ライフサイエンスコーパス: control agent

1 h, Pareuchaetes pseudoinsulata (a biological control agent).

2 d for its potential application as an insect control agent.

3 Saline was used as the control agent.

4 Gadobutrol was used as a third-space control agent.

5 light its potential as an effective mosquito control agent.

6 e efficacy of this classical weed biological control agent.

7 multi-enemy assemblage rather than a single control agent.

8 bserved between the groups after exposure to control agent.

9 M. multispinosus could serve as a biological control agent.

10 ressive soil was selected as a potential bio-control agent.

11 ms; in this case, a key predatory biological control agent.

12 r disease system and the vector's biological control agent.

13 s employed commercially as a biological pest control agent.

14 ythm control agent is used instead of a rate control agent.

15 ogenesis was established using a nonspecific control agent.

16 oup appear to be well suited as a biological control agent.

17 divided into rhythm control agents and rate control agents.

18 iew of their potential development as insect-control agents.

19 ssessed for nematode potential as biological control agents.

20 athogenic nematodes are excellent biological control agents.

21 olation versus drug therapy with rate/rhythm control agents.

22 ess of parasites and pathogens as biological control agents.

23 a bassiana are widely used insect biological control agents.

24 rating the pace of discovery of novel vector control agents.

25 h in a planetary ball mill) without process control agents.

26 ial target for the improvement of biological control agents.

27 culoviruses and for using them as biological control agents.

28 could come into contact with EPN biological control agents.

29 losing response when exposed to conventional control agents.

30 methods but sterile females are ineffective control agents.

31 city, safety and the move away from chemical control agents.

32 taki is one of the most important biological control agents.

33 Organization threshold for successful vector control agents.

34 PNs) are insect parasites used as biological control agents.

35 espread in nature and are attractive disease control agents.

36 s, such as agricultural pests and biological-control agents.

37 onsideration when identifying effective pest control agents.

38 electrostatic repulsive forces using charge control agents.

39 rtant site of entry for pathogens and insect control agents.

40 ional trade, and risk analysis of biological control agents.

41 the design and screening of selective insect control agents.

42 for the design of anticancer drugs and gene control agents.

43 o treatment but not compared with respective control agents.

44 lso indicated a general preference for human-controlled agents.

45 triles (dicyandiamide or cyanamide) as shape controlling agents.

46 ids reared from native moths were biological control agents, 14% were accidental immigrants, and 3% w

47 was chemically modified with a permeability-controlling agent, Acetyl Yellow 9 (AY9), using glutaric

48 m Asia into Africa as a classical biological control agent against the pod borer Maruca vitrata (Fabr

49 d show their potential for use as biological control agents against fungal diseases.

50 ins have demonstrated potential as microbial control agents against malaria mosquitoes.

51 er Bacilli have long been used as biological control agents against plant bacterial diseases but the

52 per 1.73 m(2) had lower adjusted use of rate control agents (aHR, 0.61; 95% CI, 0.56 to 0.67), warfar

53 of economically important pests, biological control agents and disease carriers.

54 seful herbal formulation for chemical plaque control agents and improvement in plaque and gingival st

55 trated significant protection, compared with control agents and no treatment.

56 Pest control agents and pests showed greater stability in fun

57 r atrial fibrillation is divided into rhythm control agents and rate control agents.

58 isense morpholino oligonucleotide to CD47 or control agents and tissue survival assessed.

59 ivo (n=13; P<0.05, CatK imaging agent versus control agent) and in human carotid endarterectomy speci

60 er dose (0-2 mg/L), orthophosphate corrosion control agent, and water heater anode materials (aluminu

61 efuges from attacks, reciprocal evolution by control agents, and contrasting selection pressures from

62 ng mesoscale communities of more versus less controlled agents; and globalized learning destroys meso

63 e been introduced deliberately as biological control agents (Anthocoris spp., Montandoniola moraguesi

64 ty was associated with lower receipt of rate control agents, anticoagulation, and AF procedures.

65 developing new, environmentally safe insect control agents are discussed.

66 or or disfavor control, depending on whether controlled agents are harmed or helped by contact with a

67 ing a priori ranking of candidate biological control agents based on their traits.

68 omoting rhizobacteria (PGPR) as a biological control agent (BCA) to reduce the use of agrochemicals.

69 Using biological control agents (BCAs) is an essential component of integ

70 for strain-specific screening of biological control agents before wide-spread adoption.

71 In contrast, with the control agent betaxolol, there was no increase.

72 ly infects acridids, has been developed as a control agent but its utility is limited by slow kill ti

73 erent in most naturally occurring biological control agents but development of recombinant DNA techni

74 the vector prove to be effective biological control agents, but highly virulent pathogens of the vec

75 e molecular specificity of A15 for FXIIIa, a control agent (C15) was also synthesized by modifying a

76 f problematic plant species using biological control agents can be quantified, but the risks and net

77 as DTT, IFN, and adherent-invasive E coli or control agents; cells were analyzed by immunoblots and q

78 acy of phages, as is true of many biological control agents, depends greatly on prevailing environmen

79 monstrated its potential as an efficient bio-control agent, especially against stored grain pests.

80 e transduction tool and potential biological control agent for Anopheles mosquitoes.

