ライフサイエンスコーパス: insect control

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1 tion in insects and possible applications in insect control.

2 and identification of targets for selective insect control.

3 ls by Wolbachia, and suggest new methods for insect control.

4 sease and to develop more effective means of insect control.

5 oteins may provide new molecular targets for insect control.

6 evidence of a viable RNAi-based strategy for insect control.

7 ss toxins of Bacillus thuringiensis (Bt) for insect control.

8 (Bt) toxins are currently being deployed for insect control.

9 Rhamnose is an essential component of the insect control agent spinosad.

10 stigated for its potential application as an insect control agent.

11 eful in developing new, environmentally safe insect control agents are discussed.

12 an important site of entry for pathogens and insect control agents.

13 ful in the design and screening of selective insect control agents.

14 ed in view of their potential development as insect-control agents.

15 ology is being developed to provide improved insect control and a wider spectrum of activity.

16 e, insects developing resistance, inadequate insect control and promote public acceptance of genetica

17 ctive alternative to chemical pesticides for insect control, and this fungus has been shown to be an

18 een shown to be an effective RNAi target for insect control, as DvSnf7 RNAi leads to lethality of WCR

19 oteinase inhibitor may be more effective for insect control because sugar beet is cropped in restrict

20 is (Bt) toxins are deployed increasingly for insect control, but their efficacy will be short-lived i

21 g plants for enhanced biomass production and insect control by releasing plant hormones or sugar este

22 nce by pests is the main threat to long-term insect control by transgenic crops that produce Bacillus

23 e for enabling work on innovative methods of insect control, for understanding the mechanisms of inse

24 ntial deployment of NCR toxins is useful for insect control in few situations.

25 illus thuringiensis (Bt) are used widely for insect control in sprays and transgenic plants, but thei

26 ce; Ecology, Epidemiology and Modelling, and Insect Control in the New Millennium.

27 The role of transgenic insect control in the prevention of mycotoxins in maize

28 in genes are the primary transgenes used for insect control in transgenic crops.

29 chocerciasis, has been the target of a major insect control initiative for the past 20 years.

30 Insect control is an essential part of reducing transmis

31 ernema carpocapsae, which is widely used for insect control, is capable of infecting and killing D. m

32 As with any new insect control method, questions arise about potential r

33 Based on this principle, a new generation of insect control methods using RNA interference (RNAi) are

34 In insects, control of body size is intimately linked to nu

35 Why insect control on lawns, golf courses, and sport fields

36 anosomiases, and disease containment through insect control programmes is an achievable goal.

37 prevent or manage resistance to Bt toxins in insect control programs.

38 ecades of research have revealed that flying insects control speed, altitude, and trajectory by a sim

39 rovide a sound foundation for developing new insect control strategies aimed at enhancing the impact

40 However, insect control strategies involving a different mode of

41 intracellular bacterium, provides a tool for insect control through manipulation of host-microbe inte

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