ライフサイエンスコーパス: analytical chemistry

1 e of applications in medical diagnostics and analytical chemistry.

2 ous quantitative and qualitative problems in analytical chemistry.

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

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

5 as also found very promising applications in analytical chemistry.

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

7 roenvironments in biology, biochemistry, and analytical chemistry.

8 cience, from supramolecular to materials and analytical chemistry.

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

10 g the complex systems that form the heart of analytical chemistry.

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

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

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

14 n have numerous applications in clinical and analytical chemistry.

15 f sustainability on the future of HTS-MS and analytical chemistry.

16 ty underlies many foundational principles in analytical chemistry.

17 a analysis approach in the field of volatile analytical chemistry.

18 iciently robust for standard applications in analytical chemistry.

19 ddition to following the principles of green analytical chemistry.

20 demonstrating their positive impact on food analytical chemistry.

21 uing studies in metabolomics, exposomics and analytical chemistry.

22 conservation science, materials science, and analytical chemistry.

23 flecting their cutting-edge contributions to analytical chemistry.

24 aring monoliths suitable for applications in analytical chemistry.

25 ffers versatile applications in the field of Analytical Chemistry.

26 uantifying GA remains a key research area in analytical chemistry.

27 abor-intensive step in molecular biology and analytical chemistry.

28 ch, and a central theme from cell biology to analytical chemistry.

29 vel quantities remains a challenging task in analytical chemistry.

30 al barrier in the future role of aptamers in analytical chemistry.

31 s to use information flow as a benchmark for analytical chemistry.

32 with the R&D activities involved in current analytical chemistry.

33 g, besides following the Principles of Green Analytical Chemistry.

34 of nanobiologics, molecular diagnostics, and analytical chemistry.

35 t advance in AM (3D printing) technology for analytical chemistry.

36 trategy for addressing complex challenges in analytical chemistry.

37 e framework for refining SFC-MS workflows in analytical chemistry.

38 ) enterprise, and the more specific field of analytical chemistry.

39 uires no derivatization, aligning with green analytical chemistry.

40 scussed, including in the framework of green analytical chemistry.

41 etometer and investigate its applications in analytical chemistry.

42 ticipate their growing role in the future of analytical chemistry.

43 is one of the last grand challenges in (bio)analytical chemistry.

44 in styles new to text mining but familiar to analytical chemistry.

45 ties for building highly compact devices for analytical chemistry.

46 ing platforms is a hot topic in the field of analytical chemistry.

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

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

49 eralize the application of this technique in analytical chemistry.

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

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

52 Chiral discrimination is a key problem in analytical chemistry.

53 eir monitoring is of paramount importance in analytical chemistry.

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

55 r analyzing mixing paths in biomolecular and analytical chemistry.

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

57 strated to show its potential application in analytical chemistry.

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

59 is certainly an interesting application for analytical chemistry.

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

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

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

63 fy the use of acoustic levitation as a green analytical chemistry alternative to the currently used b

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

65 enzyme reactors for various applications in analytical chemistry and beyond.

66 Analytical chemistry and biochemical methods were used t

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

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

69 many other applications in energy, sensing, analytical chemistry and biomedical engineering.

70 Advances in analytical chemistry and computational modeling detail t

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

72 Although similarity is ubiquitous in analytical chemistry and everyday life, quantifying samp

73 esis pathway in maize using a combination of analytical chemistry and genetic approaches.

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

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

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

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

78 enomics, modern proteomics, state-of-the-art analytical chemistry and innovative computational biolog

79 ntation, data processing and software, white analytical chemistry and its derivatives, regulatory com

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

81 ions and technologies in fields ranging from analytical chemistry and mechanistic modeling to medicin

82 We combined analytical chemistry and metabolic computational modelli

83 larization, another method that has affected analytical chemistry and NMR beyond expectations.

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

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

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

87 t widespread adoption of machine learning in analytical chemistry and the training of high-performanc

88 ng (DESI-MSI) facilitates the convergence of analytical chemistry and traditional pathology, allowing

89 f investigating complex systems by combining analytical (chemistry) and imaging (tomography) informat

90 vironmental monitoring, national defense and analytical chemistry, and have achieved vital positions

91 nalytical method is a fundamental problem in analytical chemistry, and it is never straightforward.

