VIAF

Virtual International Authority File

Search

Leader 00000nz a2200037n 45 0
001 WKP|Q41048978 (VIAF cluster) (Authority/Source Record)
003 WKP
005 20241120235913.0
008 241120nneanz||abbn n and d
035 ‎‡a (WKP)Q41048978‏
024 ‎‡a 0000-0001-9777-9767‏ ‎‡2 orcid‏
035 ‎‡a (OCoLC)Q41048978‏
100 0 ‎‡a Ronald Taylor‏ ‎‡9 es‏ ‎‡9 sl‏ ‎‡9 ast‏
375 ‎‡a 1‏ ‎‡2 iso5218‏
400 0 ‎‡a রোনাল্ড টেলর‏ ‎‡c গবেষক‏ ‎‡9 bn‏
400 0 ‎‡a Ronald Taylor‏ ‎‡c researcher‏ ‎‡9 en‏
400 0 ‎‡a Ronald Taylor‏ ‎‡c onderzoeker‏ ‎‡9 nl‏
670 ‎‡a Author's A guide to microarray experiments-an open letter to the scientific journals‏
670 ‎‡a Author's A network inference workflow applied to virulence-related processes in Salmonella typhimurium‏
670 ‎‡a Author's An analysis pipeline for the inference of protein-protein interaction networks‏
670 ‎‡a Author's An integrated approach to predictive genomic analytics‏
670 ‎‡a Author's An open letter on microarray data from the MGED Society‏
670 ‎‡a Author's An overview of the Hadoop/MapReduce/HBase framework and its current applications in bioinformatics‏
670 ‎‡a Author's Biological Network Inference and analysis using SEBINI and CABIN.‏
670 ‎‡a Author's Bottlenecks and hubs in inferred networks are important for virulence in Salmonella typhimurium‏
670 ‎‡a Author's Brain in situ hybridization maps as a source for reverse-engineering transcriptional regulatory networks: Alzheimer's disease insights‏
670 ‎‡a Author's Cells Respond to Distinct Nanoparticle Properties with Multiple Strategies As Revealed by Single-Cell RNA-Seq.‏
670 ‎‡a Author's Changes in translational efficiency is a dominant regulatory mechanism in the environmental response of bacteria.‏
670 ‎‡a Author's CO2 exposure at pressure impacts metabolism and stress responses in the model sulfate-reducing bacterium Desulfovibrio vulgaris strain Hildenborough.‏
670 ‎‡a Author's Computing and Applying Atomic Regulons to Understand Gene Expression and Regulation‏
670 ‎‡a Author's Coregulation of Terpenoid Pathway Genes and Prediction of Isoprene Production in Bacillus subtilis Using Transcriptomics‏
670 ‎‡a Author's Cover Image, Volume 231, Number 11, November 2016.‏
670 ‎‡a Author's Data standards for Omics data: the basis of data sharing and reuse‏
670 ‎‡a Author's Development of the Minimum Information Specification for In Situ Hybridization and Immunohistochemistry Experiments (MISFISHIE).‏
670 ‎‡a Author's Distinct strains of Toxoplasma gondii feature divergent transcriptomes regardless of developmental stage‏
670 ‎‡a Author's DNA correlations‏
670 ‎‡a Author's Enriching regulatory networks by bootstrap learning using optimised GO-based gene similarity and gene links mined from PubMed abstracts‏
670 ‎‡a Author's Evidence supporting dissimilatory and assimilatory lignin degradation in Enterobacter lignolyticus SCF1.‏
670 ‎‡a Author's Gene set analyses for interpreting microarray experiments on prokaryotic organisms‏
