about
The multicolored Asian lady beetle, Harmonia axyridis: a review of its biology, uses in biological control, and non-target impactsAlien predators and amphibian declines: review of two decades of science and the transition to conservationMammal invaders on islands: impact, control and control impact.A review of the species of Mesopolobus (Chalcidoidea: Pteromalidae) associated with Ceutorhynchus (Coleoptera: Curculionidae) host-species of European origin.Exploiting Allee effects for managing biological invasions.Weed-biocontrol insects reduce native-plant recruitment through second-order apparent competition.Augmentative biocontrol in natural marine habitats: persistence, spread and non-target effects of the sea urchin Evechinus chloroticus.An invasive species facilitates the recovery of salt marsh ecosystems on Cape Cod.Tailoring biocontrol to maximize top-down effects: on the importance of underlying site fertility.Intraguild Interactions of Native and Introduced Coccinellids: The Decline of a Flagship Species.Biotic Resistance to an Alien Amphibian: Larval Competition between Japanese Frogs and Invasive Cane Toads.Presence of Native Prey Does Not Divert Predation on Exotic Pests by Harmonia axyridis in Its Indigenous Range.Survivorship and feeding preferences among size classes of outplanted sea urchins, Tripneustes gratilla, and possible use as biocontrol for invasive alien algae.Evolution and biological control.Evolving while invading: rapid adaptive evolution in juvenile development time for a biological control organism colonizing a high-elevation environment.Spillover of a biological control agent (Chrysolina quadrigemina) onto native St. Johnswort (Hypericum punctatum).What magnitude are observed non-target impacts from weed biocontrol?Mitigating amphibian chytridiomycosis with bioaugmentation: characteristics of effective probiotics and strategies for their selection and use.Demographic models inform selection of biocontrol agents for garlic mustard (Alliaria petiolata).Implicating an introduced generalist parasitoid in the invasive browntail moth's enigmatic demise.Manipulating risk communication: Value predispositions shape public understandings of invasive species science in Hawaii.Trait-mediated interactions and lifetime fitness of the invasive plant Centaurea solstitialis.Natural Parasitism in Fruit Fly (Diptera: Tephritidae) Populations in Disturbed Areas Adjacent to Commercial Mango Orchards in Chiapas and Veracruz, Mexico.Fungicidal activity of slow-release P(3HB)/TEB formulations in wheat plant communities infected by Fusarium moniliforme.Ecological, behavioral, and genetic factors influencing the recombinant control of invasive pests.Weak founder effect signal in a recent introduction of Caribbean Anolis.Infection success in novel hosts: an experimental and phylogenetic study of Drosophila-parasitic nematodes.Intraguild predation and successful invasion by introduced ladybird beetles.The Control of Biological Invasions in the World's OceansEffects of temperature on the establishment potential in the U.K. of the non-native glasshouse biocontrol agent Macrolophus caliginosusHABITAT DISPLACEMENT OF NORTH AMERICAN LADYBIRDS BY AN INTRODUCED SPECIESBenefits and risks of exotic biological control agentsCo-occurrence and reproductive synchrony do not ensure hybridization between an alien tunicate and its interfertile native congenerPrevalence of Aquatic Introduced Species Prevention Protocols at U.S. College and University Fisheries ProgramsA genetic approach to the origin of Millepora sp. in the eastern AtlanticEffect of Rhabdias pseudosphaerocephala on prey consumption of free-ranging cane toads (Rhinella marina) during Australian tropical wet seasonsTyphoid Mary in the frogpond: can we use native frogs to disseminate a lungworm biocontrol for invasive cane toads?Fighting pathophobia: how to construct constructive public engagement with biocontrol for nature without augmenting public fearsCarnivore mollusks as natural enemies of invasive land flatwormsBiotic interactions between Eriopis connexa and Hippodamia variegata, a native and an exotic coccinellid species associated with alfalfa fields in Chile
P2860
Q24562096-46CE6ECA-F81B-4C6F-888F-13A95937C27FQ29032155-B8DBC2EF-7912-4314-9ABC-EB891721E393Q31011851-2DAEE18E-666B-4DBA-A70C-47110F4E363EQ33291469-5BE38950-A8F2-42FF-92EF-B5C51AD34557Q33850255-777A1491-2AF7-4313-AC12-88454D337841Q34820156-48AF164E-F12D-4252-8E14-03457FEC6C32Q35048972-184C93FF-0EDF-447A-8A9A-9120A6127E93Q35054289-2E62E3EF-A3FF-4438-9954-16D69009C63AQ35740631-EDECD183-EBD2-447B-9D75-AEEB23BD137EQ35756007-E93A6ACB-7823-408E-B4AF-D9ADDCD5337FQ36038186-28E7D228-77B2-45A9-8737-791125609696Q36071312-19B9C4A7-0A56-4D4E-A20A-497103861285Q36083497-AEFC186A-286A-4F6B-A3F6-D0E55C54918AQ36125894-1E002385-3103-414B-8B3A-80E9AD443520Q36125938-21D182C7-CAD9-45F2-83CD-49FCDB15C917Q36778429-D9FC383C-2477-4142-9329-0B9C175885E0Q37472836-EE24EA79-4690-4ED6-BE83-97455BDF1B6FQ38085710-7F492EB0-F04F-4E56-BA90-F4FBD21CE1A7Q40254155-D57B59E6-BA7A-4140-A79E-E7034A06CF12Q42035549-425DA197-D04D-4D78-A5A0-AF058DD1289FQ45783826-1E092FE5-5F8A-4634-9716-A3BB4A2B5863Q46057078-103DE9CB-BDE3-4BFC-9B89-84A82FB3592DQ46599761-80F5DF77-B52B-4DD6-B735-16EC551F3C01Q50092118-C773542C-1D67-48B7-83A8-164468D1E4E0Q51179975-7A72C1B9-89AE-43DD-84AE-CFA411564F60Q51694077-A2E64628-E27A-4DB5-9631-F5089E3F510DQ52605227-3B14ECF7-BD20-475B-AD50-51BD23271344Q52648605-6E1E42F3-A16D-468D-B5BF-B82DC619AEA8Q55845416-3807BB42-FAD9-44F9-9633-5C60AD13440EQ55869598-09C385A9-1FA1-43AE-BF80-1F3D4C3FBA7FQ55870719-21123A52-D824-4DD3-93D7-E36345231F1EQ56019927-1F0F7DB9-1CF2-4A4A-B3AC-63A627D34DDDQ56419262-85813593-CB74-46F7-A8BC-69C1EC8D0E71Q56425877-0FFB247D-5340-4AF5-8AE5-C81037DF0648Q56434147-751E485C-6DA7-404B-8B1B-5AD43CDC0B71Q56453189-0785CFF1-28C9-422F-88E9-564AE91662FCQ56529471-46A4D957-2594-424E-B581-D4F0FC9C5815Q56567647-7B499EF7-881E-4B94-8A4A-03814857BE15Q56588386-B547B178-8D22-4225-AD8A-7DD489BD6832Q56605725-0AF06321-6DD7-40BB-9ABB-8FC0F6BB4FFB
P2860
description
im Oktober 1996 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в жовтні 1996
@uk
name
How Risky is Biological Control?
@en
How Risky is Biological Control?
@nl
type
label
How Risky is Biological Control?
@en
How Risky is Biological Control?
@nl
prefLabel
How Risky is Biological Control?
@en
How Risky is Biological Control?
@nl
P356
P1433
P1476
How Risky is Biological Control?
@en
P2093
Daniel Simberloff
Peter Stiling
P304
P356
10.2307/2265693
P407
P577
1996-10-01T00:00:00Z