ライフサイエンスコーパス: crop protection

1 rtilization, residue management and chemical crop protection).

2 ll help us develop innovative strategies for crop protection.

3 interference (RNAi) shows great potential in crop protection.

4 as well as utilization of these pigments in crop protection.

5 gen genes on plant surfaces confer efficient crop protection.

6 ivering, sustainably, the signal systems for crop protection.

7 as presenting opportunities for sustainable crop protection.

8 den its utility and adoption for sustainable crop protection.

9 h antimicrobials for medical applications or crop protection.

10 s deserve attention beyond their efficacy in crop protection.

11 ing cyclotides and their acyclic variants in crop protection.

12 s not possible for practical applications in crop protection.

13 ynthesis and signaling important targets for crop protection.

14 ead to more evolutionarily stable methods of crop protection.

15 tion of endogenous resistance mechanisms for crop protection.

16 the basis for novel transgenic approaches to crop protection.

17 y also encode functions that can be used for crop protection.

18 ng durable disease resistance and successful crop protection.

19 ng a cost-effective strategy for sustainable crop protection.

20 viding innovative prospects for agricultural crop protection.

21 ew approaches to rhizosphere engineering and crop protection.

22 bacterial pesticidal proteins (BPP) used for crop protection.

23 , opening additional avenues for sustainable crop protection.

24 t defenses and how this can be exploited for crop protection.

25 targeted strategies for nematode control and crop protection.

26 mmune activation for durable and sustainable crop protection.

27 way for new perspectives in human health and crop protection.

28 ms to increase natural biocontrol agents for crop protection.

29 sting the potential application of FoCWEs in crop protection.

30 They also provide novel strategies for crop protection against biotrophs without compromising r

31 hnology applications such as enhancing plant crop protection against fungal pathogens.

32 has been used for many years as a biological crop protection agent.

33 Many antibiotics, chemotherapeutics, crop protection agents and food preservatives originate

34 in agriculture and medicine, as ecofriendly crop protection agents, and as drug leads or scaffolds f

35 portant scaffolds for medicinal chemistry or crop protection agents, yet the selective preparation of

36 C for the development of new antifungal and crop protection agents.

37 pharmaceuticals, pesticides, herbicides, and crop protection agents.

38 lant pathogens and are thus highly efficient crop-protection agents.

39 ng SUGR-1 signaling as a valuable target for crop protection and food security.

40 genicity factors opens new opportunities for crop protection and food security.

41 thogenic oomycetes opens up opportunities in crop protection and food security.

42 ns for heightened environmental restoration, crop protection and human health.

43 s (CTV) and in developing it into a tool for crop protection and improvement.

44 and in converting the virus into a tool for crop protection and improvement.

45 hesis, pharmaceutical discovery agrochemical crop protection and materials chemistry, new methods for

46 important compounds in asymmetric synthesis, crop protection and medicinal chemistry.

47 heir structural concept may be exploited for crop protection and novel pharmaceuticals.

48 romise for exploiting these interactions for crop protection and pest management in agriculture.

49 id is an agrochemical recently developed for crop protection and the most significant member of the s

50 macrocyclic lactones that is widely used in crop protection and to treat helminth infections in man

51 'toolbox' can enable biotechnology, enhance crop protection, and shed light on fundamental host biol

52 . Environmental Protection Agency for use in crop protection applications since approval for Bacillus

53 ery of RNAi for human therapeutics to use in crop protection as an environmentally sustainable and ea

54 not only for humans and animals but also for crop protection as pesticides.

55 ch could be applied not only to agricultural crop protection but also to the prevention of virus infe

56 nt functional genomics, crop improvement and crop protection, but the primary obstacle for the develo

57 volution, and identify targets for drugs and crop protection chemicals.

58 and health products, bio-based materials and crop protection chemicals.

59 iples belonging to the strobilurin family of crop protection compounds.

60 data sets from neglected disease screening; crop protection data; drug metabolism and disposition da

61 While IPM is broadly endorsed by crop protection disciplines, farmers, other agricultural

62 h notable applications to material sciences, crop protection, drug discovery, and pharmaceutical indu

63 ug feeding on soybean pods requires vigilant crop protection due to low economic thresholds.

64 s in plant microbiomes is highly relevant to crop protection, food safety and agroecology, and can ai

65 (such as methyl bromide) and nematicides for crop protection has been discouraged due to environmenta

66 l of ncRNAs in agriculture, particularly for crop protection, improvement, and modulation.

67 using optical disease detection systems for crop protection in precision pest management.

68 Finally, the use of PMA interactions for crop protection in sustainable plant production that sup

69 amental shift to a total system approach for crop protection is urgently needed to resolve escalating

70 noid insecticides are increasingly used as a crop protection measure to suppress insect pests on tree

71 r A. laibachii infection, highlighting their crop protection potential.

72 Crop protection products (CPPs) are subject to strict re

73 ions about the sustainable use of fruit tree crop protection products and informing regulatory proces

74 ward levels correlated with higher levels of crop protection provided by the ants.

75 nues for developing environmentally friendly crop protection strategies in an era marked by an impera

76 f an enzymatic resistance gene in transgenic crop protection strategies must take into account the ki

77 pples induced by such processes as different crop protection strategies or storage, are of interest t

78 molecular pesticides, and nucleic acid-based crop protection strategies, highlighting key design prin

79 ll ultimately lead to the development of new crop protection strategies.

80 evolutionary biology, and the application of crop protection strategies.

81 laid a foundation for the rational design of crop protection strategies.

82 pathogen AGOs promises to improve RNAi-based crop protection strategies.

83 This knowledge will inform future crop protection strategies.

84 unctions before applying them in sustainable crop protection strategies.

85 the potential of RNA interference as a novel crop protection strategy against this insect pest.

86 ve as key tools in the development of robust crop protection systems suitable for a changing climate.

87 ining living parasites are valuable emerging crop protection technologies against insect pests, but t

88 candidate genes that might lead to enhanced crop protection through genetic engineering.

89 ing plant virus transmission would allow for crop protection, virus receptors in insect vectors are u

90 lebees are exposed to pesticides applied for crop protection while foraging on treated plants, with i

91 riendly and efficacious antiviral agents for crop protection will contribute to global food security,

92 fective utilization of induced resistance in crop protection will require a functional understanding

93 pronil is an outstanding new insecticide for crop protection with good selectivity between insects an