about
Geographic selection bias of occurrence data influences transferability of invasive Hydrilla verticillata distribution models.Confronting species distribution model predictions with species functional traits.Controls on eDNA movement in streams: Transport, Retention, and Resuspension.Weed risk assessment for aquatic plants: modification of a New Zealand system for the United States.Validation of eDNA surveillance sensitivity for detection of Asian carps in controlled and field experiments.The room temperature preservation of filtered environmental DNA samples and assimilation into a phenol-chloroform-isoamyl alcohol DNA extraction.Estimating relative risk of within-lake aquatic plant invasion using combined measures of recreational boater movement and habitat suitability.The use of environmental DNA in invasive species surveillance of the Great Lakes commercial bait trade.Quantifying environmental DNA signals for aquatic invasive species across multiple detection platforms.Improving confidence in environmental DNA species detection.Quantification of mesocosm fish and amphibian species diversity via environmental DNA metabarcoding.Estimating species richness using environmental DNA.Conservation in a cup of water: estimating biodiversity and population abundance from environmental DNA.Application of random effects to the study of resource selection by animals.The roles of complement receptor 3 and Fcγ receptors during Leishmania phagosome maturation.Modelling the transport of environmental DNA through a porous substrate using continuous flow-through column experiments.Environmental conditions influence eDNA persistence in aquatic systems.Influence of Stream Bottom Substrate on Retention and Transport of Vertebrate Environmental DNA.Using Environmental DNA for Invasive Species Surveillance and Monitoring.Chance establishment for sexual, semelparous species: overcoming the Allee effect.Waiting for invasions: a framework for the arrival of nonindigenous species.Predicting invasion risk using measures of introduction effort and environmental niche models.A sensitive environmental DNA (eDNA) assay leads to new insights on Ruffe (Gymnocephalus cernua) spread in North AmericaRisk Analysis and Bioeconomics of Invasive Species to Inform Policy and ManagementActive and passive environmental DNA surveillance of aquatic invasive speciesMeta-genomic surveillance of invasive species in the bait tradeDetection of Asian carp DNA as part of a Great Lakes basin-wide surveillance programEurasian watermilfoil fitness loss and invasion potential following desiccation during simulated overland transportGlobal Introductions of Crayfishes: Evaluating the Impact of Species Invasions on Ecosystem ServicesInvestigating diversity of pathogenic microbes in commercial bait trade water“Sight-unseen” detection of rare aquatic species using environmental DNAGrass carp in the Great Lakes region: establishment potential, expert perceptions, and re-evaluation of experimental evidence of ecological impactIdentifying Movement States From Location Data Using Cluster AnalysisParticle size distribution and optimal capture of aqueous macrobial eDNAViability of Aquatic Plant Fragments following DesiccationInferring linear feature use in the presence of GPS measurement errorFish community assessment with eDNA metabarcoding: effects of sampling design and bioinformatic filteringDetecting Southern California’s White Sharks With Environmental DNAStrong Evidence for an Intraspecific Metabolic Scaling Coefficient Near 0.89 in FishMeasuring global fish species richness with eDNA metabarcoding
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researcher ORCID ID = 0000-0002-8074-3466
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Christopher L. Jerde
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Christopher L. Jerde
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Christopher L. Jerde
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Christopher L. Jerde
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Christopher L. Jerde
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Christopher L. Jerde
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Christopher Jerde
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Christopher L Jerde
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Christopher L. Jerde
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Christopher L. Jerde
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Christopher L. Jerde
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Christopher L. Jerde
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0000-0002-8074-3466