ライフサイエンスコーパス: time resolution

1 ion monitoring of drugs of abuse with a high time resolution.

2 cuss various approaches for achieving better time resolution.

3 a molecular level with high sensitivity and time resolution.

4 ingle fluorescent proteins with up to 100-Hz time resolution.

5 ng energy and coherent size with femtosecond time resolution.

6 itored electrophysiologically at millisecond time resolution.

7 strains on the single-cell level with 20 min time resolution.

8 ecules are often faster than the measurement time resolution.

9 of the water and the protein with ultrafast time resolution.

10 ed by X-ray powder diffraction with a 100 fs time resolution.

11 (OA), has been investigated with femtosecond time resolution.

12 uration of nucleosome binding with subsecond time resolution.

13 etection of minute current signals with good time resolution.

14 ombining structure resolution with ultrafast time resolution.

15 X-ray absorption spectroscopy (XAS) with ms time resolution.

16 fluorescent sensor for P(i) with millisecond time resolution.

17 nated via bioluminescent signal spectral and time resolution.

18 -molecule activation events often limits the time resolution.

19 e analysis with live-cell microscopy at high time resolution.

20 ce up-conversion measurements with sub 50 fs time resolution.

21 lectron beam properties with few-femtosecond time resolution.

22 ration of individual cells) with millisecond time resolution.

23 med at the soma and axon with submillisecond time resolution.

24 ate and glutamine were measured with a 5 min time resolution.

25 particularly hampered by signal-to-noise and time resolution.

26 dynamics of proteins in solution with 100-ps time resolution.

27 ied at nanometer resolution with millisecond time resolution.

28 release with 5 ms/frame, or even 1 ms/frame, time resolution.

29 NARE-mediated fusion events with millisecond time resolution.

30 tic aequorin variants from one another using time resolution.

31 ible and IR probes and over seven decades of time resolution.

32 esses dynamical information with femtosecond time resolution.

33 erse glutamate transport with submillisecond time resolution.

34 chemical information in an X-Y plane at high time resolution.

35 ime scales to be studied with submillisecond time resolution.

36 rent locations within the particle with 30-s time resolution.

37 nanometer spatial precision, and millisecond time resolution.

38 2 actin molecules in muscle with millisecond time resolution.

39 cells was imaged electrochemically with high time resolution.

40 angles is approximately 10 degrees at 40 ms time resolution.

41 technique with a microsecond to millisecond time resolution.

42 in an optical trap were recorded with 30-ms time resolution.

43 apted to the time domain with sub-picosecond time resolution.

44 central equatorial Pacific at sub-millennial time resolution.

45 rganosulfates in the particle phase at 1 min time resolution.

46 ontinuous acquisition for up to 3 min at 2-s time resolution.

47 uisition system (musDAQ) that provided 5 mus time resolution.

48 onized structural changes of DNA at a sub-ms time resolution.

49 nd the composition of emissions at an hourly time resolution.

50 r protein sequence reconstruction, with deep time resolution.

51 MglA and gliding motors in high spatial and time resolution.

52 elementary steps of fusion with millisecond time resolution.

53 lt-born dentate granule cells with excellent time resolution.

54 riod (2000-2006) with results saved at daily time resolution.

55 micrometer spatial resolution and subsecond time resolution.

56 iffusion rates of molecules with millisecond time resolution.

57 oot of the object size divided by the system timing resolution.

58 on future TOF PET/MR scanners with improved timing resolution.