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

93 radiometals, stemming from nuclear physics, analytical chemistry, and so many other fields, all in o

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

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

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

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

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

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

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

101 as stand-alone affinity binding reagents in analytical chemistry, aptamers have been engineered into

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

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

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

105 Basic skillsets in molecular biology and analytical chemistry are required to carry out this prot

106 Metabolomics is becoming a mature part of analytical chemistry as evidenced by the growing number

107 Using synthetic and analytical chemistry as proof of concept, we isolated an

108 tated 100 recent open access publications in Analytical Chemistry as semantic graphs.

109 of the potential applications of biochar in analytical chemistry as well as in food safety through d

110 This work describes an analytical chemistry based search for the natural S/R pr

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

112 enantiomers is a highly challenging task of analytical chemistry because of the similar physicochemi

113 biology, microbiology, immunology, genetics, analytical chemistry, bioinformatics, and synthetic biol

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

115 ut capabilities to assist experimentation in analytical chemistry, biology, and synthetic biology.

116 e becoming an increasingly important tool in analytical chemistry, biosciences, and medicine.

117 y applications in the fields of physical and analytical chemistry, biosensing, and colloidal science.

118 that can be employed in diverse areas within analytical chemistry, biotechnology, biomedicine, and mo

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

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

121 Generality in analytical chemistry can be manifested in impactful plat

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

123 MicroRNA detection is currently a crucial analytical chemistry challenge: almost 2000 papers were

124 They are also more accessible in the analytical chemistry classroom compared with typical ben

125 s or calibration curves greatly interest the analytical chemistry community.

126 teomics and is thus of relevance for a large analytical chemistry community.

127 Or the inception of a nontechnical novel analytical chemistry course for health sciences majors?

128 nd lab-on-a-chip (LOC) technologies in their analytical chemistry courses.

129 delines, and the inclusion of AI training in analytical chemistry curricula.

130 The undergraduate analytical chemistry curriculum serves to equip students

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

132 Similarly, in analytical chemistry, deep learning has enhanced data an

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

134 ecular detection for applications related to analytical chemistry, diagnostics, environmental monitor

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

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

137 on applications founded on the principles of analytical chemistry education and techniques.

138 s lag behind, precluding the transition from analytical chemistry efforts to health risk assessment.

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

140 ise in developing efficient bionanozymes for analytical chemistry, environmental protection, and biot

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

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

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

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

145 Green analytical chemistry focuses on making analytical proced

146 This work opens up an unusual approach in analytical chemistry for developing various sensing plat

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

148 rs is the most promising direction in modern analytical chemistry from the point of view of real clin

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

150 Green Analytical Chemistry (GAC) was created to develop method

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

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

153 otential chemosensors described in classical analytical chemistry has been successfully implemented i

154 Analytical chemistry has never yielded such a wealth of

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

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

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

158 y approach covering synthetic, physical, and analytical chemistry, high-throughput experimentation an

159 ing is attracting attention in all fields of analytical chemistry, i.e., clinical, pharmaceutical, en

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

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

162 minimal representation (toward awareness) of analytical chemistry in health sciences programs are pre

163 Increased notability of analytical chemistry in health sciences textbooks?

164 f student perspectives on the versatility of analytical chemistry in healthcare and a review of the s

165 the goal of acknowledging the prominence of analytical chemistry in medicine today.

166 dary) conditions is an essential activity in analytical chemistry in order to avoid a complete recali

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

168 hlights the challenges and opportunities for analytical chemistry in the built environment.

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

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

171 ategy for adopting the latest guidelines for analytical chemistry in the pharmaceutical industry (ICH

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

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

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

175 eadily be applied to other types of food and analytical chemistry instruments.

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

177 A significant and common problem in analytical chemistry is determining if a sample belongs

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

179 Analytical chemistry is far from being the sole field af

180 Analytical chemistry is key to the functioning of a mode

181 The growth of (bio)sensors in analytical chemistry is mainly attributable to the devel

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

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

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

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

186 ass spectrometry (MS) has great potential in analytical chemistry laboratories operating in a variety

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

188 With recent advances in analytical chemistry, liquid chromatography high-resolut

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

190 alysis, protein biochemistry and biophysics, analytical chemistry, material science, energy, and envi

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

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

193 eter samples were analyzed using an advanced analytical chemistry measurement platform that combines

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

195 thodology, this method can be named as green analytical chemistry method with a score of 0.77.

