ライフサイエンスコーパス: database search

1 DAS algorithm (Metabolite Identification via Database Searching).

2 g peptides to be identified by a nontargeted database search.

3 the dual-search approach than with a typical database search.

4 tide filtration in peptide identification by database search.

5 for HCC with MR imaging were identified via database search.

6 of candidate peptides, thus speeding up the database search.

7 /CT for tumor staging were identified from a database search.

8 onal structural descriptor when performing a database search.

9 of possible decoy glycopeptides tested in a database search.

10 s a spectrum-adapted, a posteriori score for database search.

11 nuary 1985 and April 2012 were identified by database search.

12 ng mass spectrometry followed by appropriate database search.

13 entifications of MS/MS spectra returned by a database search.

14 s in children were identified from a MEDLINE database search.

15 roteoform identification through an off-line database search.

16 protein structure prediction, and biological database search.

17 entatively matched to a peptide sequence via database search.

18 being applied to large-scale RNA structural database search.

19 ively improved the accuracy and speed of the database search.

20 after duplicates removed, were found by the database search.

21 structural descriptor used when performing a database search.

22 year include PubMed Labs and a new sequence database search.

23 management of chronic pain were obtained by database search.

24 ntages over methods that are purely based on database search.

25 g the confidence of proteoform IDs after the database search.

26 akes predictions based on iterative sequence database searches.

27 GR-Align, a CMO heuristic that is suited for database searches.

28 tive fragment ions that are reproducible for database searches.

29 Studies were identified by systematic database searches.

30 omain and functional predictions for protein database searches.

31 and made readily accessible to many types of database searches.

32 om the literature, homologous sequences, and database searches.

33 e, accurate mass, elemental composition, and database searches.

34 quid chromatography-tandem MS (LC-MS/MS) and database searching.

35 proach that combines de novo sequencing with database searching.

36 ndem mass spectrometry combined with protein database searching.

37 data suitable for peptide identification via database searching.

38 printing, and protein identification through database searching.

39 tide mixtures were analyzed by LC/MS/MS with database searching.

40 1,485 potentially relevant articles from the databases searched.

41 as a consequence of the poor indexing of the databases searched.

42 original 2326 studies identified through the database search, 38 studies were used to investigate rat

43 ts on miRNA obtained through the NCBI PubMed database search (adjusted P = 0.024).

44 modified peptide sequences was achieved by a database search against apo B-100 protein sequences usin

45 inked peptide pair using a fragment ion mass database search against known protein sequences coupled

46 manual confirmation step including a public database search against PubMed and sequence analyses, e.

47 sts of an LC-MS feature-finding algorithm, a database search algorithm, and an interactive results vi

48 ically generated peptides using a proteomics database searching algorithm.

49 e spectra at the first MSMs than an existing database-searching algorithm, MetFrag.

50 A breakthrough in efficient database search algorithms is crucial for peptide identi

51 SEQUEST and X!Tandem database search algorithms were used for peptide sequenc

52 ine amino acid composition, (2) an input for database search algorithms, or (3) a basis for de novo s

53 ced dissociation (CID) MS/MS experiments and database search algorithms.

54 ine and improve peptide identifications from database search algorithms.

55 need for specific parametrization of protein database search algorithms.

56 identification of O-GalNAc glycopeptides by database search and (7) quantification of O-GalNAc glyco

57 4077 peptides (2725 modified) identified by database search and 2665 peptides (223 modified) identif

58 tal of 8199 studies were identified from the database search and 30 met the inclusion criteria for th

59 r include a new PubMed interface, a sequence database search and a gene orthologs page.

60 Articles were identified through a database search and by consulting reference lists of rev

61 Database search and de novo algorithms must consider hig

62 caveats associated with the use of standard database search and error-modeling methods with nonstand

63 tion of the approach based on the MassMatrix database search and LC retention time analysis programs

64 The database search and literature review failed to find an

65 on is demonstrated with test cases including database search and pairwise alignment of protein hydrop

66 The authors conducted an electronic database search and reviewed the 14 articles that fit pr

67 h their corresponding amino acid sequence by database search and subsequent MALDI-TOF/TOF analysis.