59 instrument is field-deployable, and its high time resolution (0.5 Hz has been demonstrated) makes it

60 nnels were measured simultaneously at a high time resolution (~1 s) using two identical CRDS systems

61 ction dynamic of 95 ion traces in real time (time resolution = 1 s) during espresso coffee preparatio

62 Fast time resolution (10 Hz) NO and NO2 concentrations were m

63 eal-time PK curves with a hitherto unmatched time resolution (10 s), and none of the animals has to b

64 uisition (musDAQ) system that features 5 mus time resolution (100% duty cycle) to separate and quanti

65 The increased time resolution (13 s per image) allows the characteriza

66 s reporting data in near-real time at a high-time resolution, (2) increased computational and visuali

67 High time-resolution (30 min) PM2.5 sampling was conducted fo

68 ly absorbing transient within the instrument time resolution (300 fs), which is assigned to an excite

69 hase transitions, with millisecond or longer time resolution, account for processes occurring at surf

70 y of characterizing IVOC emissions with high time resolution across realistic engine operating condit

71 We present high time resolution airborne ethane (C2H6) and methane (CH4)

72 We exploit the sub-picosecond time resolution along with spectral resolution provided

73 transient absorption microscopy with 200 fs time resolution and 50 nm spatial precision.

74 nversion spectrophotofluorometer with 150 fs time resolution and a time-correlated single photon coun

75 oral development of the oligomers with 5-min time resolution and also demonstrate that there are cert

76 orption microscopy with approximately 200 fs time resolution and approximately 50 nm spatial precisio

77 carrier density with simultaneous ultrafast time resolution and approximately 50-nm spatial precisio

78 sient absorption spectroscopy with sub-20 fs time resolution and broad spectral coverage to directly

79 tween biomolecules in solution, offering new time resolution and control of the reaction processes.

80 b-30 kD protein molecules with unprecedented time resolution and detection efficiency.

81 decade, opening new windows into speciation, time resolution and detection of reactive and semivolati

82 ently, experimental techniques with adequate time resolution and elemental sensitivity to measure ini

83 Microfluidic mixing with microsecond time resolution and Forster resonance energy transfer de

84 icroscopy settings with high sensitivity and time resolution and it demonstrates the usefulness of io

85 ric compounds by MS/MS analysis, with better time resolution and minimal sample handling, compared to

86 ulture conditions over days with millisecond time resolution and picogram mass sensitivity.

87 covery MI, including 375 ps FWHM coincidence time resolution and sensitivity of 14 cps/kBq.

88 microscope in many 200-microm spots with 1-s time resolution and sensitivity to <1 pg of protein.

89 nnot be resolved directly due to the limited time resolution and sensitivity, but our study suggests

90 ecular recognition events, yet achieving the time resolution and statistics needed to realize this po

91 IR spectroscopy, which offers subpicosecond time resolution and structural sensitivity to distinguis

92 merize on blue-light exposure with subsecond time resolution and subcellular spatial resolution.

93 stigation of enzyme kinetics, including high time resolution and the ability to probe extremely large

94 r limit is a combination of the instrumental time resolution and the dissociation time of a ligand an

95 techniques with a millisecond-to-microsecond time resolution and the wild-type and mutated receptors

96 se distorted peak shapes, and result in poor time resolution and/or phase problems.

97 ble with the demands imposed by the quality, time-resolution and quantity of the data.

98 cceptable performance in terms of energy and timing resolution and crystal identification.

99 th near-atomic spatial resolution and 150-ps time resolution, and have used this capability to track

100 rial cell with high specificity, millisecond time resolution, and nanometer spatial precision.

101 This technique suffers from low time resolution, and often, an inability to distinguish

102 nt can be controlled via laser polarization, time resolution, and tomographic tilting.

103 HPLC profiles were compared for retention time, resolution, and peak heights.

104 e measurement technique, which offers a high time resolution ( approximately 1 ms) to resolve the fis

105 with a rise time shorter than the instrument time resolution ( approximately 170 fs).

