ライフサイエンスコーパス: pest control

1 well-known systemic insecticide for sucking pest control.

2 l control and plant resistance approaches to pest control.

3 g that transgenic crops open new avenues for pest control.

4 illus thuringiensis (Bt) are widely used for pest control.

5 ve important implications for Bt-toxin-based pest control.

6 to optimize beneficial synergies leading to pest control.

7 cal targets, and new chemical approaches for pest control.

8 evelopment of strategies for the sustainable pest control.

9 sulting in a potential decline in biological pest control.

10 y friendly, scalable, affordable methods for pest control.

11 drive could be a viable tool for vertebrate pest control.

12 environmental factors, impacting sustainable pest control.

13 ecological functions such as pollination and pest control.

14 viruses is an important topic in ecology and pest control.

15 gical and synthetic insecticides complicates pest control.

16 in service of an essential ecosystem service-pest control.

17 eby enhancing their practical application in pest control.

18 ve the potential to provide future tools for pest control.

19 mixed cropping systems that enhance natural pest control.

20 as a promising target for future hemipterans pest control.

21 D-Bol) that could be applied for sustainable pest control.

22 ect this knowledge to lead to more effective pest control.

23 s used in a number of countries for preplant pest control.

24 ing potential novel opportunities for insect pest control.

25 hitin biogenesis is an attractive target for pest control.

26 llus thuringiensis (Bt) are grown widely for pest control.

27 cluding functional genomics and agricultural pest control.

28 ull strategies in each of the major areas of pest control.

29 conventional chemical-based applications for pest controls.

30 ate safer and more sustainable protocols for pest controls.

31 he impacts of flower strips and hedgerows on pest control (18 studies) and pollination services (17 s

32 ty, leaving farmers with inadequate means of pest control(4-12).

33 practices have spillover effects on pests or pest control activity in nearby fields remains unknown.

34 hat is employed commercially as a biological pest control agent.

35 Pest control agents and pests showed greater stability i

36 en used widely as agricultural and household pest control agents for almost five decades and persist

37 Biopesticides are biological pest control agents that are viewed as safer alternative

38 ial consideration when identifying effective pest control agents.

39 de potential molecular target(s) for genetic pest control alternatives.

40 findings contribute valuable information for pest control and a basic biological understanding of lip

41 r and reproduction provides opportunities in pest control and animal husbandry, where environmentally

42 perimental results, we demonstrate that bird pest control and bee pollination services translate dire

43 two critical ecosystem services, aboveground pest control and belowground decomposition, while harves

44 ong animal species that provide pollination, pest control and cultural values.

45 position, carbon sequestration, pollination, pest control and cultural values.

46 rize recent progress in RNAi-mediated insect pest control and discuss factors determining its efficac

47 ease vectors and optimal methods for bed bug pest control and eradication are unclear.

48 outline key steps to enable effective marine pest control and eradication by (i) building upon strate

49 Pest control and eradication is challenging due to insec

50 d use of pesticides due to a lack of natural pest control and more homogeneous crop resources.

51 performing vital roles such as pollination, pest control and nutrient recycling.

52 ces provided by mobile animals, specifically pest control and pollination.

53 hroids, are the most important in the insect pest control and preventing insect vector-borne human di

54 rd species and functional guilds involved in pest control and seed dispersal increasing; however, nat

55 r, suggesting that IsoF can be exploited for pest control and sustainable agriculture.

56 ing that there may be general mechanisms for pest control and that biocontrol research might inform d

57 to detect, having important applications for pest control and understanding of chemical communication

58 er, the links between landscape composition, pest control and yield remain unclear.

59 ical of organic farms, exerted the strongest pest control and yielded the largest plants.

60 ater aquatic functions, pollination, natural pest control, and agricultural pests (a disservice).

61 rtant elements of invasive insect detection, pest control, and basic research programs.

62 uccession, use of prescribed fire for insect pest control, and effects of fire on insect diversity fr

63 ively associated with exposure to waterfowl, pest control, and location.