68 A total of 67 imaged lipids were assigned by database search and, in a number of cases, identified vi

69 ID INSENSITIVE1 (BRI1) is a BR receptor, and database searches and additional genomic sequencing iden

70 G) method, which performs iterative sequence database searches and annotates a query sequence with Ge

71 c reviews were identified through electronic database searches and citation tracking.

72 Studies were located via electronic database searches and hand searching.

73 ion (BioCAn), that combines the results from database searches and in silico fragmentation analyses a

74 using literature and international mutation database searches and in silico prediction models.

75 Database searches and in vitro kinase assays identified

76 provide incremental improvement in structure database searches and initial sequence database searches

77 e data obtained from LC-MS/MS, combined with database searches and protein assembly algorithms, allow

78 eference lists to identify records missed by database searches and publicly available data not yet pu

79 duces a new graphical interface, much faster database searches and several new options for visualizat

80 de) was discovered by using 3D pharmacophore database searches and was biologically confirmed as a ne

81 s, these were satisfactory in relation to MS database searching and mass accuracies.

82 approaches have been established: web-based database searching and PCR-based reverse screening.

83 olve hard problems, such as prime factoring, database searching and quantum simulation, at the cost o

84 ion and implements improved capabilities for database searching and results filtering.

85 , derived based on the CDD (conserved domain database) search and literature curation.

86 spectra can be identified with conventional database-searching and protein-inference tools, allowing

87 built from the identification results from a database search, and then, the library is used to resear

88 n array of 1D/2D NMR experiments at 800 MHz, database searches, and spiking with authentic compounds

89 Rognes's SWIPE optimal database search application is still generally the faste

90 s with existing methods that employ a direct database search approach.

91 A database searching approach can be used for metabolite i

92 ermediate results of sequence and structural database searches are also available.

93 Sequence database searches are an essential part of molecular bio

94 ation methods, including chemical similarity database searches, are limited to single or sequential l

95 Institutional database search at the Cincinnati Eye Institute revealed

96 m the United Kingdom Transplant Registry and database search at transplantation centers.

97 ategies were undertaken in July-August 2016: database searching, backwards citation searching and for

98 dem mass spectrometry improves confidence in database search-based peptide identification and facilit

99 oid adducts were not identified in MS2-based database searches because collision-induced adduct loss

100 ollo), data mining (BovineMine) and sequence database searching (BLAST).

101 Medical record database searches by ICD-9 codes were used to identify H

102 ed complete eukaryotic genomes, we conducted database searching by hidden Markov models, multiple seq

103 Expression of AFP was investigated using database searches, by qPCR, and by immunohistochemistry

104 ecent years, the current methods for peptide database searching cannot rapidly and thoroughly process

105 To enhance the database search capabilities, the BLAST and BLAT search

106 tivities and specificities were achieved for database searches carried out with MassMatrix, Mascot an

107 A compound database search (ChemSpider) was performed to retrieve c

108 demonstrate how MSFragger empowers the open database search concept for comprehensive identification

109 genetics, based on PubMed and Web of Science database searches conducted according to the PRISMA guid

110 Databases search consisted of MEDLINE and PubMed.

111 alk-throughs (n = 5), focus groups (n = 31), database searches, context questionnaires (n = 8), famil

112 ariants of the TDA procedure in a variety of database search contexts.

113 "Serac") that consumes results of the Mascot database search engine and identifies the amino acids va

114 We present a free and open-source database search engine for RNA MS data, called NucleicAc

115 We present a sequence database search engine that is specifically designed to

116 lementary hardware realization of a parallel database search engine that, when running on a Xilinx Vi

117 , MPA Portable now supports state-of-the-art database search engines and a convenient command line in

118 Automated database search engines are one of the fundamental engin

119 nt peptide sequence identification by common database search engines, MAGIC generates in silico spect

120 gh-throughput experiments, mass spectrometry database search engines, such as MASCOT provide a ranked

121 were systematically collected through large database searches, filtered through methodological inclu

122 A database search for "polyp" in all US examinations of th

123 A database search for EGF domain sequences shows that this

124 ntified via a pathology and dermatopathology database search for patients diagnosed as having high-ri

125 upporting various functionalities, including database search for protein and peptide identification,

126 The approach of two-step database search for qualitative analysis and proteome to

127 An electronic database search for randomized controlled trials that ev

128 A PubMed database search for relevant literature on this topic pu

129 al high throughput screening followed by web-database search for similar structures.