106 Criteria for achieving microsecond time resolution are described and modeled.

107 t nearly the speed of light in plasma with a time resolution as small as a few femtoseconds is propos

108 pproximately 50 nm in the axial direction at time resolutions as fast as 1-2 s with several independe

109 ed 4D EM to include liquid cells without the time resolution being limited by the response of the det

110 ls atomic scale processes with unprecedented time resolution bringing the so called "molecular movie"

111 eving not only sufficient simultaneous space-time resolution but also brightness for sufficient image

112 submillisecond mixer used here improves the time resolution by a factor of 50 compared to earlier .O

113 ng kinetics to be monitored with millisecond time resolution by time-resolving changes in the label f

114 Although faster time resolution can be achieved by fluorescence-correlat

115 X-ray total scattering, used with subsecond time resolution, can yield detailed, valuable insights i

116 of magnitude, marring the otherwise precise time-resolution capabilities of this class of instrument

117 were designed to characterize its intrinsic timing resolution capability, which defines its TOF perf

118 The timing resolution changes as a function of the singles r

119 o study the effect of temperature on elution time, resolution, column efficiency, and selectivity.

120 fast force spectrometer with sub-millisecond time resolution, combined with Brownian and Molecular Dy

121 d by both conventional stopped-flow and high-time-resolution continuous-flow fluorescence measurement

122 e continuous, real-time (approximately 1 min time resolution) detection of the small-molecule drug co

123 Measurements with millisecond time resolution directly demonstrate that substrate poly

124 These advances allow us to reach limits of time resolution down to regimes of a few femtoseconds an

125 ents into a single and robust technique with time resolution down to the ns scale, opening a new door

126 tors achieving single-photon sensitivity and time resolutions down to the picosecond range, thermoele

127 ses and particles continuously and with fast time resolution during field campaigns.

128 en alga Chlamydomonas reinhardtii using high-time-resolution electron paramagnetic resonance (EPR) at

129 protein degradation rates, measured in high time resolution, feature a sharp clock-regulated peak un

130 lly observed between ambient species in high time resolution fine particulate matter (PM2.5) data to

131 ic resonance (MR) imaging sequence with dual time resolution for 25 minutes.

132 sion is <30 pptv at 1 s and <4 pptv at 1 min time resolution for all measurement channels.

133 olve these nanoscale phenomena but lacks the time resolution for direct observation.

134 Detectors with sufficient time resolution for observing these processes are not av

135 that the device has adequate sensitivity and time resolution for real-time recordings.

136 The time resolution for serial synchrotron crystallography e

137 microwave-assisted reactions do provide good time resolution for studying dynamic changes to Cu-bindi

138 d empirical methods to enhance the depth and time resolution for the relevant polymorphisms and novel

139 for techniques with improved sensitivity and time resolution for use in exploring biomolecular system

140 with substantially enhanced sensitivity and time resolution for various situations where traditional

141 data quality via an improved combination of time resolution, force precision, and force stability wi

142 lagmite delta(18)O record with multi-decadal time resolution from the temperate Korean Peninsula (KP)

143 of spiking, beyond that encoded by rate, at time resolutions from 1-40 msec.

144 can provide continuous measurements at high time resolution, giving new insight into N2O sources, si

145 d (FTIR) difference spectroscopy, with 5 mus time resolution, has been used to produce P700(+)A(1)(-)

146 These include submicrosecond time-resolution, high sensitivity (baseline noise on the

147 We have measured with 3-min time resolution how heritable patterns of chromatin stru

148 rimentally, and results corresponding to 2.4 times resolution improvement are presented.

149 dividual diesel trucks were measured at high time resolution in a highway tunnel in Oakland, CA, duri

150 bmicrometer spatial resolution and subsecond time resolution in a live cell or organism.

151 can measure pH fluctuations with sufficient time resolution in freely moving animals.

152 larger (40 nm) Au labels, not only push the time resolution in long-time, continuous fluorescence-ba

153 tect CME of single vesicles in a millisecond time resolution in mouse chromaffin cells.

154 on of time varying flows at high spatial and time resolution in small animal models.

