ライフサイエンスコーパス: automation

1 oved levels of control, reproducibility, and automation).

2 ta is a key open challenge that has resisted automation.

3 broad range of analytes and a high degree of automation.

4 nts, which can be applied at a high level of automation.

5 gh selectivity, low sample volume, and assay automation.

6 experiment without the need for robotics or automation.

7 ication of image data require algorithms for automation.

8 echnique to the field of clinical laboratory automation.

9 significant innovation of the method is the automation.

10 simplified the procedure and facilitated its automation.

11 d reproducibility, and the potential of easy automation.

12 very promising, opening the possibility for automation.

13 ing a broadly applicable method suitable for automation.

14 ease uniformity in cell-based assays through automation.

15 ses speed, avoids contamination, and enables automation.

16 igher throughput and consistency afforded by automation.

17 mounts of reagents required and the need for automation.

18 seful for biological, chemical and materials automation.

19 e for further development and radiochemistry automation.

20 -applicability, sensitivity and capacity for automation.

21 n is integrated into the device for improved automation.

22 n food analysis facilitating high-throughput automation.

23 miting user time commitment and bias through automation.

24 the TNAI assay reduced hands-on time due to automation.

25 ich challenges both microfluidics and system automation.

26 satisfactory in either accuracy or extent of automation.

27 of false positive annotations emerging from automation.

28 t none is well-suited to high throughput and automation.

29 aration time, small sample requirements, and automation.

30 , cost-effective, rapid, and well suited for automation.

31 tested these hypotheses by using laboratory automation.

32 of mycobacterium species that is amenable to automation.

33 ster, to investigate the feasibility of full automation.

34 d their corresponding equations has resisted automation.

35 ing multiple processes, parallelization, and automation.

36 ample manipulation and is easily amenable to automation.

37 cs, function or activity, and is amenable to automation.

38 ivity and reproducibility, and potential for automation.

39 ble to massive scale-up, miniaturization and automation.

40 vide useful visualizations that can aid such automation.

41 l for high-throughput assays and is suitable automation.

42 itive, accurate, robust, and compatible with automation.

43 ently simple to multiplex and is amenable to automation.

44 lack sufficient ease of use, throughput, and automation.

45 s simple, stable, sensitive, and amenable to automation.

46 s, and provides the opportunity for complete automation.

47 can be easily integrated into a pipeline for automation.

48 ss amenable to high-throughput operation and automation.

49 e of their potential for miniaturization and automation.

50 ic scale owing to the lack of efficiency and automation.

51 ber of medicinal libraries, and amenable for automation.

52 impact on communication and opportunity for automation.

53 gram sample quantity and is amenable to full automation.

54 user error, which can be partly overcome by automation.

55 sequences in a modular manner using robotic automation.

56 ocess can be implemented manually or through automation.

57 hput selections that lends itself to process automation.

58 anomanufacturing with the potential for full automation.

59 f machine vision and learning techniques for automation.

60 functions on a single substrate, and enables automation.

61 a shorter time span and is more suitable for automation.

62 i) in situ detection capability and complete automation.

63 orm in parallel, and has limited options for automation.

64 tion, high-throughput format adaptation, and automation.

65 re discussed in light of miniaturization and automation.

66 bor-intensive procedure creates a barrier to automation.

67 eat potential for bulk fabrication with full automation.

68 d method was 2.5 h prior to transferring for automation, 1.3 h of automation, and 10 min postautomati

69 Such automation advances, when provided by multiuser faciliti

70 n total, 104,730 specimens were enrolled and automation agreed with manual analysis for 90.1% of all

71 l gas chromatography (3-D GC) system with an automation algorithm.

72 Nevertheless, this automation also makes it humanly impossible to manually

73 combination of microfluidic membrane valves, automation and a streamlined protocol now enables a sing

74 ia: sleepwalkers exhibited improved movement automation and a stronger dissociation between locomotor

75 blood culture system incorporating improved automation and an enhanced detection algorithm to shorte

76 We hypothesized that automation and analytic tools can repurpose the informat

77 ses for suspension cultures are amenable for automation and are easily monitored and regulated to mai

78 ng two specific classifiers as a toolset for automation and cell identification in the model organism

79 rticocerebellar loop disruption resulting in automation and cognitive optimisation lack in MS.