130 Following computational analyses and database searches for candidate exosites, we utilized si

131 ams, and hierarchical cluster analysis), and database searching for metabolite identification.

132 r a priori spectral predictions and enhanced database searching for protein identification.

133 y analysis using high-precision instruments, database searching for the addition of N-terminal argini

134 ell can be queried with a tap, and community databases searched for available information about that

135 FASD using multiple electronic bibliographic databases, searching for studies published up to July, 2

136 rary, and relevant reviews identified by our database search, for research published from Jan 1, 1972

137 MEDLINE and Google Scholar database searches from 1966 to 2011 were performed for E

138 d, PsychINFO, Cochrane Library, and the TRIP Database, searched from January 1, 2000, to February 26,

139 A database search (from January 2001 to March 2010) was pe

140 rom MS/MS spectra are identified by means of database searches, given samples with known genome-wide

141 A three-dimensional database search has been applied to design a series of e

142 pectrum matches (PSMs) obtained by proteomic database search has been well-recognized.

143 A human genomic database search has revealed a number of sequences conta

144 s of glycopeptide identification by a direct database search have been reported, false positives rema

145 cture database searches and initial sequence database searches; however, the enhancements show signif

146 A Drug Gene Interaction Database search identified 47 gene products to be affect

147 An electronic database search identified 885 citations, and a manual s

148 y thought to be a unique protein, a proteome database search identified at least 46 bacterial CooJ ho

149 PubMed and Cochrane Database searches identified articles based on design, o

150 Database searches identified orthologs for P19 and NEEP2

151 Systematic database searches identified studies reporting adult ADH

152 in scope to peptides that are identified by database searching in the first step, all MS data are co

153 The database search included key terms related to syphilis a

154 Databases searched included MEDLINE, PREMEDLINE, the Coc

155 Databases searched included The Cochrane Airways Group R

156 or putatively identified based on metabolome database searches, including 20 pairs positively identif

157 Database search is the most widely used approach for pep

158 e discovery rate (FDR) from the target-decoy database search is typically deployed to filter identifi

159 Tandem mass spectrometry (MS/MS)-based database searching is a widely acknowledged and widely u

160 PubMed and Cochrane database searches, last conducted in December 2014, yiel

161 In traditional sequence database search, many good-quality MS/MS data remain una

162 Although in silico database search methods remain more popular for shotgun

163 nsistent and unified approach to de novo and database-search methods, which is a distinctive feature

164 ormance similar to that of other de novo and database-search methods, which is reasonable, given the

165 systematic reviews to identify articles the database searches might have missed.

166 A cross-sectional database search of all RCTs published in nursing journal

167 By identifying from a database search of approximately 15000 antibody sequence

168 Retrospective pathology database search of explant histology analysis of liver t

169 incorporating variable modifications in the database search of GlycoPep DB enhances glycopeptide cov

170 A comprehensive database search of MEDLINE, EMBASE, CINAHL, and PubMed C

171 Database search of patients from 2003-2013 who underwent

172 Database search of patients with severe limbal stem cell

173 With a radiology database search of pelvic magnetic resonance images from

174 tified with mass spectrometry by independent database search of spectra associated with the two linke

175 We conducted a MEDLINE/EMBASE/CENTRAL database search of studies from 1966 to May 2008.

176 Database searches of MEDLINE (PubMed), EMBASE (OVID), Co

177 We conducted electronic database searches of phase III randomized controlled tri

178 e systematically obtained through electronic database searches of PubMed/MEDLINE, PsycINFO, Web of Sc

179 Database searching of isotopically labelled PTMs can be

180 This outcome was especially useful for database searching of larger proteins (approximately 29

181 high-throughput molecular identification via database searching of standard libraries is briefly disc

182 ransthyretin) were confidently identified by database searching of the acquired tandem spectra from p

183 of the PubMed, EMBASE, PsycINFO and Cochrane databases, search of reference lists and conference abst

184 We identified 8632 articles through our database search, of which 515 were eligible for full-tex

185 this can be a frustrating experience because database searches often miss relevant articles.

