ライフサイエンスコーパス: instrumentation

1 eign-body infections (arthroplasty or spinal instrumentation).

2 me consuming and require the use of advanced instrumentation.

3 ss laboratories with distinct chromatography instrumentation.

4 ion microscopy in whole cells using standard instrumentation.

5 neous electron transfer kinetics with simple instrumentation.

6 e and easily miniaturized and cost-effective instrumentation.

7 e required conversion to 20, 23, or 25 gauge instrumentation.

8 by minimizing the reliance on large hardware instrumentation.

9 highlighted the need for reliable analytical instrumentation.

10 plementing reliable DFOSS-based geotechnical instrumentation.

11 d pleural effusion attributed to pericardial instrumentation.

12 fluid samples without complex and expensive instrumentation.

13 e high value addition to existing analytical instrumentation.

14 l violet (LCV) dye by eye without a need for instrumentation.

15 high-performance microscopes through better instrumentation.

16 emented that allow miniaturized and portable instrumentation.

17 ent remains a major challenge for analytical instrumentation.

18 lenging and requires sophisticated and bulky instrumentation.

19 itive assay using the same mass spectrometry instrumentation.

20 wer and easy miniaturization of the required instrumentation.

21 ethodology that requires minimal specialized instrumentation.

22 thout the use of sophisticated and expensive instrumentation.

23 ithout the requirement of high mass accuracy instrumentation.

24 signed in-house and printed by Pine Research Instrumentation.

25 cause of the slow time response of available instrumentation.

26 ues require expensive and complex analytical instrumentation.

27 le of detecting of 0.1 nM target DNA without instrumentation.

28 he reported impedance values of the benchtop instrumentation.

29 ce, which could operate without any external instrumentation.

30 care, overcoming the shortcomings of current instrumentation.

31 constitute a good alternative to mechanical instrumentation.

32 itive detection, long coherences, and simple instrumentation.

33 rt catheterization with pressure-conductance instrumentation.

34 to that obtained with traditional bench-top instrumentation.

35 high temporal resolution without additional instrumentation.

36 ample and reagent consumption by inexpensive instrumentation.

37 eliminating the need for advanced expensive instrumentation.

38 pensive, stable chemical reagents and simple instrumentation.

39 gh speed with minimal sample preparation and instrumentation.

40 reported so far due to the lack of suitable instrumentation.

41 roducible manner, independent of utilized MS instrumentation.

42 paration procedures or complex and expensive instrumentation.

43 ed to formulation, process, environment, and instrumentation.

44 ioactivity or fluorescence and require bulky instrumentation.

45 chromatography and mass spectrometry (GC-MS) instrumentation.

46 ence of powerful biochemical and biophysical instrumentation.

47 es equipped with state-of-the-art analytical instrumentation.

48 properties of the newly introduced combined instrumentation.

49 ing data from the multiplex bead array assay instrumentation.

50 adily apparent with current clinical imaging instrumentation.

51 tch, without requiring complex and expensive instrumentation.

52 on label-free LSPR shift without complicated instrumentation.

53 using traditional capillary electrophoresis instrumentation.

54 l demonstrate permit analysis using portable instrumentation.

55 py method, which relies on remarkably simple instrumentation.

56 e evaluated its performance for a simplified instrumentation.

57 data can be collected using high-throughput instrumentation.

58 ls but has required very large and expensive instrumentation.

59 case required conversion to 23- or 25-gauge instrumentation.

60 d Doppler lidar now provides virtually ideal instrumentation.

61 chieved through modification of the existing instrumentation.

62 ing that which can be achieved with benchtop instrumentation.

63 lable, and low-cost with no need for complex instrumentation.

64 ring, medical imaging, aerospace and nuclear instrumentation.

65 ple preparation, and/or the need for complex instrumentation.

66 n ions leaching from glass components of the instrumentation.

67 visual detection of E. coli O157:H7 without instrumentation.

68 use of recently developed, state-of-the-art instrumentation.

69 s and reproducibility comparable to standard instrumentation.

70 rsatility requiring complex, non automatized instrumentations.

71 periment using conventional quantitative PCR instrumentation, 19,400 conditions of MgCl2, ligand and

72 one); (2) compare and contrast approaches to instrumentation; (3) describe prevalence and patterns; (

73 LC x LC and of 5 times with respect to HPLC instrumentation (40 compared with 80 and 200 min, respec

74 of more comprehensive analytical methods and instrumentation able to deal with a more diverse range o

75 re a robust approach for sample preparation, instrumentation, acquisition parameters and data process

76 ing, is rapidly increasing as technology and instrumentation advances.