80 me and access to appropriate liquid handling automation and detection instruments, a single investiga

81 As automation and device fabrication of semiconductor quant

82 new analyses that are made possible by such automation and discuss challenges of implementation and

83 ollection, this method should be amenable to automation and further scale up for preparation of large

84 ty determination was developed, facilitating automation and future routine clinical application of CL

85 ll format of our assay makes it suitable for automation and high throughput.

86 plate reader formats, and it is amenable for automation and high-throughput analysis.

87 fast and nonexpensive, hence well suited for automation and high-throughput applications.

88 on of MCs/Nod with the additional benefit of automation and high-throughput possibilities for large s

89 Microfluidic devices offer automation and high-throughput screening, and operate at

90 variability while affording suitability for automation and high-throughput uses.

91 .81+/-0.017, make the SPA format amenable to automation and higher throughput; hence, this assay can

92 le separation, have been developed and allow automation and integration of complex assay protocols in

93 The high degree of automation and interactivity in QuickMIRSeq leads to a s

94 the potential for medium- to high-throughput automation and its use in identifying physiologically re

95 correlation between the results obtained by automation and manual delineations by experts.

96 onomy of this technique make it amenable for automation and mass production, which could make polymer

97 With advances in automation and miniaturization in material fabrication,

98 ysis time (30 min), the simplicity, and easy automation and miniaturization of the required instrumen

99 The flow system was designed to focus on automation and miniaturization with minimal sample and r

100 ple bi-RMF provides a promising strategy for automation and multiplexing of magnetic particle-based a

101 t nature, which can be partially overcome by automation and new continuous monitoring technologies, a

102 Automation and optimization of DNA construction results

103 s adaptable to high-throughput screening and automation and provides a practical method to enhance cu

104 l mass spectrometry (MSn) and supported with automation and related computational tools.

105 a that can be applied to clinical use, where automation and reproducibility are critical.

106 hey must be refrigerated and typically limit automation and require more user steps.

107 al microindentation techniques with the high automation and resolution approaching that of atomic for

108 The technique is amenable to automation and streamlined workflow integration, with po

109 ducibility, making the procedure amenable to automation and suitable to routine analysis.

110 r tool but to provide a platform for further automation and tools development.

111 rapid (18 h), easy to scale up, amenable to automation and useful for a variety of samples.

112 ior to transferring for automation, 1.3 h of automation, and 10 min postautomation, resulting in a to

113 sts of luminescent reporter cells, screening automation, and a data analysis pipeline.

114 aration cost and time and is compatible with automation, and an efficient bioinformatics pipeline to

115 d, minimum sample handling, compatibility to automation, and applicability to large-scale metabolomic

116 citing opportunities for device integration, automation, and assay standardization.

117 of conventional SDS CGE (labor-saving, easy automation, and convenient quantitation) and also the hi

118 vice allows for ambient temperature storage, automation, and ease of shipping/transfer of samples.

119 een developed that enable higher-throughput, automation, and greater mass sensitivity.

120 uch as reagent addition with high precision, automation, and throughput.

121 d dynamic robots, which thrive in industrial automation, and will probably continue to do so for deca

122 plication at hand; (3) they are suitable for automation; and (4) they can optionally combine the adva

123 y separate proteins with high resolution and automation are highly desirable.

124 igned to the detection volume to improve the automation as compared to confocal SERS, which requires

125 sampling, point-of-care tests, and extended automation as well as new technologies, including mass s

126 et of tumor types and offers the benefits of automation as well as standardization.

