about
Use of 16S rRNA and rpoB genes as molecular markers for microbial ecology studiesAbility of Pseudoalteromonas tunicata to colonize natural biofilms and its effect on microbial community structure.Host specificity in marine sponge-associated bacteria, and potential implications for marine microbial diversity.Effects on the function of three trophic levels in marine plankton communities under stress from the antifouling compound zinc pyrithione.Pyrene toxicity is affected by the nutrient status of a marine sediment community: implications for risk assessment.rpoB-based microbial community analysis avoids limitations inherent in 16S rRNA gene intraspecies heterogeneity.Towards a renewed research agenda in ecotoxicology.PAH effects on meio- and microbial benthic communities strongly depend on bioavailability.Real-time quantitative PCR for assessment of abundance of Pseudoalteromonas species in marine samples.Local contamination in relation to population genetic diversity and resilience of an arctic marine amphipod.Distribution patterns of particulate trace metals in the water column and nepheloid layer of the Gulf of Riga.Endocrine-disrupting effects of compounds in Danish streams.Aquatic toxicity of PAHs and PAH mixtures at saturation to benthic amphipods: linking toxic effects to chemical activity.Combined effects of pyrene and UV-light on algae and bacteria in an arctic sediment.The amphipod Orchomenella pinguis--a potential bioindicator for contamination in the Arctic.Effects of zinc pyrithione and copper pyrithione on microbial community function and structure in sediments.Effects of tributyltin (TBT) on the seagrass Ruppia maritima.Induced tolerance in situ to chronically PAH exposed ammonium oxidizers.A fault tree model to assess probability of contaminant discharge from shipwrecks.Abnormalities in eelpout Zoarces viviparus upon chemical exposure.Direct and indirect effects of the herbicides Glyphosate, Bentazone and MCPA on eelgrass (Zostera marina).The effect of TBT on the structure of a marine sediment comunity--a Boxcosm study.Multivariate optimization of polymerase chain reaction for microbial community analysis.Sediments indicate the continued use of banned antifouling compounds.Improvements for comparative analysis of changes in diversity of microbial communities using internal standards in PCR-DGGE.Plankton stress responses from PAH exposure and nutrient enrichmentFunctional and structural responses of marine plankton food web to pyrene contaminationBenthic Foraminiferal Tolerance to Tri-n-Butyltin (TBT) Pollution in an Experimental MesocosmMolecular investigation of the distribution, abundance and diversity of the genus Pseudoalteromonas in marine samplesSeasonal variations in the effect of zinc pyrithione and copper pyrithione on pelagic phytoplankton communitiesThe use of (14)C tracer technique to assess the functional response of zooplankton community grazing to toxic impactEnvironmental fate of the antifouling compound zinc pyrithione in seawaterMeiofaunal and bacterial community response to diesel additions in a microcosm studyEvaluating the needs of risk assessment methods of potentially polluting shipwrecksLead isotopes in marine surface sediments reveal historical use of leaded fuel
P50
Q24676105-45C40719-0F34-4075-A0F2-6AAA83BD0838Q30984869-826D7331-6721-4370-9AAE-696AC4D4ABE1Q31039805-5442B981-201D-48E1-8363-9F2E127E294FQ33229409-9016644D-0B29-4E1B-AC64-020FC50E07FCQ33498286-B97FEB62-7267-4699-931C-FC6482FBEE80Q33987399-54FA2AA2-D0A9-41D2-9224-D963D244A569Q34052846-4BC1E103-9F3D-4433-97A5-5B7423F0E29AQ35064614-81554DC3-8A94-4BD1-83A2-AEDA161DEBCDQ37317996-A4280E2C-78DE-4840-A30B-C48D49B08F3CQ39292639-857E1BE7-7B37-4492-9673-A46C1D571358Q42024950-C183FA40-9C4E-41E4-9931-FECC8701AF62Q43307803-637B110F-2BDB-4982-A97F-1F4E786E725DQ45009379-389C7857-33DB-463E-BDD8-BC902C6E79D0Q45165838-01CDA04B-F276-416F-A422-1E20DF3A53E6Q45732307-C61C60FB-7593-420F-A3FE-BA50425ADB6DQ47737159-8004B110-A53B-440B-8EEC-BC50855616B8Q47914182-DA4A02FC-5344-4A4A-83ED-C2A800EF2B89Q48027962-1C57E097-E38E-4DD6-8220-1955682842DAQ51035289-C6F9B22F-87D7-4053-B0D6-32EA1CD62BC2Q51198825-770F5D0E-FC10-45D2-A83A-E7E922DBD334Q51712563-42BD358D-6036-470A-A341-DC59238A3252Q52017758-48244D1B-5F01-4D11-9C74-7972B62B9E89Q52959290-EF3E5644-D088-44B0-897A-3956F0BE8CBFQ53076597-A57FAE5E-B691-4339-8328-A72EDC9B637FQ54628389-674B41C3-8E75-47BC-AF18-927CD9BA42A8Q56962033-25BC7090-FFC8-4128-85AA-B6FAA25B30F3Q56962054-E13F98C0-EEF7-4F96-864E-510CB55BB215Q57974156-16786153-B6C6-48B3-9E08-E8A7AA997CF9Q58056374-B8964882-A70A-4BF8-924B-394326EB3549Q80355527-A07D9C72-393F-4601-907F-6C1E8FCF589EQ82136901-F3F243B6-299C-40C3-8857-4596E9A21EE1Q82416119-8916395A-9F51-4F09-A196-B5464A903A09Q83241346-45CCA175-5CD3-43F8-8026-9941C9EA2ED9Q86296917-A4C3C2A3-C7FB-49A6-98C5-A29D9EBB6920Q87405710-FA6BF5D6-9A4F-41E6-8716-6F087ACDC2FC
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Ingela Dahllöf
@ast
Ingela Dahllöf
@en
Ingela Dahllöf
@es
Ingela Dahllöf
@nl
type
label
Ingela Dahllöf
@ast
Ingela Dahllöf
@en
Ingela Dahllöf
@es
Ingela Dahllöf
@nl
prefLabel
Ingela Dahllöf
@ast
Ingela Dahllöf
@en
Ingela Dahllöf
@es
Ingela Dahllöf
@nl
P106
P1153
6602069600
P31
P496
0000-0002-0777-5971