186 regulation of OPG expression, we conducted a database search on regulatory elements in the promoter r

187 ation of intact protein species, and perform database search online to yield real-time protein identi

188 pattern sets, maximize their sensitivity in database searching or minimize the variance of the numbe

189 ptides and proteins heavily rely on sequence database searching or spectral library matching.

190 all phams can be assigned functions based on database searching or synteny.

191 Individual metabolites can be identified via database searching or, in the case of novel compounds, t

192 raries (CPLLs), SDS-PAGE, nLC-ESI-MS/MS, and database search, permitted identifying 175 proteins.

193 Integrating Prosit into database search pipelines led to more identifications at

194 data and the identification of SAPs through database searching, post-processing and generation of HT

195 A JASPAR database search predicts that the T to C transition in r

196 e mutations were identified by expanding the database search process of raw mass spectrometry files b

197 The PSI-BLAST protein database search program derives the column scores of its

198 A database-searching program, Sipros 3.0, was developed fo

199 Database search programs for peptide identification by t

200 plays an important role in protein sequence database search, protein structure prediction, protein f

201 We show that, for database searching, rasbhari generates pattern sets with

202 mbing algorithm to optimize pattern sets for database searching, read mapping and alignment-free sequ

203 A five-database search, reference review, and hand search ident

204 c stroke neuroprotection based on electronic database searches, references of previous publications,

205 tion of the UVPD-MS method with an in silico database search restricted to Tyr- and His-containing pe

206 Extensive database searches resulted in only 13 similar metal bind

207 ed application of the AAC information during database searching resulted in an average 3.5-fold highe

208 e a wide range of proteomics data, including database search results, de novo sequencing results, pro

209 Since PFP and ESG are based on sequence database search results, our analyses are not only usefu

210 tage validation of primary mass spectrometry database search results.

211 The database search retrieved 4,172 unique citations, of whi

212 igned and implemented such that most protein database searches return within a few seconds.

213 A PubMed database search returned 27 studies on 16 cohorts report

214 A transcription factor database search revealed that a putative interferon-stim

215 A genomic database search revealed that c-type cytochromes with a

216 Database searches revealed that many members of the inte

217 Public database searches revealed that the polymorphic nature o

218 Epitope mapping and database searches revealed the presence of a structured

219 Database searching revealed that Plg-R(KT) mRNA is broad

220 A database search reveals thousands of candidate topologic

221 Database searches show p22 is structurally similar to hu

222 Database searches showed that homologs of cruF and cruG

223 Database searches showed that the genes for the glyoxyla

224 del used to rank the similarities found in a database search, so that biologically relevant relations

225 omise for the development of fast structural database search solutions.

226 id composition (AAC) ions is to restrict the database search space and provide identification of pept

227 web interfaces for analyses such as sequence database search, statistical validation, and quantitatio

228 ata and a cross-validation with conventional database search strategies, we identified approximately

229 omposing a given unknown mixture, a two-step database search strategy for bottom-up nanoscale liquid

230 lized de novo sequencing for O-glycans and a database search strategy for peptide backbones.

231 ass search strategy seems the most promising database search strategy.

232 he UVPD fragmentation patterns, an automated database searching strategy (based on the MassMatrix alg

233 Herein we report a novel database-search strategy based on the use of MS/MS spect

234 night tryptic digestion, sample analysis and database searching, takes approximately 24 h to complete

235 ned peptides using an ultra-tolerant Sequest database search that allows peptide matching even with m

236 Current methods use database searches that are dependent on acquiring interp

237 ns, we systematically searched peer-reviewed databases, searched the grey literature, and disseminate

238 n the mass spectrometer per se and following database searching, the matching of the molecular masses

239 ding time spent acquiring data, and time for database searching, the procedure takes approximately 1-

240 o the complexity of MS/MS data and the large databases searched, the accuracy of peptide identificati

241 Database searches through August 2014 identified 48 elig

242 dies (enrolling 2625 patients) identified by database searches through January 2012 were included.