77 different toxins was carried out using HPLC instrumentation after pre-separation using immunoaffinit

78 us arterial BP (Finapres; TNO-TPD Biomedical Instrumentation, Amsterdam, the Netherlands) and high-re

79 ions without using sophisticated analytical instrumentation and a tedious sample preparation method

80 can potentially reduce the complexity of the instrumentation and allow the development of user-friend

81 in situ photo-oxidation that combines simple instrumentation and ambient gases (O2 and H2O) as a func

82 We used confocal and lattice light sheet instrumentation and an imaging informatics pipeline of f

83 five (or seven to nine if using complicated instrumentation and analysis).

84 With ongoing improvements in instrumentation and analytical procedures, proteomics ma

85 The development of novel devices, instrumentation and approaches facilitates this endeavor

86 niques are time-consuming, require expensive instrumentation and are labour-intensive.

87 Over the years, sensitive instrumentation and better techniques for producing thes

88 completely independent from the rest of the instrumentation and can be adapted to any gas chromatogr

89 When operating under these conditions, both instrumentation and column packing must be modified or o

90 Improvements in mass spectrometry instrumentation and computation and in protein biochemis

91 Recent developments in Raman spectroscopy instrumentation and data processing algorithms have led

92 w, the authors discuss the basic principles, instrumentation and design, examples of current clinical

93 speed, potential for miniaturization, simple instrumentation and easy automatization.

94 single protein per slide or require complex instrumentation and expertise while only staining isolat

95 under extreme conditions, and introduces the instrumentation and facilities that enable single crysta

96 ytical techniques that require sophisticated instrumentation and highly trained personnel.

97 onally difficult to interrogate, advances in instrumentation and imaging methods are providing new in

98 explained, in part, by advances in surgical instrumentation and imaging methods to detect retinal di

99 graphy (HSGC) method which requires modified instrumentation and ionic liquid stationary phases was d

100 Because CycIF uses standard reagents and instrumentation and is no more expensive than convention

101 detection of heavy metals require expensive instrumentation and laborious operation, which can only

102 The recent developments in MAS NMR instrumentation and methodologies opened new vistas to a

103 Recent advances in instrumentation and methodology have expanded the utilit

104 reased the demand for portable bioanalytical instrumentation and point-of-care.

105 integrated circuits for sensing, biomedical instrumentation and quantum communication.

106 General instrumentation and recent developments to achieve two-

107 esearch and can be performed using different instrumentation and sample preparation methods, each one

108 rapidly increasing on account of advances in instrumentation and sample-processing protocols.

109 New instrumentation and software are propelling these multip

110 well as the technical improvements involving instrumentation and spectral acquisition demand increasi

111 though DMEK is more challenging, advances in instrumentation and techniques are reducing the learning

112 Recent advances in mass spectrometry instrumentation and techniques have facilitated analysis

113 With the development of modern instrumentation and technologies, mass spectrometry base

114 has been made in recent years to develop NMR instrumentation and technology to allow the acquisition

115 e-scale test validation and the build-out of instrumentation and tests kits for POC deployment.

116 implemented with existing mercury speciation instrumentation and this would improve our knowledge of

117 depend on the performance of the analytical instrumentation and would drastically benefit from impro

118 asy-to-manufacture, do not require expensive instrumentation, and allow creation of lower micron-size

119 nsive sample preparation, highly specialised instrumentation, and are time consuming.

120 om recent advances in separation techniques, instrumentation, and bioinformatics.

121 Next, we outline techniques, instrumentation, and cell designs involved in scaling up

122 ideration of fluorescent indicators, optical instrumentation, and computational analyses.

123 cal separation techniques, mass spectrometry instrumentation, and data processing platforms continue

124 , status of lens, status of cornea, gauge of instrumentation, and history of prior vitrectomy did not

125 etection or the use of prohibitively complex instrumentation, and prospects for the use of protein en

126 cements in integrative systems, OCT-friendly instrumentation, and software algorithms will further ex

127 riate technical competency, fully functional instrumentation, and suitable reagents to perform accura

128 r method does not require highly specialized instrumentation, and thus can be adapted for use in almo

129 ality control of ddPCR systems, consumables, instrumentation, and workflow.