127 ither manual reading only or paired reading (automation-assisted reading and manual reading), between

128 ntial increase in specificity, suggests that automation-assisted reading cannot be recommended for pr

129 The inferior sensitivity of automation-assisted reading for the detection of CIN2+,

130 The primary outcome was sensitivity of automation-assisted reading relative to manual reading f

131 Specificity of automation-assisted reading relative to manual reading i

132 Automation-assisted reading was 8% less sensitive than m

133 By automation-assisted screening of numerous sediment sampl

134 ing processors are poised to replace robotic automation by miniaturizing biochemical reactions to the

135 We propose a procedure with automation capability to group and annotate peaks associ

136 Higher-order data generation implies some automation challenges, which are mainly related to the h

137 ligonucleotides into genes and genomes makes automation challenging, and site-specific incorporation

138 he method offers significant versatility and automation compared with common but laborious titration

139 Testing automation could even minimise variation caused by subje

140 Automation data packages can also be used as publication

141 e, the upcoming wave in molecular biological automation demands a rethinking of how we perform DNA as

142 platform with simple modular fluid delivery automation design described here is interchangeable betw

143 56% (15/961 samples), was observed after DS2 automation (difference, 4.0%; 95% confidence interval [C

144 Furthermore, with automation difficulties and extended sample preparation

145 Automation does not have an impact on the repeatability

146 The developed methodology is amenable to automation, enabling high-throughput determination of la

147 ay developers, high-throughput screening and automation engineers, computational scientists, and soft

148 Using robotic automation, epoxide-functionalized block polymers were c

149 omograms due to advances in data acquisition automation, existing computational approaches have very

150 Through this module, dChip automation files can be created to include menu steps, p

151 lly produced lines or lines produced through automation followed by single-colony subcloning.

152 ve been developed to create total laboratory automation for clinical microbiology.

153 The method was streamlined with automation for consistency and throughput.

154 and because it is compatible with laboratory automation for high-throughput analysis.

155 ing unique advantages and the possibility of automation for high-throughput experiments by exploiting

156 This assay is also amenable to automation for high-throughput screening and yields exce

157 rface to provide higher levels of laboratory automation for in situ biotests.

158 employed to provide sample-to-answer fashion automation for plasma extraction (from finger-prick of b

159 e method also allows for increased scale and automation for the large-scale production of mutant mice

160 pling reactions as a test case, we developed automation-friendly reactions to run in dimethyl sulfoxi

161 The FTIR method as structured is amenable to automation (>120 samples/h) and provides a very competit

162 reas experts are expected to use unconscious automation (habitual DM) in which decisions are recognit

163 reas experts are expected to use unconscious automation (habitual DM) in which decisions are recognit

164 vides linearity in response, data processing automation, improved limits of detection, and ease of us

165 pens a brand new alternative for inexpensive automation in aquatic ecotoxicology.

166 e is a general drive for miniaturisation and automation in chemistry and biology, and immobilisation

167 ortant with the drive to miniaturisation and automation in chemistry, biology and medicine.

168 Historically, the trend toward automation in clinical pathology laboratories has largel

169 SFT promises to advance the goal of full automation in image analysis.

170 Up to now, use of automation in immunofluorescent staining was mostly limi

171 t double what was achieved with conventional automation in large-scale protein structure consortia.

172 be performed to fully assess the benefits of automation in microbiology laboratories.

173 reasingly being performed using microfluidic automation in multiwell format.

174 is easily adaptable and amenable for future automation in order to mimic standardized organ dynamics

175 cle, we review the historical impediments to automation in the microbiology laboratory and offer insi

176 ample preparation approach that enables full automation including all the process phases just in a co

177 uickly engineer alternatives to conventional automation infrastructure that are low-cost and user-fri

178 High-content screening microscopy relies on automation infrastructure that is typically proprietary,

179 sent development of a customized mechatronic automation interface that includes a high-resolution USB

180 a dramatic change that will sweep a wave of automation into clinical microbiology laboratories.

181 The automation is achieved by using a Bayesian formalism for

182 Automation is an ideal approach for high-throughput samp

183 Combining this with robotic automation is difficult, however, as micropipette penetr

184 The HPLC-based platform for automation is easy to setup and adapt to different syste

185 A convenient type of automation is in the form of workflows that also allow s

186 uctured experimentation for which laboratory automation is necessary.