243 Database searches through March 2014 were undertaken and

244 Electronic databases searched through October 2008 identified 3,794

245 ranging from ultra-fast low-RAM k-mer-based database search to fully exhaustive gapped DNA alignment

246 All elements of data analysis-from database search to site-resolved and normalized labeling

247 We conducted database searches to identify members of the RNHL superf

248 y with isobaric tagging (iTRAQ) and multiple database searching to identify proteins that were differ

249 We present a database search tool MS-GF+ that is sensitive (it identi

250 (HS-BLASTN), a parallel and fast nucleotide database search tool that accelerates MegaBLAST--the def

251 In addition, our work provides a database-search tool that enables rapid identification o

252 We used advanced database search tools to delineate testable hypotheses a

253 (it identifies more peptides than most other database search tools) and universal (it works well for

254 for x86 CPUs, most are embedded into larger database search tools.

255 ia sequences will improve the sensitivity of database search tools.

256 ovement in speed over most existing proteome database search tools.

257 We performed a comprehensive database search up to February 2017 and searched other r

258 8 NCBI RefSeq genomes in 33 CPU h; real-time database search using assembled or unassembled Illumina,

259 filters candidate peptide sequences during a database search using this information.

260 Protein database searches using the consensus PDZ-binding motif

261 d matrix by mass spectrometry and subsequent database searching using an O. beta transcriptomic seque

262 ative metabolites are then assigned based on database searching using both m/ z and C/N atom counts.

263 v2.0 was developed to perform unconstrained database searching using high-resolution tandem mass spe

264 th <10 ppm mass accuracy for highly specific database searching using tailored software.

265 In this work, we have performed database searches utilizing each D. melanogaster insulat

266 A comprehensive electronic database search was conducted in PubMed (2012-2017), Web

267 A database search was conducted to identify all RCTs publi

268 A PubMed MEDLINE database search was done to gather data on the published

269 Database searching was performed by using various combin

270 ND By incorporating extensive literature and database searches, we designed a collection of TALEN con

271 Using database searches, we extracted 66 distinct human RHOGAP

272 In various database searches, we observed no new associations betwe

273 The last database searches were conducted in July 2016.

274 Database searches were conducted on October 22, 2015.

275 Online database searches were performed for studies of prostate

276 Database searches were performed using MeSH terms, keywo

277 Compound identification criteria for database searching were defined and the approach was val

278 The databases searched were MEDLINE, MEDLINE In-Process, EMB

279 The databases searched were Ovid, EMBASE, CINAHL and Pubmed.

280 Databases searched were PubMed, Cochrane Library, PsychI

281 The databases searched were PubMed, Embase (OVID version), W

282 Results of the databases searched were supplemented with hand searching

283 Electronic databases searches were run to identify published and un

284 tudies, the conventional approach involves a database search, wherein chemical shifts are assigned to

285 Peptides maps or sequences were used for database searches which identified several homologs.

286 technologies, namely, mass spectrometry and database searching, which drove protein analysis from 1

287 by tryptic digestion, mass spectrometry, and database searching, which we enhance using isotope label

288 ion requires roughly 1-4 h per sample, and a database search will take 0.5-2 h to complete.

289 tides from AXL, triple the number found by a database search with Byonic software, and detected incor

290 collision-induced dissociation data into the database searches with ETD data may prove decisive in mo

291 resulting identifications while controlling database searches with robust and reproducible TDA estim

292 the reference sequence database in proteomic database searching with a customized protein database th

293 arily identified using biomedical literature database searches, with additional studies added at the

294 arily identified using biomedical literature database searches, with additional studies added at the

295 The database search yielded 1303 articles, of which 139 were

296 The database search yielded 2976 articles, of which 37 were

297 A surgical database search yielded medical record numbers of 925 pa

298 A database search yielded which threshold for Banff i was

299 Database searches yielded 1923 articles, of which 257 we

300 The database searches yielded 70 trials of which 13 met thes