FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2020296943> ?p ?o ?g. }

• W2020296943 endingPage "429" @default.
• W2020296943 startingPage "416" @default.
• W2020296943 abstract "The cuticular and internal lipid composition in Calliphora vomitoria larvae, pupae, and male and female adults was studied. The free fatty acid (FA) compositions of the lipids were chemically characterized using gas chromatography (GC) and gas chromatography-electron impact mass spectrometry (GC-MS). Analyses of cuticular extracts from larvae, pupae, and male and female adults revealed that the carbon numbers of the acids ranged from C7:0 to C22:0, from C8:0 to C24:0, from C7:0 to C24:0 and from C7:0 to C22:0 respectively. The internal lipids of C. vomitoria larvae, pupae, male and female adults contained FAs ranging from C8:0 to C20:0, from C9:0 to C22:0, from C8:0 to C24:0 and from C9:0 to C22:0 respectively. Nine FAs with odd-numbered carbon chains from C7:0 to C21:0 were identified in the cuticular lipids of the larvae. The internal lipids of C. vomitoria larvae contained 8 odd-numbered FAs ranging from C9:0 to C19:0. Eight odd-numbered FAs from C9:0 to C21:0 were identified in the cuticular and internal lipids of pupae, while nine such FAs were found in the cuticular lipids of male and female adults. The internal lipids of adult males and females respectively contained nine and seven odd-numbered FAs, while both larvae and pupae contained eight such compounds. Eight unsaturated FAs were identified in the cuticular lipids of larvae, adult males and females and also in the internal lipids of females. Seven unsaturated FAs were identified in the cuticular lipids of pupae. The internal lipids of larvae, pupae and males contained 10, 11 and 12 unsaturated FAs respectively. Developmental changes were found both in the amounts of extracted cuticular and internal FAs and in their profiles. Four cuticular FAs (C7:0, C9:0, C10:0 and C15:1), identified as being male-specific, were either absent in the female cuticle or present there only in trace amounts. Cuticular and internal extracts obtained from larvae, pupae, adult males and females were tested for their potential antimicrobial activity. The minimal inhibitory concentrations of extracts against reference strains of bacteria and fungi were determined. Antimicrobial activity was the strongest against Gram-positive bacteria; Gram-negative bacteria, on the other hand, turned out to be resistant to all the lipids tested. Overall, the activities of the internal lipids were stronger. All the lipid extracts were equally effective against all the fungal strains examined. In contrast, crude extracts containing both cuticular and internal lipids displayed no antifungal activity against the entomopathogenic fungus Conidiobolus coronatus, which efficiently killed adult flies, but not larvae or pupae." @default.
• W2020296943 created "2016-06-24" @default.
• W2020296943 creator A5002503784 @default.
• W2020296943 creator A5006090306 @default.
• W2020296943 creator A5011383621 @default.
• W2020296943 creator A5029589805 @default.
• W2020296943 creator A5033580359 @default.
• W2020296943 creator A5080038571 @default.
• W2020296943 creator A5091880331 @default.
• W2020296943 date "2013-04-01" @default.
• W2020296943 modified "2023-10-03" @default.
• W2020296943 title "Free fatty acids in the cuticular and internal lipids of Calliphora vomitoria and their antimicrobial activity" @default.
• W2020296943 cites W1673479458 @default.
• W2020296943 cites W1961993092 @default.
• W2020296943 cites W1966452648 @default.
• W2020296943 cites W1980805735 @default.
• W2020296943 cites W1982194624 @default.
• W2020296943 cites W1986853025 @default.
• W2020296943 cites W1990795993 @default.
• W2020296943 cites W1992667608 @default.
• W2020296943 cites W1994056848 @default.
• W2020296943 cites W1998507660 @default.
• W2020296943 cites W2000306757 @default.
• W2020296943 cites W2007031506 @default.
• W2020296943 cites W2012532867 @default.
• W2020296943 cites W2015308149 @default.
• W2020296943 cites W2016587329 @default.