670 ‎‡a Author's Genomic expansion of domain archaea highlights roles for organisms from new phyla in anaerobic carbon cycling.‏
670 ‎‡a Author's GEST: a gene expression search tool based on a novel Bayesian similarity metric.‏
670 ‎‡a Author's Identification of Differential Gene Expression Patterns after Acute Exposure to High and Low Doses of Low-LET Ionizing Radiation in a Reconstituted Human Skin Tissue‏
670 ‎‡a Author's Learning biological networks via bootstrapping with optimized go-based gene similarity‏
670 ‎‡a Author's Microbial Community Metabolic Modeling: A Community Data-Driven Network Reconstruction‏
670 ‎‡a Author's Minimum information about a microarray experiment (MIAME)-toward standards for microarray data‏
670 ‎‡a Author's Minimum information specification for in situ hybridization and immunohistochemistry experiments (MISFISHIE)‏
670 ‎‡a Author's Modeling dynamic regulatory processes in stroke‏
670 ‎‡a Author's Modeling framework for isotopic labeling of heteronuclear moieties‏
670 ‎‡a Author's Network analysis of transcriptomics expands regulatory landscapes in Synechococcus sp. PCC 7002.‏
670 ‎‡a Author's Network inference algorithms elucidate Nrf2 regulation of mouse lung oxidative stress‏
670 ‎‡a Author's PACAP interactions in the mouse brain: implications for behavioral and other disorders.‏
670 ‎‡a Author's Predicting Species-Resolved Macronutrient Acquisition during Succession in a Model Phototrophic Biofilm Using an Integrated 'Omics Approach‏
670 ‎‡a Author's Reverse engineering adverse outcome pathways‏
670 ‎‡a Author's SEBINI: Software Environment for BIological Network Inference.‏
670 ‎‡a Author's Standards for microarray data‏
670 ‎‡a Author's Submission of microarray data to public repositories‏
670 ‎‡a Author's The frameshift signal of HIV-1 involves a potential intramolecular triplex RNA structure‏
670 ‎‡a Author's The highly conserved MraZ protein is a transcriptional regulator in Escherichia coli‏
670 ‎‡a Author's The Toxoplasma gondii cyst wall protein CST1 is critical for cyst wall integrity and promotes bradyzoite persistence.‏
670 ‎‡a Author's The underlying principles of scientific publication.‏
670 ‎‡a Author's Transcriptomic and proteomic dynamics in the metabolism of a diazotrophic cyanobacterium, Cyanothece sp. PCC 7822 during a diurnal light-dark cycle‏
670 ‎‡a Author's Using the gene ontology to enrich biological pathways.‏
909 ‎‡a (orcid) 0000000197779767‏ ‎‡9 1‏
919 ‎‡a frameshiftsignalofhiv1involvesapotentialintramoleculartriplexrnastructure‏ ‎‡A The frameshift signal of HIV-1 involves a potential intramolecular triplex RNA structure‏ ‎‡9 1‏
919 ‎‡a highlyconservedmrazproteinisatranscriptionalregulatorinescherichiacoli‏ ‎‡A The highly conserved MraZ protein is a transcriptional regulator in Escherichia coli‏ ‎‡9 1‏