130 e, it would take a person skilled in optical instrumentation approximately 1 month to assemble and op

131 Shortcomings of existing instrumentation are also noted.

132 ability, and the requirement for specialized instrumentation are among the various reasons for delaye

133 These techniques and associated instrumentation are at an early stage of technical devel

134 y, the multiple roles op amps play in modern instrumentation are described along with a number of exa

135 o improve patient care, but the reagents and instrumentation are expensive.

136 ology, metabolic engineering, and analytical instrumentation are improving the production, manipulati

137 Technological advances in cytometry instrumentation are increasing the size and dimensionali

138 umes and lack of complex and highly specific instrumentation, as well as positive control and reusabi

139 The electronic revolution in analytical instrumentation began when we first exceeded the two-dig

140 samples in six laboratories using different instrumentation but a common protocol (the AbsoluteIDQ p

141 the past, the variations were attributed to instrumentation, but high performance SFC systems have s

142 enzyme-carbon composite pellets, and sensor instrumentation circuits.

143 ration of genomic data with high-tech animal instrumentation comes as a natural progression of tradit

144 We describe the sensor and its associated instrumentation, compare the performance of several type

145 With the advances in instrumentation, computational and mathematical techniqu

146 more applications due to the advancement in instrumentation, computing power and multivariate data a

147 This review presents the various instrumentation considerations relevant to the clinical

148 The underlying instrumentation consists of a 2D stage with an additiona

149 The instrumentation consists of one particle-into-liquid sam

150 y, resolution and dynamic range of modern MS instrumentation continue to improve at an ever accelerat

151 rizes the current state of the art in PET/MR instrumentation, correction techniques, and data analysi

152 onnection to a computer was required and the instrumentation cost orders of magnitude less than that

153 rapidly emerging field with new advances in instrumentation, data acquisition and data analysis.

154 ecently a microfabricated device with modest instrumentation demonstrated all-optical hyperpolarizati

155 measurement biases introduced by measurement instrumentation detecting only certain isotopologues.

156 Automated goniometer-based instrumentation developed for use at the Linac Coherent

157 Hardware and software modifications during instrumentation development can dramatically affect the

158 sights which have been central to analytical instrumentation development, improvement, and utilizatio

159 Root surfaces experience continuous abrasive instrumentation during lifelong periodontal maintenance.

160 rapid response, and do not require external instrumentation during operation.

161 f mycotoxins normally requires sophisticated instrumentation, e.g. liquid chromatography with fluores

162 or portable analysis because battery-powered instrumentation (electronic micropipette and potentiosta

163 latform along with anatomically-miniaturized instrumentation electronics featuring a potentiostat, mi

164 me samples by standard diagnostic laboratory instrumentation employing commercial kits.

165 processors eliminates potentially cumbersome instrumentation engineering challenges and is compatible

166 of imaging methods that require specialized instrumentation, exotic reagents or proprietary protocol

167 Novel computer-controlled instrumentation facilitates the collection of very large

168 ive synthesis, high selectivity, inexpensive instrumentation, fast signal transduction, and low limit

169 their cavity round trip period, calling for instrumentation featuring both high temporal and spectra

170 odology with state of the art drug discovery instrumentation (FLIPR Tetra) and used selective tool co

171 aging is presented, including techniques and instrumentation, followed by a discussion of potential c

172 ion are not well-understood due to a lack of instrumentation for combined and real-time monitoring of

173 se microscopy, or bulky/expensive chemo-stat instrumentation for dynamic measurement and control of b

174 The available instrumentation for gasometric analysis is generally dif

175 However, the instrumentation for lifetime measurements is complex, ge

176 lar summit underwent percutaneous epicardial instrumentation for mapping and ablation because of unsu

177 Epicardial instrumentation for mapping and ablation of ventricular

178 wine (80.0 +/- 6.0 kg) underwent anesthesia, instrumentation for monitoring, and splenectomy.

179 nd modification of the software and hardware instrumentation for nanoscale SECM are explicitly explai

180 also demonstrate the use of hand-held Raman instrumentation for NRS and EC-SERS, showing that Raman

181 We describe novel instrumentation for potentiostatically controlled voltam

182 Instrumentation for probing this interface is limited.

183 Second, an overview about the instrumentation for spontaneous and coherent Raman scatt

184 However, instrumentation for the automated, real-time analysis of

185 nders; this necessitates robust and reliable instrumentation for the observation of unique and charac

186 In this review, instrumentation for the two in situ/operando techniques

187 Here, we employ standard qPCR instrumentation for thermofluorimetric analysis of bival

188 l range are highly desired to enable compact instrumentation for THz sensing and spectroscopy.