155 in-type pseudoknot obtained with microsecond time-resolution in response to a laser temperature-jump

156 s with 10 orders of magnitude improvement in time resolution, in convergent-beam ultrafast electron m

157 d) makes it well-suited for studies in which time resolution is critical, such as aircraft studies.

158 ts based on the Hadamard transform, in which time resolution is defined by the underlying periodicity

159 r measuring them quickly in situations where time resolution is important.

160 s high elemental sensitivity; however, their time resolution is inadequate to characterize rapid envi

161 ed to current trap experiments, in which the time resolution is insufficient to detect pre-rigor stat

162 The timing resolution is also stable over a long duration, i

163 tal challenges in achieving high spatial and time resolution, it is not yet known whether or not TF a

164 The control over bilayer environment and time resolution makes this method a powerful assay for e

165 Multiple high-time-resolution mass spectrometry organic aerosol measur

166 In addition, high time resolution measurements of single-particle mixing s

167 evolution of OA that is constrained by high-time-resolution measurements of its composition, volatil

168 e photoconductance, using simultaneous, high time-resolution measurements of membrane current and Ca(

169 Using measurements with very high time resolution, NASA's Magnetospheric Multiscale (MMS)

170 Although high-time-resolution observations are often possible in radio

171 The method has a time resolution of <1 s and sensitivity to osmotic chang

172 els to examine dynamic chemical events (to a time resolution of <10 ms).

173 es) of bound protein in each array spot at a time resolution of 1 s.

174 of spinning-disc confocal microscopy with a time resolution of 10 ms.

175 cells with single-molecule sensitivity and a time resolution of 100 ms.

176 sheet to alpha-helix could be monitored at a time resolution of 15 s per spectrum.

177 ntermediate even at the earliest times, at a time resolution of 16 ms.

178 species can be tracked with an unparalleled time resolution of 2 min during day-night cycles.

179 ensitive to achieve acquisition rates with a time resolution of 2.5 micros (equivalent to 400,000 fps

180 Our dwell-time resolution of 2.5 mus enables translocation time di

181 A time resolution of 200 ms was applied.

182 s the X frequency band (8 GHz-12 GHz), and a time resolution of 200 ps (6 cm optical path in free spa

183 The ultrafast time resolution of 2D IR spectroscopy provides an instan

184 proteins by acquiring sequential images with time resolution of 3 s during stimulation of RBL-2H3 mas

185 microtubule dynamics in living cells with a time resolution of 3 s.

186 Ia observed during the Kepler mission with a time resolution of 30 minutes.

187 wth of gold nano- and microstructures with a time resolution of 5 ms.

188 the time that each photon is detected with a time resolution of 50 ns using a low-cost counting board

189 fMRI, this is necessitated by the fact that time resolution of a BOLD signal much lower than that of

190 Due to the high time resolution of about 2.5 h intensity correlations of

191 pid changes with time can be recorded with a time resolution of approximately 1 s.

192 ments using a capillary mixing system with a time resolution of approximately 100 micros.

193 oncentration (R(2) from 0.86 to 0.97) with a time resolution of approximately 3 min.

194 ng a laser-pulse photolysis technique with a time resolution of approximately 60 mus, we measured the

195 ated ion channels control the submillisecond time resolution of binaural coincidence detection, but l

196 of a few tens of microliters, with a kinetic time resolution of ca. 1 s.

197 Here, we report that the time resolution of commercial instruments is on the orde

198 This device allows us to improve the time resolution of ex situ aggregation assays relative t

199 ed stopped-flow techniques that have limited time resolution of few milliseconds.

200 The reported femtosecond time resolution of four-dimensional (4D) electron micros

201 using a quadrupole mass spectrometer with a time resolution of less, similar1 min.

202 Within the time resolution of our experiments, this static kink occ

203 on-dissociation events that occur within the time resolution of our setup as well as FRET-fluctuation

204 es, reducing phototoxicity and improving the time resolution of particle tracking in live cells.