919 ‎‡a toxoplasmagondiicystwallproteincst1iscriticalforcystwallintegrityandpromotesbradyzoitepersistence‏ ‎‡A The Toxoplasma gondii cyst wall protein CST1 is critical for cyst wall integrity and promotes bradyzoite persistence.‏ ‎‡9 1‏
919 ‎‡a underlyingprinciplesofscientificpublication‏ ‎‡A The underlying principles of scientific publication.‏ ‎‡9 1‏
919 ‎‡a transcriptomicandproteomicdynamicsinthemetabolismofadiazotrophiccyanobacteriumcyanothecesppcc7822duringadiurnallightdarkcycle‏ ‎‡A Transcriptomic and proteomic dynamics in the metabolism of a diazotrophic cyanobacterium, Cyanothece sp. PCC 7822 during a diurnal light-dark cycle‏ ‎‡9 1‏
919 ‎‡a usingthegeneontologytoenrichbiologicalpathways‏ ‎‡A Using the gene ontology to enrich biological pathways.‏ ‎‡9 1‏
919 ‎‡a guidetomicroarrayexperimentsanopenlettertothescientificjournals‏ ‎‡A A guide to microarray experiments-an open letter to the scientific journals‏ ‎‡9 1‏
919 ‎‡a networkinferenceworkflowappliedtovirulencerelatedprocessesinsalmonellatyphimurium‏ ‎‡A A network inference workflow applied to virulence-related processes in Salmonella typhimurium‏ ‎‡9 1‏
919 ‎‡a analysispipelinefortheinferenceofproteinproteininteractionnetworks‏ ‎‡A An analysis pipeline for the inference of protein-protein interaction networks‏ ‎‡9 1‏
919 ‎‡a integratedapproachtopredictivegenomicanalytics‏ ‎‡A An integrated approach to predictive genomic analytics‏ ‎‡9 1‏
919 ‎‡a openletteronmicroarraydatafromthemgedsociety‏ ‎‡A An open letter on microarray data from the MGED Society‏ ‎‡9 1‏
919 ‎‡a overviewofthehadoopmapreducehbaseframeworkanditscurrentapplicationsinbioinformatics‏ ‎‡A An overview of the Hadoop/MapReduce/HBase framework and its current applications in bioinformatics‏ ‎‡9 1‏
919 ‎‡a biologicalnetworkinferenceandanalysisusingsebiniandcabin‏ ‎‡A Biological Network Inference and analysis using SEBINI and CABIN.‏ ‎‡9 1‏
919 ‎‡a bottlenecksandhubsininferrednetworksareimportantforvirulenceinsalmonellatyphimurium‏ ‎‡A Bottlenecks and hubs in inferred networks are important for virulence in Salmonella typhimurium‏ ‎‡9 1‏
919 ‎‡a braininsituhybridizationmapsasasourceforreverseengineeringtranscriptionalregulatorynetworksalzheimersdiseaseinsights‏ ‎‡A Brain in situ hybridization maps as a source for reverse-engineering transcriptional regulatory networks: Alzheimer's disease insights‏ ‎‡9 1‏
919 ‎‡a cellsrespondtodistinctnanoparticlepropertieswithmultiplestrategiesasrevealedbysinglecellrnaseq‏ ‎‡A Cells Respond to Distinct Nanoparticle Properties with Multiple Strategies As Revealed by Single-Cell RNA-Seq.‏ ‎‡9 1‏
919 ‎‡a changesintranslationalefficiencyisadominantregulatorymechanismintheenvironmentalresponseofbacteria‏ ‎‡A Changes in translational efficiency is a dominant regulatory mechanism in the environmental response of bacteria.‏ ‎‡9 1‏