189 Improved instrumentation has advanced breath analysis for several

190 The technological development of LC-MS instrumentation has led to significant improvements of p

191 While mass spectrometry instrumentation has seen advancements in capabilities, d

192 systems and progresses in mass spectrometry instrumentation have enabled direct introduction of the

193 While advances in instrumentation have improved figures of merit, acquirin

194 Recent advances in X-ray instrumentation have made it possible to measure the spe

195 ventional state-of-the-art image acquisition instrumentation, here represented by the Typhoon 9400 in

196 several limitations, including sophisticated instrumentation, high reagent consumption, limited multi

197 New instrumentation imaged the smallest foveal cones, thus a

198 he unique Jonathan Amy Facility for Chemical Instrumentation in the Department of Chemistry at Purdue

199 The advances in mass spectrometry (MS) instrumentation in the past 2-3 decades have rendered MS

200 he vast amount of data produced by modern MS instrumentation in their quest to understand gene functi

201 Instrumentation included a sulfur dioxide monitor and an

202 The important ways that developments in instrumentation influenced the choices, possibilities, a

203 rofabricated photodiode array and electronic instrumentation into a hand-held unit.

204 ment) model that is validated by integrating instrumentation into the testing platform.

205 Recent advances in biological techniques and instrumentation involving nanomaterials, surface plasmon

206 ds predating direct observations with modern instrumentation is based on geological and archaeologica

207 cles and this problem is magnified when such instrumentation is coupled with ion trap mass spectromet

208 Although LAS instrumentation is easy to use, its incorporation into l

209 Instrumentation is one way to improve sensitivity by inc

210 monstrate that a reduction of the supporting instrumentation is possible without a significant decrea

211 e method can be implemented with appropriate instrumentation, is applicable to any biological system,

212 d low cost colorimetric method, requiring no instrumentation, is presented for the detection of fruct

213 se membranes can also be coupled to benchtop instrumentation it is reasonable to assume that detectio

214 point-of-care and at home with minimal or no instrumentation, it is necessary to streamline unit oper

215 mass cytometry, providing an overview of the instrumentation, its present capabilities, and methods o

216 ite analysis as it overcomes need of complex instrumentation, lengthy protocols and surface modificat

217 with real-time data from reaction monitoring instrumentation (like UV-vis, FTIR, Raman, and 2D NMR be

218 out the need for complex time-gated decoding instrumentation.Luminescent materials that are capable o

219 s sample details (e.g. species and tissues), instrumentation (mass spectrometer), keywords and other

220 With the use of hand-portable GC-TMS instrumentation, membranes cut with dimensions 40 mm lon

221 solid phase extraction together with various instrumentation methods including LC-MS, HPLC-UV and UV/

222 logy, refinements in surgical techniques and instrumentation, new imaging modalities, and the widespr

223 Low power and poor instrumentation of activity limited causal analysis of t

224 ing nature and/or the need for sophisticated instrumentation of those methods limit their on-site app

225 Recent development in instrumentation, optics and manufacturing approaches has

226 and quantitative readouts without expensive instrumentation or complicated data processing.

227 teps are all at room temperature, require no instrumentation or equipment, and can be carried out by

228 specimen manipulation without any dedicated instrumentation or specialized training by the operator

229 ea of a pure lipid bilayer given appropriate instrumentation or tens of counts from a minor constitue

230 their rollout, as access to state-of-the-art instrumentation or the need for years of hands-on experi

231 h standard bilamellar tarsal rotation (BLTR) instrumentation or the TT clamp and were followed up for

232 icient lipid removal without electrophoretic instrumentation (passive CLARITY) to optimized objective

233 Here we compared two MALDI-TOF MS instrumentation platforms and three databases: Bruker Bi

234 high sensitivity, selectivity, simplicity of instrumentation, portability, and low cost of the total

235 The instrumentation presented here has broad applications to

236 hout the need for electrophoretic or complex instrumentations, preservation of cytoarchitectural deta

237 polarizations and the need for sophisticated instrumentation render conventional nuclear magnetic res

238 icient mixing, aggregation, and the advanced instrumentation required for effective actuation.

239 n are urgently needed to develop the in situ instrumentation required to document this era of rapid o

240 lation can be effective but entails arterial instrumentation risk.

241 s, emphasizing the equally critical roles of instrumentation, sample preparation, and photophysics, a

242 Significant advances in instrumentation, sample preparation, spectroscopic techn

243 ication to fast ET kinetic study with simple instrumentation should be useful in studies of particle

244 le was also used to diagnose issues with IMS instrumentation such as intermittent losses of pixel dat

245 ons of recently introduced integrated PET/MR instrumentation, such as MR-based attenuation correction

246 The fluctuations were not due to the instrumentation system, or to any other of the known sou

247 ly the limiting portions of our computerized instrumentation systems.