205 Here, we exploited the high time resolution of patch-clamp recordings to examine the

206 high sensitivity, elemental specificity, and time resolution of Q-XAS, it has many potential applicat

207 de incorporation and GFP-PCNA gave exquisite time resolution of S phase events.

208 We demonstrate here that the technique has a time resolution of seconds and is capable of making stab

209 coated vesicles (CCVs) at single CCPs with a time resolution of seconds.

210 anging from 3.2 to 25.0 mug m(-3) and with a time resolution of several minutes.

211 utocorrelation force spectroscopy pushes the time resolution of single-molecule force spectroscopy to

212 The time resolution of spectral acquisition is short enough

213 ual synaptic responses, and we show that the time resolution of synaptic coincidence detection can be

214 e-dependent manner and actively improved the time resolution of synaptic integration.

215 In this work, we have improved the time resolution of tdelay control up to ca. 1 mus, enhan

216 By overcoming the coarse time resolution of the array, our framework uniquely ach

217 Furthermore, the time resolution of the assay reveals a number of distinc

218 the cues often changes as a function of the time resolution of the code, implying that information a

219 cates the modeling process, as it limits the time resolution of the data.

220 re under force is much faster, improving the time resolution of the discrimination process.

221 The frame rate of the camera limits the time resolution of the experiment and thus the fastest r

222 The time resolution of the folding reaction was enhanced wit

223 To overcome the low time resolution of the imaging frames needed to collect

224 To improve the time resolution of the inherently brief alpha7 channel o

225 pper limit of quantification, defined by the time resolution of the measurement.

226 rces and detector technology are pushing the time resolution of the method to ever shorter periods, c

227 While some of these bulk assays provide time resolution of the order of 1min, they do not captur

228 istribution of the positron activity and the time resolution of the PET scanner.

229 rturbation of specific cellular pathways and time resolution of the TCRP approach can serve as a comp

230 to 1.8, which is consistent with the 590-ps time resolution of the TOF PET scanner.

231 The ultimate time resolution of these devices can be restricted by pr

232 The time resolution of these measurements was extended to 2.

233 e scan and a dynamic hepatobiliary scan with time resolutions of 60 s and 15 s, respectively.

234 -electron lasers require pulse durations and time resolutions of only a few femtoseconds.

235 The time-resolution of 0.2 ms revealed initial collapse of t

236 of this spiro-system within the experimental time-resolution of 270 fs.

237 Utilizing the nearly instantaneous time-resolution of 2D IR spectroscopy, parallel and anti

238 tetium-yttrium oxyorthosilicate and a system timing resolution of approximately 600 ps.

239 In addition, we measured the energy and timing resolution of both of the crystal layers (cerium-

240 n-echo (HeSE) technique achieves spatial and time resolution on the nm and ps scale, respectively, th

241 ingle cells during hyperosmotic shock with a time resolution on the order of seconds to examine the r

242 s/cm(3) and 100 ng/m(3), respectively, and a time resolution on the order of seconds.

243 Existing techniques lack adequate time resolution or require potentially toxic exogenous r

244 g (AuRBT), which yields >100x improvement in time resolution over previous techniques.

245 67P/Churyumov-Gerasimenko with well-sampled time resolution per rotation.

246 Femtosecond time resolution permits direct observation of the fast i

247 ture and morphology, achieved with sub-20 fs time resolution pump-probe spectroscopy.

248 nly known repeating burst source, using high-time-resolution radio interferometric observations that

249 lved .OH footprinting capable of millisecond time resolution readily applicable to DNA and RNA.

250 in physiological conditions at the mass and time resolutions required to observe fast cellular dynam

251 The high time-resolution results in spatially and time resolved i

252 ns from single hybridoma cells, the enhanced time resolution revealed two modes of secretion: one in

253 released as a function of time, with 50 mus time resolution, revealing biophysical characteristics o

254 gle X-ray scattering (SAXS) with millisecond time-resolution reveals two discrete phases of global co

255 ave been developed that show improvements in time resolution, sensitivity, and accuracy.