919 ‎‡a co2exposureatpressureimpactsmetabolismandstressresponsesinthemodelsulfatereducingbacteriumdesulfovibriovulgarisstrainhildenborough‏ ‎‡A CO2 exposure at pressure impacts metabolism and stress responses in the model sulfate-reducing bacterium Desulfovibrio vulgaris strain Hildenborough.‏ ‎‡9 1‏
919 ‎‡a computingandapplyingatomicregulonstounderstandgeneexpressionandregulation‏ ‎‡A Computing and Applying Atomic Regulons to Understand Gene Expression and Regulation‏ ‎‡9 1‏
919 ‎‡a coregulationofterpenoidpathwaygenesandpredictionofisopreneproductioninbacillussubtilisusingtranscriptomics‏ ‎‡A Coregulation of Terpenoid Pathway Genes and Prediction of Isoprene Production in Bacillus subtilis Using Transcriptomics‏ ‎‡9 1‏
919 ‎‡a coverimagevolume231number11november‏ ‎‡A Cover Image, Volume 231, Number 11, November 2016.‏ ‎‡9 1‏
919 ‎‡a datastandardsforomicsdatathebasisofdatasharingandreuse‏ ‎‡A Data standards for Omics data: the basis of data sharing and reuse‏ ‎‡9 1‏
919 ‎‡a developmentoftheminimuminformationspecificationforinsituhybridizationandimmunohistochemistryexperimentsmisfishie‏ ‎‡A Development of the Minimum Information Specification for In Situ Hybridization and Immunohistochemistry Experiments (MISFISHIE).‏ ‎‡9 1‏
919 ‎‡a distinctstrainsoftoxoplasmagondiifeaturedivergenttranscriptomesregardlessofdevelopmentalstage‏ ‎‡A Distinct strains of Toxoplasma gondii feature divergent transcriptomes regardless of developmental stage‏ ‎‡9 1‏
919 ‎‡a dnacorrelations‏ ‎‡A DNA correlations‏ ‎‡9 1‏
919 ‎‡a enrichingregulatorynetworksbybootstraplearningusingoptimised5basedgenesimilarityandgenelinksminedfrompubmedabstracts‏ ‎‡A Enriching regulatory networks by bootstrap learning using optimised GO-based gene similarity and gene links mined from PubMed abstracts‏ ‎‡9 1‏
919 ‎‡a evidencesupportingdissimilatoryandassimilatorylignindegradationinenterobacterlignolyticusscf1‏ ‎‡A Evidence supporting dissimilatory and assimilatory lignin degradation in Enterobacter lignolyticus SCF1.‏ ‎‡9 1‏
919 ‎‡a genesetanalysesforinterpretingmicroarrayexperimentsonprokaryoticorganisms‏ ‎‡A Gene set analyses for interpreting microarray experiments on prokaryotic organisms‏ ‎‡9 1‏
919 ‎‡a genomicexpansionofdomainarchaeahighlightsrolesfororganismsfromnewphylainanaerobiccarboncycling‏ ‎‡A Genomic expansion of domain archaea highlights roles for organisms from new phyla in anaerobic carbon cycling.‏ ‎‡9 1‏
919 ‎‡a gestageneexpressionsearchtoolbasedonanovelbayesiansimilaritymetric‏ ‎‡A GEST: a gene expression search tool based on a novel Bayesian similarity metric.‏ ‎‡9 1‏
919 ‎‡a identificationofdifferentialgeneexpressionpatternsafteracuteexposuretohighandlowdosesoflowletionizingradiationinareconstitutedhumanskintissue‏ ‎‡A Identification of Differential Gene Expression Patterns after Acute Exposure to High and Low Doses of Low-LET Ionizing Radiation in a Reconstituted Human Skin Tissue‏ ‎‡9 1‏
