ライフサイエンスコーパス: analytical

1 The development of analytical alternatives might have advantages such as gr

2 fect-directed analysis (EDA) utilizing novel analytical and biological approaches to a water sample e

3 Here, using a combination of analytical and biophysical methods in vitro, we tested w

4 Here, we present FishTaco, an analytical and computational framework that integrates t

5 y, we implemented a workflow including novel analytical and data evaluation methods aiming to identif

6 Using advanced analytical and imaging techniques, such as vibrating ion

7 rom both simulation and modelling as well as analytical and numerical analysis points of view, and th

8 Here, we present analytical and numerical evidence for the existence of a

9 act diagonalisation approach, we derive both analytical and numerical results for the population of v

10 e by the structural biology, bioinformatics, analytical and pharmaceutical communities, and has forme

11 ed particle, which is used in many fields of analytical and physicochemical science.

12 This scheme may be informed by analytical and semi-analytical models for the network st

13 itically analyzes their ability to test both analytical and simulation-based models.

14 A variety of analytical and visualization tools provide support for e

15 d a spatially arrayed detector, can increase analytical and volumetric throughputs by orders of magni

16 The combined analytical approach allowed the quantification and spati

17 te this problem, we developed a graphing and analytical approach for use with more than two variables

18 The use of a worst-rank analytical approach proved to be an important limitation

19 Here we develop an analytical approach that corrects a major cause of measu

20 We report an analytical approach to integrate ordinal clinical inform

21 se limitations necessitate a new, integrated analytical approach to pneumonia etiology data.

22 Thanks to this analytical approach we identified a fragrant lactone cor

23 This work describes a versatile analytical approach, which combines the proxy ligand ele

24 pneumonia etiology and review how the common analytical approaches (eg, descriptive, case-control, at

25 Complemented by several alternative analytical approaches (i.e., in vivo visualization and i

26 9% difference in predictions between the two analytical approaches across all samples analyzed, with

27 erent amplification strategies is one of the analytical approaches allowing the screening of protein

28 We discuss some of the analytical approaches applied to extract biological know

29 Our experimental and analytical approaches are important alternatives and com

30 Altogether, combining observation scales and analytical approaches enabled to quantify SM degradation

31 ritical quality attribute (CQA), and several analytical approaches have been proposed that facilitate

32 nalyzed the 187-taxon dataset using multiple analytical approaches, and we evaluated several alternat

33 tuations in the internal state, complicating analytical approaches.

34 y comparisons are hampered by differences in analytical approaches.

35 f random-walk-based models and probabilistic analytical approximations.

36 living cells, thus hold great promise in the analytical aspects of H2S.

37 n, individual layer treatment, and multiplex analytical assays.

38 Linearity in the analytical blank was obtained by using the square root o

39 Using analytical calculations and numerical simulations, we de

40 have been achieved in paper and have enabled analytical capabilities comparable to those of conventio

41 CHARON-PTR-ToF-MS technique adds significant analytical capabilities for characterizing particulate o

42 living cells at the nanoscale poses a unique analytical challenge, as cells are dynamic, chemically d

43 It shows analytical characteristics comparable to glucose sensors

44 The biosensors showed good analytical characteristics to glucose determination in w

45 The optimization, analytical characterization and validation of a novel io

46 Analytical characterization of DNA microviscosity provid

47 rometry (HX-MS) in many contexts, especially analytical characterization of various protein therapeut

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

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

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

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

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

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

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

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

56 form to promote a closer interaction between analytical chemists and modellers to identify models for

57 Here, we write to introduce analytical chemists who are new to the open-source movem

58 A 3D analytical cochlear model was developed that fits the an

59 is is followed by E/Z separation in a fourth analytical column.

60 tationary phases tend to produce well packed analytical columns with small particles.

61 obes for environmental analysis are possible analytical configurations.

62 Using analytical considerations and numerical simulation, we s

63 ow Cytometry (MFC) produces multidimensional analytical data on the quantitative expression of multip

64 ural networks (ANNs) were applied on several analytical datasets, namely standard merceological param

65 We present our approach with an analytical derivation, a numerical demonstration, and an

66 ase with non-uniform doping profiles and the analytical description is verified with drift-diffusion

67 The analytical descriptions of the conductance and potential

68 amer-based (E-AB) sensors offer advantageous analytical detection abilities due to their rapid respon

69 ed electrochemical micro fluidic paper-based analytical device (EmuPADs) for electrochemical sensing

70 The device, called a hybrid paper-based analytical device (hyPAD), uses faradaic electrochemistr

71 erein, we present a colorimetric paper-based analytical device (PAD) combined with immunomagnetic sep

72 that 3D-printing will have on the future of analytical device fabrication, miniaturization, and func

73 design and characteristics of a paper-based analytical device for analyte concentration enrichment.