256 enesis pathways to methane production with a time resolution shorter than one minute.

257 Distances computed at differing time resolutions show significant information in the tem

258 tion dispersion during transport with a 30 s time resolution showed that the dispersion standard devi

259 High spatial and time resolution single-molecule fluorescence resonance e

260 is electrochemical camera provides very high time resolution, spatiotemporal localization of individu

261 A fine time resolution spectral analysis shows power-law decays

262 Greater time resolution techniques will be required to detect th

263 ch faster than previously estimated with low time-resolution techniques.

264 measurement technique that provides a higher time resolution than imaging techniques.

265 Low Frequency Array, an instrument with high-time resolution that also permits imaging at scales much

266 absorption spectra obtained with picosecond time resolution that the nascent HCN products of reactio

267 the detection of single cell secretions have time resolutions that range from hours to days, and as a

268 ture prospect of significant improvements in timing resolution that could lead to further effective s

269 ortical inputs to the BG to study, with fine time resolution, the functional connectivity within this

270 jump apparatus to probe, with submillisecond time resolution, the kinetics of bending/unbending of a

271 visible and infrared regions with nanosecond time resolution, the latter being accomplished using tun

272 These limitations place constraints on the time resolution, the signal-to-noise ratio, and the tota

273 With a 40-ms time resolution, the spatial distribution exhibits two o

274 ight sources, which can be studied with high time resolution, thus providing access to picosecond dyn

275 between F subunits a and c by improving the time resolution to 10 mus at unprecedented S/N, and by u

276 However, these studies did not have adequate time resolution to define precisely the disassembly kine

277 sembly in its native environment, with ample time resolution to extract kinetic rates and observe int

278 ubtilis (B. subtilis) are measured with 4 ms time resolution to investigate the behavior of individua

279 ed electrophysiological techniques with high time-resolution to directly investigate the mechanistic

280 entional PET scanner as well as provide good timing resolution to operate as a time-of-flight (TOF) P

281 With 20 ns time resolution, transient absorption measurements revea

282 ies of biological reactions with millisecond time resolution under conditions of macromolecular crowd

283 into larger FCC crystals, captured at 2.5 ms time resolution using a fast electron camera.

284 oplasmic pH of E. coli was measured with 4-s time resolution using a method that can be applied to an

285 i cells in suspension were observed with 4-s time resolution using fluorimetry of TorA-green fluoresc

286 l glucose metabolism in vivo with sub-second time resolution using hyperpolarized (13)C MRS.

287 was carried out for more than 16 h at 1 min time resolution using microdialysis coupled online to a

288 was 9.40% FWHM, and the average coincidence time resolution was 375.4 ps FWHM.

289 The coincidence timing resolution was 1.42-ns full width at half maximum

290 The system coincidence timing resolution was measured to be 585 ps.

291 acitance measurements that offer millisecond time resolution, we demonstrate that the dynamics of ves

292 otolysis technique that provides microsecond time resolution, we investigated the channel-opening kin

293 raphy to measure neural activity with a high time resolution, we show that such episodic retrieval en

294 Utilizing this time-resolution, we then developed a simultaneous, dual-

295 Energy resolution and coincidence time resolution were measured.

296 on cross section (M.A.C., m(2)/g) with 1 min time resolution when soot concentrations were in the low

297 paringly stained boutons were imaged at high time resolution, while high-frequency electrical stimula

298 four dimensional (4D) PAT, which integrates time resolutions with 3D spatial resolution, obtained us

299 ography by integrating the fourth dimension (time resolution) with the 3D spatial resolution obtained

300 e use stopped-flow fluorescence (millisecond time resolution) with three fluorescent probes to monito

301 megabecquerel amounts of tracer or subsecond time resolution would enable a wide range of new imaging