248 The Teledyne Advanced Pollution Instrumentation (TAPI) model 602 Beta(Plus) particulate

249 In this review, we overview the instrumentation techniques commonly utilized for the cha

250 cy in the laboratory, and recent progress in instrumentation technology.

251 ted this calibrator with atmospheric mercury instrumentation (Tekran 2537/1130/1135 speciation system

252 because of continuous technical advances in instrumentation that are now enabling quantitative lipid

253 d extensional probes, which are monitored by instrumentation that combines magnetic tweezers with obj

254 ches, however, typically involve integrative instrumentation that necessarily must balance sensitivit

255 oom temperature and uses simple, inexpensive instrumentation that permits multiplexed analysis.

256 With the introduction of digital instrumentation that will enable larger reaction volumes

257 etic materials from cells, and sophisticated instrumentations that follow.

258 islice data sets and ongoing improvements in instrumentation, the ability to retain all pixels and ma

259 Despite recent advances in IM-MS instrumentation, the resolution of closely related prote

260 essengers and protein analytes with standard instrumentation, thereby simplifying workflows in studie

261 nexpensive option to conventional analytical instrumentation, they can be readily integrated into ele

262 With improved instrumentation, this capability scales to spaceborne ap

263 be easily obtained with modern computerized instrumentation, this is not the case for D and t(+).

264 ion without external standards and expensive instrumentation, this PCQ-PCR-LFNAB cascade method shows

265 ried out by the same operator using the same instrumentation, thus eliminating possible differences i

266 nted using the most basic and inexpensive MS instrumentation, thus providing an attractive alternativ

267 system incorporates a microfluidic chip and instrumentation to accomplish universal PCR amplificatio

268 With the availability of portable instrumentation to accurately detect biological warfare

269 low Earth orbit, a convergence in analytical instrumentation to analyze both air and water samples is

270 We validated the use of the new instrumentation to both coherent anti-Stokes scattering

271 l, has not been adequately met by rapid qPCR instrumentation to date.

272 Here, we use new isotopic instrumentation to determine ecosystem photosynthesis an

273 To assess the contribution of instrumentation to larger scale fluctuation scaling, we

274 This study compares instrumentation to measure tumor fluorescence.

275 sible platform without sophisticated optical instrumentation to realize label-free surface plasmon re

276 Advances in analytical instrumentation towards acquiring high-resolution images

277 on of analytical procedures across different instrumentation types promoting the adoption of MCC-IMS

278 es all possible uncertainties involved, from instrumentation up to data analysis into a single model

279 The simplicity of the instrumentation used and the low cost of each single dev

280 ity and selectivity, as the traditional HRMS instrumentation used for this analysis.

281 ould be developed further into point of care instrumentation useful in the diagnosis of various forms

282 four areas with identical diameter open for instrumentation using bicarbonate powder and glycine pow

283 he TBE virions determined after SEC by GEMMA instrumentation was 46.8 +/- 1.1 nm.

284 GEMMA instrumentation was also used for fractionation of virio

285 Additional support for instrumentation was obtained from the National Center fo

286 oroidial ion trap mass spectrometry (GC-TMS) instrumentation was shown to push detection limits for t

287 The new instrumentation was tested with molecular imprinted sens

288 ple, versatile, and does not require special instrumentation, we envision its broad application in a

289 Using recent advances in analytical instrumentation, we have developed a simple yet powerful

290 Studies began 3 months after instrumentation when wall thickening was reduced (left a

291 new developments in the area of miniaturised instrumentation which extends the concept and breadth of

292 ons depending on experimental conditions and instrumentation, which is consistent with previous studi

293 tend to involve sophisticated and expensive instrumentation, while providing only modest temperature

294 The techniques and instrumentation will be useful for objective quantitativ

295 e, the current advancement in technology and instrumentation will certainly provide better insights i

296 n of custom-designed portable in situ EC-XRF instrumentation will make heavy metal analysis at the so

297 Progress required design of instrumentation with ever-increasing spatial and tempora

298 ure assessment rely on cumbersome laboratory instrumentation with high capital and operational expend

299 detection of mechanical curvature, enabling instrumentation with simpler geometry.

300 ation of compact and non-invasive diagnostic instrumentation, with both bedside and intra-operative o