74 icle describes a 3D microfluidic paper-based analytical device that can be used to conduct an enzyme-

75 A smartphone is a facile, handy-analytical device that makes our lives comfortable and s

76 Three-dimensional microfluidic paper-based analytical devices (3D-muPADs) are an evolution of singl

77 for lateral flow assays, microfluidic paper analytical devices and other point-of-care diagnostic as

78 r the development of lateral flow assays and analytical devices based on paper microfluidics.

79 Paper-based micro analytical devices offer significant advantages compared

80 tic tools increases the demand for efficient analytical devices to detect ZIKV infection.

81 ake aptamers broadly applicable (e.g., as an analytical, diagnostic, or separation tool).

82 on mobility separation can add an orthogonal analytical dimension, reducing ion interference to impro

83 constraints on sample type, preparation, and analytical environment.

84 Based on nanoparticle dynamic simulation and analytical estimates, we attribute the stochasticity in

85 As part of this, we develop analytical expressions for key probability distributions

86 linear range between 0.3 and 15mM with good analytical features and being able of quantifying glucos

87 ble with a smartphone detector, and displays analytical figures of merit that are comparable to stand

88 eadout computations of the network in simple analytical form and derive a binocular likelihood model

89 In both cases analytical formulas are derived for the spin-orbit torqu

90 s study aims to introduce a novel conceptual analytical framework for identification of biomarkers of

91 We developed a novel analytical framework for mapping and testing the distrib

92 es behind the theoretical, experimental, and analytical framework presented herein offer an automated

93 g quality in cardiovascular imaging using an analytical framework put forth by the Institute of Medic

94 dicating the potential applicability of this analytical framework to larger and less well-characteriz

95 We use an analytical framework to show that temporal networks can,

96 eighted mean of 764.8 +/- 0.3/0.6 ka (2sigma analytical/full uncertainty) indicating eruption only ap

97 We derive an analytical function based on the elastic-viscoelastic co

98 ceutical products, chemical waste dumps, and analytical-grade material, covering the production time

99 actor technology, metabolic engineering, and analytical instrumentation are improving the production,

100 n attractive high value addition to existing analytical instrumentation.

101 ma analysis but also of the use of different analytical instruments in this field, highlighting the r

102 Using a spectrum of state-of-the-art analytical instruments, we present in this study for the

103 ally, its promising role in state-of-the-art analytical laboratories for the identification of small

104 The results obtained will be very useful for analytical laboratory control, risk assessment, establis

105 The analytical limits were moreover much lower than the maxi

106 We developed a decision analytical Markov model to simulate opioid overdose, HIV

107 mical sensors are an attractive platform for analytical measurements due to their high sensitivity, p

108 The analytical method applied was direct liquid injection in

109 on the doping level is well described by an analytical method based on an electron-counting rule.

110 We also introduce a novel analytical method for an objective assessment of the mig

111 the new SPME probes were used to validate an analytical method for determination of banned doping sub

112 aims to employ an (18)O-isotope ratio-based analytical method for quantitative estimation of CA acti

113 This study aimed to develop an analytical method for the determination of tryptophan an

114 A simple and sensitive analytical method has been developed employing gas chrom

115 Moreover, the novel analytical method of using 2D plasmonic nanoparticle as

116 In this study, we developed a new analytical method that combines magnetic molecularly imp

117 Thus, a qualitative analytical method to detect Aspergillus flavus in food s

118 This analytical method using surface-enhanced Raman spectrosc

119 Furthermore, an analytical method using ultra performance liquid chromat

120 A fast and simple analytical method was developed and characterized for th

121 An analytical method was developed and validated for the de

122 The analytical method was then applied to 291 food samples f

123 this statement, bio-sensing, as a sensitive analytical method, opens novel avenues in biological asp

124 In this work, an analytical methodology in combination with a low power b

125 Advantages and limitations of both analytical methods are contrasted in the context of RIPF

126 Proper extraction and analytical methods are critical for quantification.

127 n efficiently, rapid and easy-to-use on-site analytical methods are needed.