64 iensis (Bt) crops play an increasing role in pest control, and resistance management is a major issue

65 dopteran pheromones are used extensively for pest control, and were easily prepared using ruthenium-b

66 Kasugamycin residues (KASU), a pest control antibiotic, was reported as an ecosystem th

67 Alternative pest control approaches are therefore highly desirable.

68 Pest control approaches are thus numerous, but their imp

69 a compelling need to develop new vector and pest control approaches.

70 Regarding the agricultural pest control apps that can be searched in the Chinese ma

71 uce Bacillus thuringiensis (Bt) proteins for pest control are grown extensively, but insect adaptatio

72 One author evaluated the pest control articles.

73 for manipulating predator numbers to enhance pest control at different scales are discussed.

74 Here, we show that pest control at the landscape scale is driven by differe

75 Farming systems for pest control, based on the stimulo-deterrent diversionar

76 areas of both trees and shade coffee reduced pest control because CBB was less often profitable prey.

77 target genes for crop improvement, parasite/pest control, bioconservation and genetic diagnostic.

78 uringiensis (Bt) toxins are grown widely for pest control, but insect adaptation can reduce their eff

79 Transgenic crops have revolutionized insect pest control, but their effectiveness has been reduced b

80 m Bacillus thuringiensis (Bt) are useful for pest control, but their efficacy is reduced when pests e

81 ques have the potential to act as biological pest control by feeding on plantation rats, the major pe

82 In a field exclusion experiment, pest control by flying insect enemies increased with lan

83 Biological pest control by natural enemies is an important componen

84 erm pest suppression but improves short-term pest control by reducing the magnitude and duration of t

85 al approaches used in successful terrestrial pest control campaigns, and (ii) developing a toolbox of

86 ing systems typically provide better natural pest control compared with monocultures, although the su

87 Retaining forest and accounting for pest control demonstrates a win-win for biodiversity and

88 is a paradigm that is widely adopted by all pest control disciplines but whose early definitions and

89 For pest control, documentation that an eradication measure

90 Nanoencapsulation can enhance the pest-control efficiency over extended durations by preve

91 uld severely impede effectiveness of current pest control efforts and potentially cause large economi

92 es occur and how they will influence current pest control efforts is a challenge.

93 of material science in improving sustainable pest control for the future.

94 The prediction of pest-control functioning by multi-predator communities i

95 r-reliance on synthetic pesticides in insect pest control has caused widespread public and scientific

96 The extensive use of imidacloprid for pest control has raised concerns about its environmental

97 Rapid expansion of biological pest control has resulted in increased exposure to preda

98 In recent years, bioinspired strategies of pest control have emerged as alternatives to the develop

99 pulation monitoring, most notably for rodent pest control (immunoglobulins (Igs) and amylases) and li

100 ached highest abundances and pollination and pest control improved 1.7- and 1.4-fold respectively.

101 Pest control in agriculture is mainly based on the appli

102 e results may open a new route to transgenic pest control in agriculture.

103 natural enemy interactions thus constrained pest control in complex landscapes.

104 an important strategy to strengthen natural pest control in crops, especially through enhancing the

105 trophic levels in ways that enhance natural pest control in managed ecosystems and consumer control

106 ed in flowering crops and effective low-risk pest control in such crops could potentially benefit bum

107 ained currency in recent years is autonomous pest control, in which complex ecological interactions a

108 n simple landscapes had a negative effect on pest control, increasing plant damage and reducing crop

109 The pest control industry has increasingly emphasized the im

110 re to various public health and agricultural pest control insecticides in nature, and thus the effect

111 gs were identified and tested the ability of pest control interventions to eradicate bed bugs.

112 cific and environmentally friendly method of pest control involving mass release of sterilized insect

113 This form of pest control is called xenointoxication.

114 While chemical pest control is crucial for maximizing yields, applying

115 along with the benefits and consequences for pest control, is discussed.

116 em services, such as pollination and natural pest control, is widely being advocated to maintain and

117 As a hallmark of sustainable pest control, maize-Desmodium push-pull intercropping ha

118 endly alternative to traditional disease and pest control measures.

119 to agriculture worldwide and warrant serious pest control measures.

120 The sterile insect technique is an area-wide pest control method that reduces pest populations by rel

121 tional genomics and in developing innovative pest control methods such as gene drive.

122 to the development of nontoxic, sustainable pest control methods.