919 ‎‡a learningbiologicalnetworksviabootstrappingwithoptimized5basedgenesimilarity‏ ‎‡A Learning biological networks via bootstrapping with optimized go-based gene similarity‏ ‎‡9 1‏
919 ‎‡a microbialcommunitymetabolicmodelingacommunitydatadrivennetworkreconstruction‏ ‎‡A Microbial Community Metabolic Modeling: A Community Data-Driven Network Reconstruction‏ ‎‡9 1‏
919 ‎‡a minimuminformationaboutamicroarrayexperimentmiametowardstandardsformicroarraydata‏ ‎‡A Minimum information about a microarray experiment (MIAME)-toward standards for microarray data‏ ‎‡9 1‏
919 ‎‡a minimuminformationspecificationforinsituhybridizationandimmunohistochemistryexperimentsmisfishie‏ ‎‡A Minimum information specification for in situ hybridization and immunohistochemistry experiments (MISFISHIE)‏ ‎‡9 1‏
919 ‎‡a modelingdynamicregulatoryprocessesinstroke‏ ‎‡A Modeling dynamic regulatory processes in stroke‏ ‎‡9 1‏
919 ‎‡a modelingframeworkforisotopiclabelingofheteronuclearmoieties‏ ‎‡A Modeling framework for isotopic labeling of heteronuclear moieties‏ ‎‡9 1‏
919 ‎‡a networkanalysisoftranscriptomicsexpandsregulatorylandscapesinsynechococcussppcc‏ ‎‡A Network analysis of transcriptomics expands regulatory landscapes in Synechococcus sp. PCC 7002.‏ ‎‡9 1‏
919 ‎‡a networkinferencealgorithmselucidatenrf2regulationofmouselungoxidativestress‏ ‎‡A Network inference algorithms elucidate Nrf2 regulation of mouse lung oxidative stress‏ ‎‡9 1‏
919 ‎‡a pacapinteractionsinthemousebrainimplicationsforbehavioralandotherdisorders‏ ‎‡A PACAP interactions in the mouse brain: implications for behavioral and other disorders.‏ ‎‡9 1‏
919 ‎‡a predictingspeciesresolvedmacronutrientacquisitionduringsuccessioninamodelphototrophicbiofilmusinganintegratedomicsapproach‏ ‎‡A Predicting Species-Resolved Macronutrient Acquisition during Succession in a Model Phototrophic Biofilm Using an Integrated 'Omics Approach‏ ‎‡9 1‏
919 ‎‡a reverseengineeringadverseoutcomepathways‏ ‎‡A Reverse engineering adverse outcome pathways‏ ‎‡9 1‏
919 ‎‡a sebinisoftwareenvironmentforbiologicalnetworkinference‏ ‎‡A SEBINI: Software Environment for BIological Network Inference.‏ ‎‡9 1‏
919 ‎‡a standardsformicroarraydata‏ ‎‡A Standards for microarray data‏ ‎‡9 1‏
919 ‎‡a submissionofmicroarraydatatopublicrepositories‏ ‎‡A Submission of microarray data to public repositories‏ ‎‡9 1‏
943 ‎‡a 201x‏ ‎‡A 2016‏ ‎‡9 1‏
946 ‎‡a b‏ ‎‡9 1‏
996 ‎‡2 BNC|981058512037006706
996 ‎‡2 LC|n 96046692
996 ‎‡2 DE633|pe30032998
996 ‎‡2 LC|nb2020007063
996 ‎‡2 LC|n 86811394
996 ‎‡2 BLBNB|000594196
996 ‎‡2 BNE|XX844657
996 ‎‡2 KRNLK|KAC200604469
996 ‎‡2 ISNI|0000000082795943
996 ‎‡2 LC|n 94037992
996 ‎‡2 ISNI|0000000035502730
996 ‎‡2 ISNI|0000000073318264
996 ‎‡2 LC|no2017042280
996 ‎‡2 LC|nr 95017617
996 ‎‡2 LC|no2014109519
996 ‎‡2 JPG|500003919
996 ‎‡2 ISNI|0000000385039504
996 ‎‡2 DNB|1158629435
996 ‎‡2 NII|DA12757743
996 ‎‡2 DNB|1056501561
996 ‎‡2 SUDOC|126105316
996 ‎‡2 BIBSYS|90157135