187 -clamp recording has recently benefited from automation, it is normally performed "blind," meaning th

188 ion throughput was greatly improved using an automation liquid-handling system, meeting the needs for

189 The microfluidic chip successfully combines automation, low sample consumption, ultra-sensitive fluo

190 mode has advantages such as its reusability, automation, low sample volume (6 muL), and fast response

191 The demonstrated automation, low sample-to-answer time and portability of

192 This high degree of automation makes the developed EME-autosampler a powerfu

193 larization or the experimental stability for automation-making this approach beneficial for improving

194 ce, show extensive potential applications in automation, manufacturing, process control, and portable

195 San Antonio explains why he thinks that this automation may not become widely used.

196 This study demonstrates that GM-EIA automation may reduce intersite variability.

197 Similar automation mechanisms could be valuable to the research

198 The dChip automation module is a step toward reproducible research

199 implementation and application of the dChip automation module.

200 f Robot Scientist "Adam," which advances the automation of both.

201 and is a simple and compact solution for the automation of colony-counting assays and microbe behavio

202 Progress in the miniaturization and automation of complex analytical processes depends large

203 g operations that can be combined to achieve automation of complex and diverse assay protocols.

204 ved the data release frequency by increasing automation of curation and providing scaling improvement

205 tic, metagenomic and genome assembly provide automation of data conversion, analysis and graphical vi

206 Our future tasks include automation of data flows and further integration with ot

207 Automation of dispersive solid-phase extraction (d-SPE)

208 Automation of EIAs can reduce variation.

209 n the R environment for further analysis and automation of error detection.

210 lution, experimental versatility and mostly, automation of force recordings.

211 ore complex circuits, ssTEM will require the automation of image processing.

212 Automation of immunostaining improves reproducibility an

213 the microarray analysis platform MCR 3, the automation of isothermal multiplex-amplification (39 deg

214 nd applicability to be fully exploited, full automation of its operations seamlessly integrated with

215 Automation of laboratory tests, bioinformatic analysis o

216 hese unit operations can be combined for the automation of laboratory workflows.

217 We describe automation of liquid injection field desorption/ionizati

218 and the current version 3.0, emphasizing the automation of many steps and addition of various checks

219 s, we have demonstrated that high-throughput automation of Mass Frontier allows researchers to genera

220 ecome a valuable tool for simplification and automation of molecular biology protocols.

221 pipet tips have great potential in achieving automation of N-linked glycopeptide isolation for high-t

222 ogy for simple, scalable, and transformative automation of oligosaccharide synthesis that easily inte

223 ethodologies in mass spectrometry, including automation of phosphopeptide enrichments and detection,

224 ons illustrate the feasibility of procedural automation of physics-based scoring calculations to prod

225 Automation of postsearch validation was approached by tw

226 So far, the automation of preprocessing raw mass spectra has not bee

227 the improvement of "omic" technologies, and automation of protein crystallization makes this strateg

228 t, simplicity, small size, as well as facile automation of sample delivery and processing without the

229 Here we report the complete automation of sample handling, high-resolution microscop

230 advantages, such as low reagent consumption, automation of sample preparation, reduction in processin

231 The automation of specimen processing and culture workup has

232 These systems allow for the automation of specimen processing, specimen incubation,

233 This allows the automation of such tasks using the R programming languag

234 It also enables automation of tasks performed using PathVisio, making it

235 in 2 broad and highly interconnected areas: automation of tasks that might otherwise be performed by

236 Automation of the assay was demonstrated in a flow-throu

237 rostate specific antigen (PSA) at 330 fg/mL, automation of the assay, and the results of a clinical p

238 in a tester set-up that facilitated complete automation of the assay.

239 The simplicity and automation of the CE-LIF assay offers advantages over th

240 core-shell microspheres as sorbent to enable automation of the integrative extraction and analytical

241 stopped-flow reactor allows near continuous automation of the process leading to potential industria

242 with enhanced resolution of the analysis and automation of the signal processing stage.

