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dc.contributor.authorBRAUER, Jonathan I.
dc.contributor.authorMAKAMA, Zakari
dc.contributor.authorBONIFAY, Vincent
dc.contributor.authorKAUFMAN, Eric D.
dc.contributor.authorBEECH, Iwona B.
dc.contributor.authorSUNNER, Jan
dc.contributor.authorAydin, Egemen
dc.date.accessioned2021-03-05T22:00:22Z
dc.date.available2021-03-05T22:00:22Z
dc.date.issued2015
dc.identifier.citationBRAUER J. I. , MAKAMA Z., BONIFAY V., Aydin E., KAUFMAN E. D. , BEECH I. B. , SUNNER J., "Mass spectrometric metabolomic imaging of biofilms on corroding steel surfaces using laser ablation and solvent capture by aspiration", BIOINTERPHASES, cilt.10, 2015
dc.identifier.issn1934-8630
dc.identifier.otherav_db86db7c-e488-45be-b664-b9233aed4c50
dc.identifier.othervv_1032021
dc.identifier.urihttp://hdl.handle.net/20.500.12627/144715
dc.identifier.urihttps://doi.org/10.1116/1.4906744
dc.description.abstractAmbient laser ablation and solvent capture by aspiration (LASCA) mass spectrometric imaging was combined with metabolomics high-performance liquid chromatography (HPLC) mass spectrometry analysis and light profilometry to investigate the correlation between chemical composition of marine bacterial biofilms on surfaces of 1018 carbon steel and corrosion damage of steel underneath the biofilms. Pure cultures of Marinobacter sp. or a wild population of bacteria present in coastal seawater served as sources of biofilms. Profilometry data of biofilm-free surfaces demonstrated heterogeneous distributions of corrosion damage. LASCA data were correlated with areas on the coupons varying in the level of corrosion attack, to reveal differences in chemical composition within biofilm regions associated with corroding and corrosion-free zones. Putative identification of selected compounds was carried out based on HPLC results and subsequent database searches. This is the first report of successful ambient chemical and metabolomic imaging of marine biofilms on corroding metallic materials. The metabolic analysis of such biofilms is challenging due to the presence in the biofilm of large amounts of corrosion products. However, by using the LASCA imaging interface, images of more than 1000 ions (potential metabolites) are generated, revealing striking heterogeneities within the biofilm. In the two model systems studied here, it is found that some of the patterns observed in selected ion images closely correlate with the occurrence and extent of corrosion in the carbon steel substrate as revealed by profilometry, while others do not. This approach toward the study of microbially influenced corrosion (MIC) holds great promise for approaching a fundamental understanding of the mechanisms involved in MIC. (C) 2015 American Vacuum Society.
dc.language.isoeng
dc.subjectMühendislik ve Teknoloji
dc.subjectSağlık Bilimleri
dc.subjectTemel Tıp Bilimleri
dc.subjectBİYOFİZİK
dc.subjectBiyoloji ve Biyokimya
dc.subjectYaşam Bilimleri (LIFE)
dc.subjectMALZEME BİLİMİ, BİYOMATERYAL
dc.subjectMalzeme Bilimi
dc.subjectMühendislik, Bilişim ve Teknoloji (ENG)
dc.subjectBiyofizik
dc.subjectBiyokimya
dc.subjectYaşam Bilimleri
dc.subjectTemel Bilimler
dc.subjectTıp
dc.titleMass spectrometric metabolomic imaging of biofilms on corroding steel surfaces using laser ablation and solvent capture by aspiration
dc.typeMakale
dc.relation.journalBIOINTERPHASES
dc.contributor.departmentUniversity of Oklahoma System , ,
dc.identifier.volume10
dc.identifier.issue1
dc.contributor.firstauthorID103903


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