128 However, to exploit this potential, novel analytical methods are required, capable of discovering

129 Analytical methods based on mass spectrometry (MS) have

130 nt health has created a significant need for analytical methods capable of rapidly identifying intera

131 as water pollutants yet, due to the lack of analytical methods capable to detect them.

132 n clarifying reaction mechanisms, developing analytical methods for both liquid and gas phases, and i

133 To address this limitation, we present analytical methods for designing origami-based closed-lo

134 However, required analytical methods for the simultaneous measurement of t

135 dented LOD compared with previously reported analytical methods for TNT detection.

136 Several analytical methods have been proposed for analyzing Tn-S

137 proaches, study designs, and statistical and analytical methods have emerged for studying gene-enviro

138 being used to construct biosensors and other analytical methods in various fields of science.

139 Electrochemical-based analytical methods offer an effective, rapid, and simple

140 global scale remain largely unknown, but new analytical methods such as high-resolution mass spectrom

141 This has raised the need for analytical methods that can both perform rapid sample an

142 The feature of our newly developed analytical methods that coupled sample pre-treatment (sa

143 ctal organization according to six different analytical methods that included Power Spectrum, Enright

144 The development of new analytical methods to accurately quantify hydrogen perox

145 combining inferences derived from two unique analytical methods to inform decisions related to risk-b

146 ng demand for rapid, sensitive, and low cost analytical methods to routinely screen antibiotic residu

147 We then apply the analytical methods to the anatomical brain networks of h

148 modality and address some of the more common analytical methods used with this data.

149 Among other analytical methods, electrochemical approaches have been

150 l consideration, including the improved data analytical methods, environmental exposure assessment, a

151 Coordinated protocols and new analytical methods, particularly the use of exact sequen

152 tudied, including four studies using optimum analytical methods, were followed by reductions in pesti

153 al and requires novel study designs and data analytical methods.

154 dvantages with regard to previously reported analytical methods.

155 Analytical microscopy demonstrated internalization and d

156 An analytical model based on field susceptibilities is deve

157 We present an analytical model that allows simulating ATDs resulting f

158 ctive of this study is to develop a new semi-analytical model to simulate the flow inside a homogenou

159 An analytical model was developed that incorporated an expo

160 ethod, confirm the trends extracted from the analytical model.

161 sms resulting in its unique properties using analytical modeling and experiments.

162 Analytical modeling suggests that crosstalk should overw

163 Experimental data and analytical modelling show that myosin-II-dependent force

164 cheme may be informed by analytical and semi-analytical models for the network structure, or through

165 This contradicts analytical models of homogeneous materials in which the

166 The potential to revolutionize analytical NMR and clinical diagnosis through this appro

167 oss point serves as a simple yet informative analytical parameter to analyze the electrokinetic trans

168 The remarkable analytical parameters and long term stability of both th

169 After the analytical parameters optimization, a linear detection r

170 The influences of the analytical parameters such as pH, waiting time of alumin

171 c mode would provide achievement of the best analytical performance characteristics.

172 The Veris HCV Assay demonstrated an analytical performance comparable to that of currently m

173 Comparatively little work has addressed analytical performance criteria, particularly criteria r

174 r the optimum conditions exhibited excellent analytical performance for EDI determination, ranging fr

175 cost polymer based microarray and tested its analytical performance for integrated single-molecule di

176 The proposed aptasensor showed excellent analytical performance in comparison with current HER2 b

177 With thanks of the good resulting analytical performance in this work, the proposed method

178 Crucial to reliable quantification and analytical performance is the calibration of the ATR-FTI

179 work was to demonstrate and to evaluate the analytical performance of a combined falling drop/open p

180 , sensing mechanisms, target biomarkers, and analytical performance of the paper biosensors with thei

181 ation and indicates the good selectivity and analytical performance of the v-CuNWs.

182 he sensor features greater power economy and analytical performance relative to commercially availabl

183 The methodology showed excellent analytical performance with good selectivity, linearity

184 sensor presented here yields an outstanding analytical performance, with a linear range that spans f

185 se to increased storage stability and better analytical performance.