81 ed widely as agricultural and household pest control agents for almost five decades and persist in ou

82 s are being developed as aqueous rheological control agents for diverse industrial and food applicati

83 exist that should be further investigated as control agents for olive fruit fly in the many climatic

84 ce of phenazine producers used as biological control agents for soilborne plant pathogens.

85 the VHHs and their potential use as quality control agents for the end game of poliovirus eradicatio

86 Since the use of antibiotics as control agents has not been shown to be effective, an al

87 t-R-AEF interactions and R-AEF as biological control agents have been studied independently and witho

88 efuges and diversity of enemy species, or if control agents have genetic barriers to evolution.

89 ar tumor margin identification compared to a control agent, ICG alone.

90 d 1000 mOsm) and mannitol used as an osmotic control agent in both experiments.

91 ympathetic nervous system and betaxolol as a control agent in independent test sessions separated by

92 ential to evolve resistance to their primary control agent in the near future, highlighting the urgen

93 ived oligogalacturonides (OGs) as biological control agents in agriculture, very little information e

94 application of bacteriophages as biological control agents in clinical therapy, food processing, and

95 he efficacy of different types of biological control agents in controlling vector-borne diseases.

96 ation and persistence of candidate microbial control agents in mosquito hosts, and the need for robus

97 one of the most extensively used biological control agents in the field to manage arthropod pest spe

98 the potential damage caused by an introduced control agent, in addition to that caused by the target

99 Vinblastine, but not control agents, induced cleavage of procaspase-3, procas

100 her understanding of the dynamics and how to control agent interactions to facilitate or avoid multiv

101 nd toward less anticoagulation when a rhythm control agent is used instead of a rate control agent.

102 Increased age and use of rate control agents is associated with the use of anticoagula

103 The species, once used as a biological control agent, is now a worldwide invader.

104 PN Meloidogyne incognita with the biological control agent KM2501-1 resulted in a mortality of 87.66%

105 e of their selectivity and safety, microbial control agents (MCAs) appear to be ready-made components

106 Use of a rhythm control agent might be associated with less use of antic

107 tration did not increase MACEs compared with control agents (odds ratio [OR], 1.16; 95% CI, 0.85-1.58

108 15 mCi given in 2-3 doses over 2-8 days, or control agents of buffer, unlabeled octreotide or 64Cu-l

109 en studied for their potential as biological control agents of fungi.

110 attracting attention as potential biological control agents of insect pests.

111 hat improve the utility of fungi as specific control agents of insects.

112 applied interest because many are biological control agents of pest insects.

113 economic loss when they occur in biological control agents of pests.

114 16 and MDA-MB-231), as well as a non-binding control agent on CA IX positive cells, showed low fluore

115 ingle 15 mCi dose than in rats injected with control agents (p < 0.05).

116 al pests and increasingly as biological weed control agents, particularly in North America.

117 thresholds of host, pathogen and biological control agent, performing an equilibrium analysis, and n

118 e initial amounts of pathogen and biological control agent present.

119 rate new insights into identifying effective control agents prior to their release in the field.

120 es from an economically important biological control agent, Puccinia suaveolens, to highlight the pot

121 ct factor IXa inhibitor RB006 and its active control agent RB007.

122 Although parasitism by biological control agents reached 28% in some species of moth, all

123 es, the mode of action of natural biological control agents related to pathogens can be systematicall

124 f Bacillus amyloliquefaciens as a biological control agent relies on its ability to outgrow plant pat

125 ness of entomopathogenic fungi as biological control agents require a clear understanding of the path

126 e slowly than xenograft tumors in mice given control agents, resulting in longer survival times.

127 ression over time (5- to 7-fold greater than control agent signal at 2 years; P<0.01).

128 nose is an essential component of the insect control agent spinosad.

129 les resulted from the introduction of charge control agents such as AOT molecules can enhance the cha

130 y by the inherent instability of many of the control agents, suggesting that pursuit of the autonomou

131 stic fungus Trichoderma viride, a biological control agent that has previously been shown to affect t

132 Biopesticides are biological pest control agents that are viewed as safer alternatives to

133 ernanthera philoxeroides) and its biological control agent the alligatorweed flea beetle (Agasicles h

134 liberate introduction of an alien biological control agent: the carnivorous snail Euglandina rosea[3]

135 r tumors and survived longer than mice given control agents; the tumor stroma had fewer activated pan

136 d to no PrEP in 70% coverage components with control agents, there was a 15% disseminated risk reduct

137 tion to identifying new potential biological control agents, these results expand the grand view of t

138 ophyte that has been applied as a biological control agent to protect plants from fungal pathogens.

139 ulness as an environmentally friendly vector control agent to reduce malaria transmission, warranting

140 Alkylamines serve as shape-control agent to regulate the growth of the hexagonal py

141 hen insect herbivores are used as biological control agents to manage invasive plants.

142 d many greenhouse growers rely on biological control agents to regulate T. vaporariorum populations.

143 munities of predator and pathogen biological control agents, typical of organic farms, exerted the st

144 n occurred in 12 of 13 animals given various control agents under similar conditions.

145 ption of calcium homeostasis and appropriate control agents were investigated in vitro using Affymetr

146 We excluded studies with an active control agent (which might mitigate the lethality of ven

147 ork suggests that interactions of biological control agents with their own natural enemies can disrup