996 ‎‡2 BIBSYS|90165167
996 ‎‡2 CAOONL|ncf10311974
996 ‎‡2 JPG|500070187
996 ‎‡2 NII|DA01491101
996 ‎‡2 NUKAT|n 2019016142
996 ‎‡2 LNB|LNC10-000160696
996 ‎‡2 BNF|12777372
996 ‎‡2 PLWABN|9810670516405606
996 ‎‡2 DNB|141595264
996 ‎‡2 NUKAT|n 2019222527
996 ‎‡2 BAV|495_128025
996 ‎‡2 LC|no2022017790
996 ‎‡2 J9U|987007449489605171
996 ‎‡2 CAOONL|ncf11166914
996 ‎‡2 ISNI|0000000041916518
996 ‎‡2 LC|no2010127574
996 ‎‡2 LC|n 2018014811
996 ‎‡2 LC|no2020134612
996 ‎‡2 DNB|139686479
996 ‎‡2 NLA|000035829911
996 ‎‡2 BIBSYS|55848
996 ‎‡2 LC|nb2014019529
996 ‎‡2 NSK|000187261
996 ‎‡2 ISNI|0000000114769003
996 ‎‡2 BIBSYS|97054622
996 ‎‡2 LC|n 84008510
996 ‎‡2 BIBSYS|90511513
996 ‎‡2 BIBSYS|11029165
996 ‎‡2 RERO|A013355184
996 ‎‡2 ISNI|0000000067717883
996 ‎‡2 NII|DA06612189
996 ‎‡2 ISNI|0000000376056011
996 ‎‡2 LC|no2004100463
996 ‎‡2 LC|n 82217027
996 ‎‡2 ISNI|0000000123937152
996 ‎‡2 DNB|1068846933
996 ‎‡2 LIH|LNB:B_c_CO;=BN
996 ‎‡2 J9U|987007386926905171
996 ‎‡2 LC|no2021048906
996 ‎‡2 SUDOC|085990469
996 ‎‡2 BIBSYS|90896566
996 ‎‡2 ISNI|000000002849981X
996 ‎‡2 BIBSYS|90942650
996 ‎‡2 LC|no2018090002
996 ‎‡2 LC|n 86811309
996 ‎‡2 LC|no2009037112
996 ‎‡2 SUDOC|084010371
996 ‎‡2 PLWABN|9810587279805606
996 ‎‡2 NKC|jcu2016898662
996 ‎‡2 NII|DA01119075
996 ‎‡2 NSK|000253107
996 ‎‡2 BIBSYS|90069091
996 ‎‡2 LC|n 81134150
996 ‎‡2 ISNI|0000000027283910
996 ‎‡2 CAOONL|ncf11328810
996 ‎‡2 DNB|139546944
996 ‎‡2 NTA|267571356
996 ‎‡2 J9U|987007337215105171
996 ‎‡2 SUDOC|066007828
996 ‎‡2 NYNYRILM|139525
996 ‎‡2 J9U|987007268718005171
996 ‎‡2 LC|no2010148995
996 ‎‡2 BIBSYS|90194129
996 ‎‡2 LC|n 2017181457
996 ‎‡2 NUKAT|n 00045688
996 ‎‡2 ISNI|0000000024277523
996 ‎‡2 BNF|12422085
996 ‎‡2 SUDOC|08612630X
996 ‎‡2 BIBSYS|11048200
996 ‎‡2 RERO|A012763955
996 ‎‡2 J9U|987007325740505171
996 ‎‡2 CAOONL|ncf10155583
996 ‎‡2 RERO|A003890348
996 ‎‡2 RERO|A003890349
996 ‎‡2 SUDOC|257686460
996 ‎‡2 J9U|987007385810005171
996 ‎‡2 J9U|987007391678205171
996 ‎‡2 LC|no 95027780
996 ‎‡2 RERO|A003890346
996 ‎‡2 ISNI|0000000500259976
996 ‎‡2 J9U|987007429308605171
996 ‎‡2 RERO|A003890345
996 ‎‡2 ISNI|0000000383770723
996 ‎‡2 RERO|A011514269
996 ‎‡2 LC|n 81128182
996 ‎‡2 ISNI|0000000409450817
996 ‎‡2 ISNI|0000000035390169
996 ‎‡2 ISNI|0000000073801993
996 ‎‡2 SIMACOB|39703651
996 ‎‡2 DBC|87097969720552
996 ‎‡2 CAOONL|ncf10233337
996 ‎‡2 ISNI|0000000019767886
996 ‎‡2 BNF|12641497
996 ‎‡2 ISNI|0000000081752730
996 ‎‡2 NUKAT|n 2022063202
996 ‎‡2 BNF|14140437
996 ‎‡2 LC|n 82070100
996 ‎‡2 ISNI|0000000032767629
996 ‎‡2 ISNI|0000000068798435
996 ‎‡2 LC|no2016106088
996 ‎‡2 BIBSYS|90159692
996 ‎‡2 NII|DA02507750
996 ‎‡2 CAOONL|ncf11167761
996 ‎‡2 ISNI|0000000035746460
996 ‎‡2 SUDOC|243386605
996 ‎‡2 ISNI|0000000114577992
996 ‎‡2 PLWABN|9810695672105606
996 ‎‡2 LC|n 86868183
996 ‎‡2 DNB|1240864159
996 ‎‡2 SUDOC|227831756
996 ‎‡2 CAOONL|ncf10030985
996 ‎‡2 LC|nb2012017931
996 ‎‡2 NKC|xx0185115
