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농업해충에 대한 친환경유기농자재들의 살충력 및 섭식저해력 평가

Evaluation of Insecticidal and Antifeeding Activities of Eco-friendly Organic Insecticides Against Agricultural Insect Pests

  • 김유화 ((주)나리소 연구개발전담팀) ;
  • 나영은 (농촌진흥청 연구운영과) ;
  • 김민준 ((주)나리소 연구개발전담팀) ;
  • 최병렬 (국립농업과학원 작물보호과) ;
  • 조형찬 (우석대학교 보건복지대학 재활학과) ;
  • 김순일 ((주)나리소 연구개발전담팀)
  • Kim, Yoo Hwa (Team of Research & Development, Nareso Co., Ltd.) ;
  • Na, Young-Eun (R&D Coordination Division, RDA) ;
  • Kim, Min Joon (Team of Research & Development, Nareso Co., Ltd.) ;
  • Choi, Byung Ryul (National Academy Agricultural Science) ;
  • Jo, Hyeong-Chan (Department of Rehabilitation Welfare, College of Health Sciences and Social Welfare, Woosuk University) ;
  • Kim, Soon-Il (Team of Research & Development, Nareso Co., Ltd.)
  • 투고 : 2015.05.08
  • 심사 : 2015.05.15
  • 발행 : 2015.06.01

초록

충해 또는 병충해 관리용 친환경유기농자재로 목록공시된 제품 29종의 배추좀나방과 파밤나방 유충, 복숭아혹진딧물 성충, 꽃노랑총채벌레 성충에 대한 살충과 섭식저해활성을 분무법과 잎침지법을 이용하여 실내에서 평가하였다. 배추좀나방 유충에 대해 추천농도 분무 또는 잎침지시 유효성분으로 고삼 추출물 60% 단제(EOIS)와 고삼외 3종 식물 추출물(백부근, 멀구슬나무, 개박하, EIOSm) 및 고삼외 2종 식물추출물(EOISc)을 함유한 혼합제의 살충력이 우수했다. 하지만 반량 처리 시 그 활성은 50% 이하로 감소되었다. 파밤나방 유충에 대해서는 고삼 60%단제(EOIS)만이 우수한 살충력을 보였고, 비슷하게 꽃노랑총채벌레 성충에 대해 잎침지 후 24시간과 48시간 노출 시 85%와 95%의 살충력을 나타냈다. 복숭아혹진딧물 성충에 대한 분무시험에서 고삼 외 3종 혼합제(EOISm)와 유채외 2종 혼합제(EOIR)가 93%와 68% 살충력을 보였는데, 농도를 배량 증가시켜도 살충력은 크게 향상되지 않는 경향을 보였다. 추천농도 잎침지에서는 고삼외 3종 혼합제(EIOSm)만이 100%의 강한 접촉독성을 나타냈는데, 노출 시간과 농도를 증가시키면 시트로넬라오일외 1종(EOICi)과 유채외 2종 혼합제(EOIR)들의 살충력이 증가하였다.흥미롭게도 cedar oil 16%(EOICe), 고삼 60% 단제(EOIS), 고삼외 3종 혼합제(EIOSm), 고삼외 2종 혼합제(EOISc), 미생물 89.62%(EOIM), 유채외 2종 혼합제(EOIR), 식물추출물(EOIPe), 차나무추출물 48%(EOIT)제 등은 파밤나방에 대해 분무처리 시 강한 섭식저해활성을 나타냈다. 또한 배추좀나방 유충에 대해서도 이들 혼합제들 이외에 3종 미생물제들(EOIB, EOIM, EOIBs)과 시트로넬라오일외 1종(EOICi), 겨자외 2종(EOIMc) 등의 식물 추출물 혼합제들이 70% 이상의 섭식저해활성을 나타냈다. 이상의 결과, 대상 곤충 종 및 유효성분이나 처리량에 따라 살충력과 섭식저해력이 차이를 보였으나, 전체적으로 고삼추출물외 2-3종 식물추출물을 복합적으로 함유한 혼합제들의 유효력이 우수하게 나타남을 알 수 있었다.

Insecticidal and antifeeding activities of 29 commercialized eco-friendly organic products for managing plant diseases and insect pests against Plutella xylostella larvae, Spodoptera exigua larvae, Frankliniella occidentalis adults, and Myzus persicae adults were tested using spraying and leaf dipping bioassays under laboratory conditions. Products containing 60% Sophora extract (EOIS) and mixtures (EOISm) with Sophora extract, Stemona japonica extract, Melia azedarach extract, and Nepeta cataria extract as well as mixtures (EOISc) with Sophora extract, Chenopodium ambrosioides extract, and Melia azedarach extract as active ingredients showed strong insecticidal activity at recommended concentration against P. xylostella larvae. At half concentration, their insecticidal activities were decreased under 50%. The EOIS gave good insecticidal activity against S. exigua larvae and also showed 85% and 95% insecticidal activity at 24 and 48 hours after treatment to F. occidentalis adults, respectively. For M. persicae adults, EOISm and mixtures (EOIR) containing rape seed extract, neem extract, and castar oil produced 93% and 68% insecticidal activity, but their activities did not be increased at double concentration. EOISm only showed 100% contact toxicity against M. persicae adults exposed to dipping leaves. Interestingly, the insecticidal activity of EOIR and EOICi (citronella oil and derris extract) against M. persicae adults was increased with exposed time and concentration. In addition, EOICe (cedar oil), EOIS, EOISm, EOISc, EOIM (microorganism), EOIR, EOIPe (plant extract), and EOIT (tea tree extract) gave strong antifeeding activity against S. exigua and P. xylostella larvae. EOIB, EOIBs, EOIM, EOICi, and EOIMc showed above 70% antifeeding activity to the lepidopteran larvae. These results indicate that mixtures containing 2 to 3 plant extracts with Sophora extract show good activities against insect pests, although the difference of insecticidal and antifeeding activities was produced depending on both a tested insect species and an active ingredient or concentration.

키워드

참고문헌

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