186 etrological characterization of the system's analytical performances for concentration measurements s

187 oronic acid (BA) based cytosensors and their analytical performances in cancer cell detection were an

188 )/BA based cytosensors showed extremely good analytical performances in cancer cell detection with li

189 several types of supports, showing excellent analytical performances such as, for example, R(2) of th

190 and immune cells, we propose an integrative analytical pipeline encompassing the evaluation of molec

191 We have created an analytical pipeline to recover immune receptor alleles f

192 cally profile only tens of samples, and most analytical pipelines are optimized for these smaller stu

193 e same products, thus providing a consistent analytical platform for investigation of potential nanos

194 the device is not turbulent and provides an analytical platform for the investigation of homogeneous

195 Using a novel analytical platform, Google Earth Engine, and open acces

196 ed for the development and implementation of analytical platforms enabling detection and quantitation

197 many biosensing technologies, which require analytical platforms with high selectivity and sensitivi

198 adder cancers characterized by multiple TCGA analytical platforms.

199 result is a single code capable of learning analytical potentials, non-linear density functionals, a

200 Initial analytical predictions utilized generalization of a simp

201 l inspire new users to adopt 2D-LC for their analytical problems.

202 In this paper, a simple and effective analytical procedure based on dispersive micro solid-pha

203 d on repeated measurements across the entire analytical procedure is 0.6 per thousand for delta(15)N

204 In this study, a new analytical procedure was developed and validated to meas

205 ient samples that must not be altered by the analytical procedure.

206 scribe an integrated and straightforward new analytical protocol that identifies plant gums from vari

207 standard (IS) for lignin quantification via analytical pyrolysis coupled to gas chromatography with

208 This limits the analytical rate to approximately 50K particles/s and the

209 The analytical recovery of added urea in serum was 106.33%.

210 meters investigated has been explained by an analytical relationship between the effective vapor comp

211 oduced to the T-CUAs were examined for their analytical response to nitric oxide (NO(*)).

212 dated method is essential to obtain reliable analytical results since the legislation establishes max

213 The accuracy and reliability of analytical results were challenged by method validation

214 With analytical rheology, we quantify real-time platelet paus

215 chromatography (RPLC-HILIC) coupling and an analytical scale supercritical fluid chromatography (SFC

216 The analytical sensitivities determined by probit analysis w

217 st, simple and easy-to-use method to improve analytical sensitivity by integrating sponge shunt into

218 First, Joule heating substantially impacts analytical sensitivity due to diffusive losses of protei

219 st, rapid, and simple features, but the poor analytical sensitivity of LFA restricts its application.

220 The precision, analytical sensitivity, performance with negative sample

221 As advances in analytical separation techniques, mass spectrometry inst

222 ension of structural information in MS-based analytical separations.

223 the sensing of APAP and INH with an enhanced analytical signal (voltammetric peak) over that achievab

224 Interaction isotherms were derived from analytical signals of immunosensor.

225 utorial review presents and extends a simple analytical simulation method that allows us to accuratel

226 rkforce of tomorrow requires new emphases on analytical skills.

227 The model combines an analytical solution of upward flux from groundwater with

228 hboring tetrahedral interstitial sites, with analytical solutions for basin exiting time and probabil

229 coeluting isobaric species across the entire analytical space.

230 migration limits cannot be enforced because analytical standards are unavailable.

231 Syntheses of analytical standards, including deuterium-labeled intern

232 level of information obtained from a single analytical step.

233 nt Center (SDMC), the LC has developed novel analytical strategies that integrate microbiologic and g

234 The robustness of the analytical strategy due to the reproducibility of the gu

235 We present an analytical strategy, dimethylation-deuteration and oxyge

236 Analytical studies should be carried out to distinguish

237 The analytical system is based on the oxidation of cysteine

238 A semi-automated dithiothreitol (DTT) analytical system was used to measure daily average OP (

239 oscopy has evolved into a cross-disciplinary analytical technique by unveiling relevant chemical, bio

240 esolved neutron imaging is a very attractive analytical technique in cases where other conventional n

241 An analytical technique operating at the nanoscale must be

242 The developed analytical technique resulted in quantitative extraction

243 rface enhanced Raman scattering (SERS) is an analytical technique which has gained a great deal of in

244 lity (IM) is now a well-established and fast analytical technique.

