs.org/jour

131 podcast about this feature, please go to the Analytical Chemistry website at pubs.acs.org/ac.).

132 podcast about this feature, please go to the Analytical Chemistry website at pubs.acs.org/journal/anc

133 podcast about this feature, please go to the Analytical Chemistry website at pubs.acs.org/journal/anc

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135 designs to be applied in many other areas of analytical chemistry where representative, balanced, and

136 s, and Studentized residuals are standard in analytical chemistry with spectroscopic data.

137 -long matrix effects problem in quantitative analytical chemistry without separation of analytes from