123 g a toolbox of effective and scalable marine pest-control methods.

124 phylactic medicine and as a poison in rodent pest control, numerous attempts have been made to unders

125 te to multiple ecosystem services, including pest control, nutrient cycling, and soil structural regu

126 ficient birds to control pests, whether this pest control offsets the reduced cropland, and the compa

127 d mite control implemented during the 1980s, pest control on apple crops was dominated by intensive o

128 ell-established technology, which can enable pest control operators to rapidly confirm the presence o

129 uxes of pesticides (pet grooming operations, pest control operators, and laundromats).

130 arse estimate is that forest patches doubled pest control over 230 km2 by providing habitat for ~ 55

131 We suggest that the effectiveness of DEET in pest control owes to its dual action in inducing avoidan

132 landscape structure with impacts on natural pest control, pesticide use, and conservation of biodive

133 ll major guilds, including those involved in pest control, pollination and seed dispersal, were affec

134 ) on arthropods in fields and their margins, pest control, pollination and yields.

135 se rodents and therefore it provides data to pest control practitioners to choose the most suitable A

136 The results are relevant to vertebrate pest control programs worldwide, especially as technical

137 tter set to develop biological control-based pest control programs, particularly on an area-wide basi

138 and, more generally, other vector or insect pest control programs.

139 dvantageous for the implementation of insect pest control programs.

140 For pest control, PubMed and Toxline searches (1960-October

141 critical services such as disease diagnosis, pest control recommendations, and farm management soluti

142 industry's progression from 1960s integrated pest control research to today's comprehensive integrate

143 Because of the pest control service provided by birds, land sharing was

144 Flower strips, but not hedgerows, enhanced pest control services in adjacent fields by 16% on avera

145 ger field sizes consistently disrupt natural pest control services is without foundation in either th

146 These pest-control services prevented US$75-US$310 ha-year(-1)

147 pendence on diverse natural biota to support pest control, soil bioturbation, and nutrient recycling.

148 not universally beneficial or detrimental to pest control strategies and is dependent on the doses of

149 n R. ferrugineus has the potential to inform pest control strategies and thereby mitigate economic an

150 repair process reduces the effectiveness of pest control strategies are discussed.

151 equently, for the development of sustainable pest control strategies based on manipulating chemosenso

152 underlying molecular mechanisms into durable pest control strategies, including embracing microbial p

153 esign of more sophisticated insect-selective pest control strategies.

154 ation of species-specific targets for future pest control strategies.

155 genic sexing strains that produce one sex in pest control strategies.

156 es in insects has emerged as a promising new pest control strategy, and RNAi-based products are being

157 were reduced to typical levels in landscape pest-control studies.

158 this group is to identify issues relevant to pest control, such as dispersal ecology and the recent g

159 ptimization of this environmentally friendly pest-control tactic.

160 unt for a relatively small proportion of the pest control tactics employed, and in some systems they

161 ural biotechnology in concert with classical pest control tactics.

162 eatens the more widespread use of this novel pest control technology.

163 d this can create a coordinated response for pest control that is effective at a landscape scale.

164 It has applications in pest control that mimic Sterile Insect Technique when on

165 systems make it difficult to use traditional pest control theory to guide biological control of disea

166 hat contributes to the ecosystem function of pest control, this is an example of how spatial dynamics

167 ed to produce all male population for use in pest control though sterile male release methods.

168 more show that enhancing natural enemies and pest control through increasing landscape complexity can

169 anual searches of older journals, textbooks, pest control trade journals, and newspapers (1892-Octobe

170 the interactions of two ES, pollination and pest control, via a factorial field experiment in 30 Cos

171 AI seropositive flocks that did not use pest control were 2.5 times as likely to be AI seroposit

172 Traditional methods of stored-product pest control were initially passed from generation to ge

173 complexity is assumed to enhance biological pest control, whereas below ground, soil organic carbon

174 ological control is one of the strategies of pest control which is determined by the biological fitne

175 ng chemicals and biologicals for sustainable pest control with human safety.

176 In pest control workers, sangre de grado balm (Zangrado) wa

177 clinical trial of a sangre de grado balm in pest control workers.