196 The majority of analytical chemistry methods requires presence of target

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

198 spectroscopy (NMR) is one of the most potent analytical chemistry methods, providing unique insight i

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

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

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

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

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

207 To develop the analytical chemistry necessary for the identification of

208 is increasingly present across all phases of analytical chemistry, not only in experimental workflows

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

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

211 Ns) represent a groundbreaking innovation in analytical chemistry, offering a new paradigm for molecu

212 chanisms of action from pharma, biomedicine, analytical chemistry, or toxicology, and finding strateg

213 ough the current state of DNA nanotechnology analytical chemistry, outlining important factors to con

214 This analytical chemistry Perspective focuses on fostering ev

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

216 neficial in the fields of materials science, analytical chemistry, physical chemistry, food science,

217 usters corresponding to key domains, such as analytical chemistry, plant biology, pharmacology, and c

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

219 In analytical chemistry, preconcentration represents a crit

220 These lab-on-a-tip systems align with green analytical chemistry principles by reducing chemical was

221 The method was aligned with green analytical chemistry principles, achieving scores of 0.5

222 3 indicates a favorable alignment with green analytical chemistry principles, highlighting its improv

223 nd quantitation while best integrating green analytical chemistry principles.

224 nd quantitation while best integrating green analytical chemistry principles.

225 ges, the transformative potential of SANs in analytical chemistry promises significant advances in bo

226 is valid throughout the different periods of analytical chemistry, regardless of the analytical metho

227 luation of analytical methods to ensure that analytical chemistry remains at the forefront of scienti

228 ool to be extensively applied to the process analytical chemistry scenario.

229 Despite recent technological developments in analytical chemistry, separation and direct characteriza

230 such as neuroscience, environmental science, analytical chemistry, separation, catalysis, and nanopar

231 ia are taken from the 12 principles of green analytical chemistry (SIGNIFICANCE) and are transformed

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

233 published in leading journals for topics in analytical chemistry, spectroscopy, bioimage super-resol

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

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

236 Analytical chemistry swiftly grasped the significance of

237 rge molecules and open new opportunities for analytical chemistry, synthetic biology, and nanomedicin

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

239 Although analytical chemistry techniques are widely used to satis

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

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

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

243 ons are challenging to detect using standard analytical chemistry techniques.

244 The method is demonstrated on comparisons of analytical-chemistry techniques and semantically enriche

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

246 pen for the development of a new frontier in analytical chemistry that creates a new set of tools for

247 day with simple devices, and in the field of analytical chemistry the pressure-based signaling strate

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

249 cs are core concepts that are fundamental to analytical chemistry; thus, covering them will inherentl

250 we present here could be a step toward using analytical chemistry to advance the utilization of human

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

252 goal is to convey the exciting potential of analytical chemistry to contribute to understanding the

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

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

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

256 iologists continue to improve enzymology and analytical chemistry to support AEGIS-LIVE, this technol

257 g concern and one of the major challenges in analytical chemistry today.

258 n techniques in microfluidics are a powerful analytical chemistry tool, although an inherent limitati

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

260 rigorous study design, coupled with advanced analytical chemistry tools, provided important insights

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

262 ower analyte concentration than conventional analytical chemistry tools.

263 : Should there be a higher representation of analytical chemistry topics in undergraduate and graduat

264 dded potentiostat, our approach can leverage analytical chemistry toward increasingly important, more

265 ensing technologies for the GI tract from an analytical chemistry viewpoint.

266 toxicity assays were performed, and targeted analytical chemistry was used to measure media and tissu

267 Using static exposures coupled with analytical chemistry, we determined the 24-h LC(50) valu

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

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

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

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

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

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

276 d can be leveraged across various domains of analytical chemistry, where the detection of rare events

277 ed from the currently accepted definition of analytical chemistry, which reflects the paradigm change

278 d applications of artificial intelligence in analytical chemistry, which shall lead to increased effi

279 The pairing of analytical chemistry with genomic techniques represents

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

281 everage IRIS toward a transformative tool in analytical chemistry, with potential applications expand

282 erminations are critical across the field of analytical chemistry, with the advances in qNMR being of

283 g the performance of instrumental methods in analytical chemistry, with the well-known formula "three

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

285 can better prepare undergraduates for modern analytical chemistry work in various industries and fiel