245 as characterized using a combination of bulk analytical techniques and high resolution transmission e

246 time-of-flight mass cytometry requires novel analytical techniques because the application of convent

247 Advanced analytical techniques currently used for characterizatio

248 ed Raman spectroscopy (TERS) have emerged as analytical techniques for characterizing molecular syste

249 ocedures and also instrumental conditions of analytical techniques for determination of organic and i

250 y defined biochemical features, and emerging analytical techniques have shed light on nuanced and con

251 We also apply common data collection and analytical techniques in the field and evaluate their ab

252 ll inhibited by limitations of the different analytical techniques such as high sample needs, offline

253 it is crucial to overcome the lack of robust analytical techniques that continue to hinder the purifi

254 this Review, we consider the biological and analytical techniques that could facilitate a precision

255 ed to develop robust, rapid, and nontargeted analytical techniques to determine the identity of the p

256 This study utilises analytical techniques to provide a comprehensive metabol

257 loped and compared by applying two different analytical techniques.

258 time monitoring of the process using process analytical technology (PAT) enabled stable and scalable

259 Analytical TEM allowed assessing the homogeneous localiz

260 ical technologies, detection sensitivity and analytical throughput have delivered a significant expan

261 This system also functions at varying analytical throughputs from 24 to 1200 samples per day t

262 tron emission tomography (PET) is a powerful analytical tool for in vivo molecular imaging of the hum

263 metry (LC-MS/MS) has proven to be a powerful analytical tool for the characterization of modified rib

264 reaks of hepatotoxicity-related drugs, a new analytical tool for the continuously determination of th

265 value of this new MALDI-TOF MS method as an analytical tool for the identification of gum arabic in

266 ge, the GSE-based approach offers a powerful analytical tool for the rapidly progressing mid- and lon

267 d enable the deployment of CV-PAS SECM as an analytical tool for traditionally challenging conditions

268 nance Raman spectroscopy is introduced as an analytical tool for ultrasensitive analysis of antibioti

269 d be used as a noninvasive, highly sensitive analytical tool to quantitatively track and visualize NP

270 thermochemolysis is shown to be an excellent analytical tool to simultaneously identify and optionall

271 0.12 ppm) are some of the key merits of this analytical tool.

272 New analytical tools are needed to fill the void for detecti

273 Current analytical tools are obsolete when it comes to handling

274 However, few analytical tools exist to identify which host species ar

275 emissions, dominant fate processes, types of analytical tools required for characterization and monit

276 Developing new analytical tools to detect these patterns in digital soc

277 many established assays, they do not support analytical tools with customized liquid holding geometri

278 We then combined these analytical tools with in vivo models of osteotomy healin

279 these sequences with associated metadata and analytical tools.

280 emission and prevent viral rebound following analytical treatment interruption (ATI).

281 MS), Transmission Electron Microscopy (TEM), Analytical Ultracentrifugation (AUC), and UV/Vis spectro

282 or hardware and software for multiwavelength analytical ultracentrifugation (MWL-AUC) experiments, de

283 Analytical ultracentrifugation analysis reveals that the

284 Previously, analytical ultracentrifugation was utilized to demonstra

285 Sedimentation velocity analytical ultracentrifugation with fluorescence detecti

286 l, hydrodynamic and structural studies using analytical ultracentrifugation, NMR, and small-angle x-r

287 ermined by size-exclusion chromatography and analytical ultracentrifugation, whereas other class III

288 stent with those from solution studies using analytical ultracentrifugation.

289 fluorescence-detected sedimentation velocity analytical ultracentrifugation.

290 hort-column sedimentation equilibrium in the analytical ultracentrifuge and model-independent SEDFIT-

291 In this article, we refine the analytical uncertainty analysis by a more precise, secon

292 the precision of the first- and second-order analytical uncertainty approaches by comparing analytica

293 Our model enables an analytical understanding of how Red Queen dynamics emerg

294 The analytical utility was further assessed by the selective

295 alytical uncertainty approaches by comparing analytical variances to variances from statistical Monte

296 ce computing, have significantly widened our analytical window and have enabled increasingly sophisti

297 good agreement, but reveal that selection of analytical window can impact which binding sites are tit

298 ire laborious, time-consuming, and expensive analytical workflows.

299 on must precede broad range integration into analytical workflows.

300 dual-marker analysis can be used to define "analytical zones" in a manner which is then independent