BACKGROUND: Field and tunnel cage studies were undertaken to determine the extent to which honey bees foraging on citrus blossoms were exposed to imidacloprid and its metabolites when citrus trees were treated with soil applications of the insecticide. Residues were measured by LC/MS/MS in nectar and pollen samples from trees treated up to 232 days prior to bloom. RESULTS: Imidacloprid, imidacloprid olefin and 5-hydroxy imidacloprid were detected in nectar and pollen sampled from the flowers of citrus trees treated with imidacloprid up to 232 days prior to bloom. In tunnel studies, where foraging was restricted exclusively to citrus, imidacloprid residues in nectar extracted from flowers and from bee crops were similar (<10 ng mL(-1) ) and below the established no-observed-effects limit; however, the residue levels were about threefold higher in nectar sampled from comb. Concentrations of imidacloprid in nectar were higher in trees treated with higher application rates. CONCLUSIONS: Imidacloprid and its metabolites were detected in the nectar and pollen of citrus trees treated up to 232 days prior to the onset of bloom. However, based on published bioassay data, the imidacloprid concentrations in the floral nectar did not surpass levels that would compromise foraging activity under normal use conditions for imidacloprid. Further research is needed to assess the impact of elevated levels of imidacloprid within stored nectar in the comb.
BACKGROUND: Field and tunnel cage studies were undertaken to determine the extent to which honey bees foraging on citrus blossoms were exposed to imidacloprid and its metabolites when citrus trees were treated with soil applications of the insecticide. Residues were measured by LC/MS/MS in nectar and pollen samples from trees treated up to 232 days prior to bloom. RESULTS:Imidacloprid, imidacloprid olefin and 5-hydroxy imidacloprid were detected in nectar and pollen sampled from the flowers of citrus trees treated with imidacloprid up to 232 days prior to bloom. In tunnel studies, where foraging was restricted exclusively to citrus, imidacloprid residues in nectar extracted from flowers and from bee crops were similar (<10 ng mL(-1) ) and below the established no-observed-effects limit; however, the residue levels were about threefold higher in nectar sampled from comb. Concentrations of imidacloprid in nectar were higher in trees treated with higher application rates. CONCLUSIONS:Imidacloprid and its metabolites were detected in the nectar and pollen of citrus trees treated up to 232 days prior to the onset of bloom. However, based on published bioassay data, the imidacloprid concentrations in the floral nectar did not surpass levels that would compromise foraging activity under normal use conditions for imidacloprid. Further research is needed to assess the impact of elevated levels of imidacloprid within stored nectar in the comb.
Authors: J-M Bonmatin; C Giorio; V Girolami; D Goulson; D P Kreutzweiser; C Krupke; M Liess; E Long; M Marzaro; E A D Mitchell; D A Noome; N Simon-Delso; A Tapparo Journal: Environ Sci Pollut Res Int Date: 2014-08-07 Impact factor: 4.223
Authors: Sébastien Kessler; Erin Jo Tiedeken; Kerry L Simcock; Sophie Derveau; Jessica Mitchell; Samantha Softley; Jane C Stout; Geraldine A Wright Journal: Nature Date: 2015-04-22 Impact factor: 49.962
Authors: Baida Alshukri; Federica Astarita; Mushtaq Al-Esawy; Hesham Mohamed El Sayed Abd El Halim; Francesco Pennacchio; Angharad Margaret Roscoe Gatehouse; Martin Gethin Edwards Journal: Pest Manag Sci Date: 2019-07-29 Impact factor: 4.845
Authors: Miguel Calvo-Agudo; Joel González-Cabrera; Yolanda Picó; Pau Calatayud-Vernich; Alberto Urbaneja; Marcel Dicke; Alejandro Tena Journal: Proc Natl Acad Sci U S A Date: 2019-08-05 Impact factor: 11.205