ライフサイエンスコーパス: chemical control

1 for activating molecules within cells under chemical control.

2 ify promising and more effective targets for chemical control.

3 chieved rapidly and can be also placed under chemical control.

4 ced the American farmer to the modern era of chemical control.

5 sistance in mosquito populations targeted by chemical control.

6 r that will replace costly and unsustainable chemical controls.

7 management of M. incognita relies heavily on chemical controls.

8 dative radical coupling that is under simple chemical control, a mechanism analogous to that theorize

9 r specificity, safety and the move away from chemical control agents.

10 Cultural and chemical controls are effective and available.

11 Physical and chemical control at the nanoscale is also necessary tail

12 ral domains and also provide a rich suite of chemical controls available to manipulate plasmons, such

13 hese studies show how combining physical and chemical control can expand the possibilities of crystal

14 ly relied upon worldwide for larval mosquito chemical control due to their target specificity and lon

15 ist introductions, integrated biological and chemical control, environmental optimization, and the ut

16 n established by microfluidics methods, this chemical control has largely been limited to two dimensi

17 ht a previously unrecognized role of mechano-chemical control in patterned cell division during regen

18 monic structure with a regulated physical or chemical control input.

19 Chemical control is not effective and unfriendly to the

20 Chemical control is the primary management strategy curr

21 otection with great potential to replace the chemical control measures now prevalent.

22 Chemical control methods are expensive, harmful to non-t

23 ore questions at yet another length scale of chemical control, namely: What are the molecular-scale f

24 can provide the degree of conformational and chemical control necessary for directing such reactions.

25 onsidered include the nature of physical and chemical control objectives, the development of possible

26 Methods for the chemical control of Auger recombination and Auger coolin

27 For the last decade, chemical control of bacterial virulence has received con

28 limited selectivity, full post-translational chemical control of biology would circumvent the dogma o

29 to be an effective tool for high-resolution chemical control of brain circuits.

30 We conclude that the chemical control of breathing does not become unstable w

31 This implies that the chemical control of breathing might become less stable w

32 he protein and, therefore, offers a tool for chemical control of charge transport across biomaterial-

33 Chemical control of cullin neddylation is attracting inc

34 This work lays the foundation for chemical control of defect quantum states in low-dimensi

35 nd theoretical investigation, we demonstrate chemical control of different forms of constructive QI (

36 exclusive, further demonstrating the mechano-chemical control of fibrin biochemistry.

37 rfaces by small molecules, a minimum step in chemical control of gene networks.

38 ater supplies, filtration of drinking water, chemical control of intermediate hosts, case containment

39 cal and physiological applications requiring chemical control of ion conductance.

40 s and added them to lipid bilayers, allowing chemical control of length, glycosylation, and surface d

41 e neuroligin molecule, effectively bestowing chemical control of neuroligin dimerization.

42 resent, there is no effective alternative to chemical control of parasitic helminths where livestock

43 Chemical control of protein secretion using a small mole

44 In this way combining chemical control of PTM with readily available protein s

45 In this way, combining chemical control of PTM with readily available protein s

46 adds to the growing complexity regarding the chemical control of retinal function that is likely to i

47 Chemical control of stem cells provides potential soluti

48 Chemical control of the conformation of a flexible organ

49 diol/diester interfacial layers, indicating chemical control of the crystallite thickness.

50 This is achieved through chemical control of the degree of s-orbital mixing into

51 dependent EOF in the pH range of 5-10 due to chemical control of the effective zeta-potential.

52 greater positive impact on LCA metrics than chemical control of the fungal pathogen using a fungicid

53 Advances in chemical control of the photophysical properties of tran

54 We demonstrated that chemical control of the spatial arrangement of distinct

55 ture by experimentally demonstrating precise chemical control of the SPR peak positions via ligand ex

56 onic spin qubits within layered 2DPs enables chemical control of their inter-qubit interactions and s

57 A chemo-genetic variation enabling chemical control of ubiquitination revealed KCNQ1 surfac

58 lood flow regulation is discussed, including chemical control of vascular tone, heterotypic and homot

59 ving water bodies, where it may exert strong chemical controls on ecosystem function.

60 work for understanding linked hydrologic and chemical controls on microbial denitrification (and pote

61 By resolving the chemical controls on mineral dissolution in ice, this wo

62 Here, we examine the chemical controls on Ni(II) and Zn(II) release from Ni-

63 zation-either by minimizing disorder through chemical control or by achieving sufficient couplings us

64 Chemogenetics enables noninvasive chemical control over cell populations in behaving anima

65 em represents a new modality for engineering chemical control over intracellular protein function tha

66 o this work demonstrates the possibility for chemical control over molecular order within films of co

67 current approaches are limited by a lack of chemical control over proteins in the gas phase.

68 to split Cas9 protein fragments can provide chemical control over split Cas9 activity.

69 Here, we show that it is possible to exert chemical control over the formation of metal/molecule...

70 e formed defects demonstrate the outstanding chemical control over the incorporation of impurities in

71 ates, which will enable improved and diverse chemical control over the nature of analyte-surface bind

72 ule-protein-protein conjugates with complete chemical control over the sites of modification.

73 a systematic approach that provides rational chemical control over the structural characteristics of

74 Gaining chemical control over the thermodynamics and kinetics of

75 the two photocatalysts afford complementary chemical control over these reactions to design elaborat

76 atial, temporal, thermal, concentration, and chemical control parameters.

77 iochemical inputs and autonomously implement chemical control programs.

78 ith economic thresholds, sampling plans, and chemical control recommendations widely adopted.

79 While chemical control simply increases the formation probabil

80 ould synergistically integrate with existing chemical control strategies to avert insecticide resista

81 nimize bromate formation during ozonation by chemical control strategies, such as ammonium with or wi

82 p synthesis of nanomaterials, the effects of chemical control (strength of the directionality in the

83 tudy cell-surface phenomena with a degree of chemical control that cannot be achieved using conventio

84 ses of anthelmintics and an over-reliance on chemical control, there is a great need to discover new

85 Chemical control through the frequent 'blanket' administ

86 Here, we use chemical control to acutely restrict Piezo1 conformation

87 Chemical control using lampricides (i.e., lamprey pestic

88 However, through chemical controls using the (R) stereoisomer of RSL3 [(1

89 ransmission biology, biological control, and chemical control with respect to "Candidatus Liberibacte