996 ‎‡2 LIH|LNB:DSZE;=BS
996 ‎‡2 ISNI|0000000071415247
996 ‎‡2 LC|no2014119832
996 ‎‡2 J9U|987007386227405171
996 ‎‡2 LC|no 98034730
996 ‎‡2 PTBNP|205789
996 ‎‡2 NTA|146758811
996 ‎‡2 CAOONL|ncf12134173
996 ‎‡2 DNB|115634975
996 ‎‡2 LC|nb2021007115
996 ‎‡2 RERO|A016740087
996 ‎‡2 CAOONL|ncf11187301
996 ‎‡2 B2Q|0000127153
996 ‎‡2 LC|n 89200274
996 ‎‡2 LC|n 82151896
996 ‎‡2 LC|nb2001048645
996 ‎‡2 DBC|87097969720463
996 ‎‡2 LC|n 82065485
996 ‎‡2 J9U|987007429233205171
996 ‎‡2 ISNI|0000000050772165
996 ‎‡2 LC|no2008144738
996 ‎‡2 LC|nb2002042836
996 ‎‡2 LC|no2019044283
996 ‎‡2 B2Q|0000034939
996 ‎‡2 BNC|981058518805606706
996 ‎‡2 NTA|068682506
996 ‎‡2 BIBSYS|98052199
996 ‎‡2 BAV|495_320419
996 ‎‡2 BIBSYS|90254716
996 ‎‡2 SUDOC|075495856
996 ‎‡2 NTA|182793656
996 ‎‡2 CAOONL|ncf10044299
996 ‎‡2 LC|nb2008020864
996 ‎‡2 LNB|LNC10-000158698
996 ‎‡2 LC|n 00026166
996 ‎‡2 ISNI|000000006652959X
996 ‎‡2 LC|no 98100286
996 ‎‡2 LC|n 81029719
996 ‎‡2 J9U|987007381931105171
996 ‎‡2 LNB|LNC10-000158697
996 ‎‡2 ISNI|0000000075085978
996 ‎‡2 BAV|495_284138
996 ‎‡2 ISNI|0000000043179128
996 ‎‡2 NUKAT|n 98020627
996 ‎‡2 LC|nb 99094908
996 ‎‡2 BNF|14232022
996 ‎‡2 SUDOC|243344813
996 ‎‡2 LC|n 93118992
996 ‎‡2 PTBNP|1788380
996 ‎‡2 LC|n 87128763
996 ‎‡2 RERO|A003890393
996 ‎‡2 RERO|A003890392
996 ‎‡2 RERO|A003890395
996 ‎‡2 RERO|A003890394
996 ‎‡2 ISNI|0000000024258533
996 ‎‡2 BIBSYS|2101247
996 ‎‡2 PLWABN|9810620403505606
996 ‎‡2 ISNI|0000000498752066
996 ‎‡2 LC|nb2014027302
996 ‎‡2 LC|no 94006187
996 ‎‡2 SUDOC|139502181
996 ‎‡2 LC|no2017147615
996 ‎‡2 NUKAT|n 2018247997
996 ‎‡2 SUDOC|030173442
996 ‎‡2 ISNI|000000002347383X
996 ‎‡2 BNE|XX1297176
996 ‎‡2 ISNI|0000000106413058
996 ‎‡2 NTA|074209647
996 ‎‡2 CAOONL|ncf10260929
996 ‎‡2 LC|n 95047155
996 ‎‡2 ISNI|0000000374641874
996 ‎‡2 LC|no2012023601
996 ‎‡2 LC|no2021137373
996 ‎‡2 BIBSYS|99024007
996 ‎‡2 SUDOC|050470051
996 ‎‡2 NTA|072767782
996 ‎‡2 LC|n 87812994
996 ‎‡2 NUKAT|n 2012152891
996 ‎‡2 LC|n 79151606
996 ‎‡2 CAOONL|ncf10083049
996 ‎‡2 DNB|1056529598
996 ‎‡2 LC|no2001046704
996 ‎‡2 NTA|072794240
996 ‎‡2 BNF|12164409
996 ‎‡2 PTBNP|142498
996 ‎‡2 LC|n 80134709
996 ‎‡2 J9U|987010188911805171
996 ‎‡2 ISNI|0000000017002169
996 ‎‡2 LC|n 93069636
996 ‎‡2 SUDOC|192673149
996 ‎‡2 J9U|987007272664105171
996 ‎‡2 NDL|00458417
996 ‎‡2 BIBSYS|90198200
996 ‎‡2 ISNI|000000004865563X
996 ‎‡2 NTA|392070065
996 ‎‡2 NII|DA12055892
996 ‎‡2 RERO|A024711362
996 ‎‡2 LC|n 2010055169
996 ‎‡2 LC|n 77015260
996 ‎‡2 J9U|987007452566105171
996 ‎‡2 BIBSYS|90797907
996 ‎‡2 NII|DA08833021
996 ‎‡2 LC|no2008017294
996 ‎‡2 BIBSYS|90069327
996 ‎‡2 ISNI|0000000038574940
996 ‎‡2 LC|nb2009031072
996 ‎‡2 LC|no2022003957
996 ‎‡2 SUDOC|079131514
996 ‎‡2 ISNI|0000000080941521
996 ‎‡2 LC|n 82209344
996 ‎‡2 NTA|371245125
996 ‎‡2 SUDOC|244903344
996 ‎‡2 NTA|155735551
996 ‎‡2 RERO|A005701743
996 ‎‡2 BNC|981058518909406706
997 ‎‡a 0 0 lived 0 0‏ ‎‡9 1‏