Coexistence of Biotech and Non-biotech Crops

The database contains 337 references relating to the Safety and Benefits of Biotechnology and "Maize".

References relating to "Maize":

  1. Coexistence of Biotech and Non-biotech Crops
    (2020)
  2. Over expression of zmm28 increases maize grain yield in the field
    (2019) Wu J, Lawit SJ, Weers B, Sun J, Mongar N, Van Hemert J, Melo R, Meng X, Rupe M, Clapp J, Huag K, et al.
  3. Effect of Bt Corn (Bt 38) Cultivation on Community Structure of Collembola
    (2020) Chang L, Song X, Wang B, Wu D, Reddy GVP
  4. Ecotoxicological effects of transgenic mCry1Ac maize (BT799) on zebrafish
    (2019) Dong SS, Zhang DN, Zhang ZH, Yu CG, Liu Y, Zhao HM, Wang CY
  5. Genetically modified (GM) crop use in Colombia: farm level economic and environmental contributions
    (2020) Brookes G
  6. Effect of Cry1Ie Bt Maize on Carbon Source Metabolism of Rhizosphere Microorganisms
    (2019) Liang J, Xin L, Luan Y, Song X, Zhang Z
  7. Species Richness and Community Composition of Ants and Beetles in Bt and non-Bt Maize Fields
    (2019) Fernandes MG, Costa EN, Dutra CC, Raizer J
  8. No impact of transgenic cry1Ie maize on the diversity, abundance and composition of soil fauna in a 2-year field trial
    (2019) Fan C, Wu F, Dong J, Wang B, Yin J, Song X
  9. Abundance of Non-Target Predators in Genetically Modified Corn
    (2019) Hernández-Juàrez A, Aguirre LA, Cerna E, Flores M, Frias GA, Landeros J, Ochoa-Fernandez R
  10. Improved folate accumulation in genetically modified maize and wheat
    (2019) Liang Q, Wang K, Liu X, Riaz B, Jiang L, Wan X, Ye X, Zhang C
  11. Presence of Cry1Ab in the Bt maize – aphid (Rhopalosiphum maidis) – ladybeetle (Propylea japonica) system has no adverse effects on insect biological parameters
    (2019) Shu Y, Du Y, Wang J
  12. The impact of Bt maize expressing the Cry1Ac protein on non-target arthropods
    (2019) Xing Y, Qin Z, Feng M, Li A, Zang L, Wang Y, Dong X, Zang Y, Shi W
  13. A proteomic-based approach to study underlying molecular responses of the small intestine of Wistar rats to genetically modified corn (MON810)
    (2019) Al-Harbi A, Lary S, Edwards MG, Qusti S, Cockburn A, Poulsen M, Gatehouse AMR
  14. Twenty-one years of using insect resistant (GM) maize in Spain and Portugal: farm-level economic and environmental contributions
    (2019) Brookes G
  15. Effects of non-genetically and genetically modified organism (maize-soybean) diet on growth performance, nutrient digestibility, carcass weight, and meat quality of broiler chicken
    (2019) Zhang S, Ao X, Kim IH
  16. Use of Taxonomic and Trait-Based Approaches to Evaluate the Effects of Transgenic Cry1Ac Corn on the Community Characteristics of Soil Collembola
    (2019) Song X, Chang L, Reddy GVP, Zhang L, Fan C, Wang B
  17. Results of a 16-week Safety Assurance Study with Rats Fed Genetically Modified Bt Maize: Effect on Growth and Health Parameters
    (2018) Szymczyk B, Szymczyk W, Świątkiewicz S, Kwiatek K, Sieradzki Z, Mazur M, Bednarek D, Reichert M
  18. Lack of adverse effects in subchronic and chronic toxicity/carcinogenicity studies on the glyphosate-resistant genetically modified maize NK603 in Wistar Han RCC rats
    (2019) Steinberg P, van der Voet H, Goedhart P, Kleter G, Kok EJ, Pla M, Nadal A, Zeljenkova D, Alacova R, et al.
  19. Development, Adoption, and Management of Drought-Tolerant Corn in the United States
    (2019) McFadden J, Smith D, Wechsler S, Wallander S
  20. The GMO90+ project: absence of evidence for biologically meaningful effects of genetically modified maize based-diets on Wistar rats after 6-months feeding comparative trial.
    (2018) Coumoul X, Servien R, Juricek L, Kaddouch-Amar Y, Lippi Y, Berthelot L, Naylies C, Morvan M-L, Antignac J-P, Christèle D-L, Jegou B, et al.