243 of (18)F-FDOPA, resulting in straightforward automation of the synthesis in a commercially available

244 Upon automation of the system and optimization of the method,

245 a microfluidic Lab-on-a-Chip technology for automation of the zebrafish embryo toxicity test common

246 Unquestionably, the automation of these technologies allows for faster sampl

247 Our goal is to provide partial automation of this process to begin examining associatio

248 The automation of this step opens the SPN simulator to a far

249 Automation of this task is therefore critical to enablin

250 The automation of this technique allows it to be applied eas

251 The miniaturization and automation of this technology has led to an associated p

252 Automation of tunneling current-distance (I(s)) spectros

253 automates "blind" patching in vivo, but full automation of visually guided, targeted in vivo patching

254 nsors and simple nonmicrofluidic measurement automation offers a convenient, labor- and cost-efficien

255 Assay automation on an electromechanical instrument produced a

256 mount of technical preparation, facilitating automation, optimizing selections by matching display le

257 A miniaturized automation platform enabling high-throughput experimenta

258 An automation process was implemented using a custom image

259 Partial automation provides reproducibility and throughput essen

260 med Radial Column Array for Distribution and Automation (RCADiA), to automate multiple MuDPIT experim

261 Automation results were discordant for 10,348 specimens,

262 f care (PoC) devices, with lower unit costs, automation, reusability and ease of use.

263 tains an updated processor enabling complete automation, revealed the two tests to be functionally eq

264 group from the Department of Urology and the Automation & Robotics Research Institute of the Universi

265 for analyzing CyTOF data attempt to improve automation, scalability, performance and interpretation

266 Design automation simplifies the incorporation of genetic circu

267 e in software used for visualizing GEMs: (i) automation, since GEMs can be quite large; (ii) producti

268 The operation of MACS is described, and automation software is provided to integrate MACS contro

269 instruments as well as the total laboratory automation solutions.

270 alytical instrumentations with unprecedented automation, speed of analysis, and flexibility.

271 An automation system accommodates loading of two samples vi

272 Through the use of the assay automation system and the PC embedded within the microfl

273 ic cartridge for holding the PC and an assay automation system that provides a leak-free fluid interf

274 ly invasive surgery, active prosthetics, and automation tasks involving delicate irregular objects.

275 ently, there is considerable interest in new automation that could potentially lessen labor demands f

276 ucibility, quickness, and compatibility with automation, the minimization of matrix effects being amo

277 low time consumption, and compatibility with automation, the new proposed method could be a suitable

278 Beyond the convenience of automation, the RCADiA platform also produces data of si

279 With computer automation, the reactor can prepare binding reactions fr

280 real-time PCR has the highest potential for automation, therefore representing the currently most su

281 addition, we have adapted this technique for automation, thus enabling the simultaneous and rapid ana

282 ALDI-TOF MS) and BD Kiestra total laboratory automation (TLA) 4 and 3 years ago, respectively.

283 lection; adoption of DNA design software and automation to build constructs and libraries more easily

284 Full automation to enable high throughput N-glycosylation pro

285 ely used genomics tools, parallelization and automation to increase the accuracy and accessibility of

286 mized design of microfluidic channels allows automation to mimic sequential analytical steps in bench

287 mple inputs, paving the way for microfluidic automation to replace robotic library distribution.

288 to a flow-injection analysis system, in full automation under the control of a sampler manager.

289 High throughput is achieved by SPME automation using a CTC Analytics platform and custom bag

290 o standard data analysis procedures and full automation using scripts, QSoas features a very powerful

291 e enrichment statistics, pipeline-compatible automation via scripting and the ability to completely c

292 Method automation was achieved by using a robotic system for sp

293 High-throughput, parallel processing, and automation were achieved through integration of the meta

294 pound screens, infection models, and robotic automation, which are promising to revolutionize the stu

295 We envision that this automation will make it practical to systematically deci

296 transparent approach that supports potential automation with flexibility to incorporate new data sour

297 let control in the muChopper was improved by automation with pneumatic valves, allowing fluorescence

298 n large LC/MS data sets requires significant automation without loss of accuracy in the compound scre

299 To streamline automation workflow and minimize operator intervention,

300 Complete automation would also yield unambiguous documentation of