• W2020296943 cites W2023756776 @default.
• W2020296943 cites W2024578773 @default.
• W2020296943 cites W2031836217 @default.
• W2020296943 cites W2036062140 @default.
• W2020296943 cites W2037724936 @default.
• W2020296943 cites W2038599207 @default.
• W2020296943 cites W2039187492 @default.
• W2020296943 cites W2039984568 @default.
• W2020296943 cites W2043865262 @default.
• W2020296943 cites W2061219853 @default.
• W2020296943 cites W2066946045 @default.
• W2020296943 cites W2069062747 @default.
• W2020296943 cites W2069315080 @default.
• W2020296943 cites W2069817767 @default.
• W2020296943 cites W2070373609 @default.
• W2020296943 cites W2075634839 @default.
• W2020296943 cites W2093567515 @default.
• W2020296943 cites W2106875513 @default.
• W2020296943 cites W2109742887 @default.
• W2020296943 cites W2111904961 @default.
• W2020296943 cites W2136511195 @default.
• W2020296943 cites W2141712686 @default.
• W2020296943 cites W2176975656 @default.
• W2020296943 cites W2188799256 @default.
• W2020296943 cites W2460145869 @default.
• W2020296943 cites W2761376902 @default.
• W2020296943 cites W315019117 @default.
• W2020296943 doi "https://doi.org/10.1016/j.jinsphys.2013.02.001" @default.
• W2020296943 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/23419415" @default.
• W2020296943 hasPublicationYear "2013" @default.
• W2020296943 type Work @default.
• W2020296943 sameAs 2020296943 @default.
• W2020296943 citedByCount "43" @default.
• W2020296943 countsByYear W20202969432013 @default.
• W2020296943 countsByYear W20202969432014 @default.
• W2020296943 countsByYear W20202969432015 @default.
• W2020296943 countsByYear W20202969432016 @default.
• W2020296943 countsByYear W20202969432017 @default.
• W2020296943 countsByYear W20202969432018 @default.
• W2020296943 countsByYear W20202969432019 @default.
• W2020296943 countsByYear W20202969432020 @default.
• W2020296943 countsByYear W20202969432021 @default.
• W2020296943 countsByYear W20202969432022 @default.
• W2020296943 countsByYear W20202969432023 @default.
• W2020296943 crossrefType "journal-article" @default.
• W2020296943 hasAuthorship W2020296943A5002503784 @default.
• W2020296943 hasAuthorship W2020296943A5006090306 @default.
• W2020296943 hasAuthorship W2020296943A5011383621 @default.
• W2020296943 hasAuthorship W2020296943A5029589805 @default.
• W2020296943 hasAuthorship W2020296943A5033580359 @default.
• W2020296943 hasAuthorship W2020296943A5080038571 @default.
• W2020296943 hasAuthorship W2020296943A5091880331 @default.
• W2020296943 hasConcept C173758957 @default.
• W2020296943 hasConcept C175734852 @default.
• W2020296943 hasConcept C2776732978 @default.
• W2020296943 hasConcept C31903555 @default.
• W2020296943 hasConcept C543025807 @default.
• W2020296943 hasConcept C55493867 @default.
• W2020296943 hasConcept C59822182 @default.
• W2020296943 hasConcept C86803240 @default.
• W2020296943 hasConceptScore W2020296943C173758957 @default.
• W2020296943 hasConceptScore W2020296943C175734852 @default.
• W2020296943 hasConceptScore W2020296943C2776732978 @default.
• W2020296943 hasConceptScore W2020296943C31903555 @default.
• W2020296943 hasConceptScore W2020296943C543025807 @default.
• W2020296943 hasConceptScore W2020296943C55493867 @default.
• W2020296943 hasConceptScore W2020296943C59822182 @default.
• W2020296943 hasConceptScore W2020296943C86803240 @default.
• W2020296943 hasIssue "4" @default.
• W2020296943 hasLocation W20202969431 @default.
• W2020296943 hasLocation W20202969432 @default.

• next