ライフサイエンスコーパス: biological reaction

1 ble flexibility in a variety of chemical and biological reactions.

2 , by using radiotracers that detect relevant biological reactions.

3 s) plays a crucial role in many chemical and biological reactions.

4 for revealing the dynamic nature of complex biological reactions.

5 ccuracy when monitoring small pH dynamics in biological reactions.

6 xpands our capability to interrogate complex biological reactions.

7 ry powerful tool to miniaturize chemical and biological reactions.

8 udies investigating HNO-related chemical and biological reactions.

9 energy of highly efficient enzyme-catalyzed biological reactions.

10 on for the formation of adenosine from other biological reactions.

11 izing our ability to probe the mechanisms of biological reactions.

12 an enhance nucleobase reactivity to catalyze biological reactions.

13 mechanistic understanding of these critical biological reactions.

14 Carbon monoxide is produced by several biological reactions.

15 is quantifying the isotopic fractionation of biological reactions.

16 regation in biofluids can trigger unexpected biological reactions.

17 fill temperatures above those estimated from biological reactions alone.

18 is an important aspect of understanding many biological reactions and a key part of drug design.

19 -C formation is of fundamental importance in biological reactions and has considerable relevance to b

20 effects of strabismus surgery on muscle cell biological reactions and myofiber remodeling may suggest

21 sylmethionine is widely used in a variety of biological reactions and participates in the methionine

22 rovide new opportunities for light-triggered biological reactions and photodynamic therapy.

23 h of unique reactivity that is orthogonal to biological reactions and processes.

24 In vitro studies of biological reactions are rarely performed in conditions

25 ns that have hundreds of amino acids-complex biological reactions-are often spontaneous and rapid.

26 Carbanions appear in many organic or biological reactions as fleeting intermediates, prohibit

27 ve site is able to catalyse this fundamental biological reaction at a suitable rate for protein synth

28 nced evolutionary development of oscillatory biological reactions at shores where waves impinge on ro

29 Mathematical models of biological reactions at the system-level lead to a set o

30 abolites, used not only in a large number of biological reactions but amenable to several different m

31 Dioxygenases catalyze a diverse range of biological reactions by incorporating molecular oxygen i

32 Here, we demonstrate how a biological reaction can be followed on ultrafast timesca

33 The complexity of biological reactions can obscure specific conformational

34 In an effort to determine which biological reactions can occur in relation to the water

35 A classic example of a diffusion-controlled biological reaction catalyzed by an oligomeric enzyme is

36 physiological redox cofactors, we posit that biological reaction centers have recruited a strategy to

37 n that the droplets can be used as versatile biological reaction compartments.

38 In this first continuous observation of a biological reaction coordinate from substrate to product

39 Intracellular compartmentalization enhances biological reactions, crucial for cellular function and

40 rved in a variety of physical, chemical, and biological reaction-diffusion systems.

41 This view ignores a critical reality: biological reactions do not happen in an empty space, bu

42 e, in addition to being an energy source for biological reactions, for which micromolar concentration

43 Amyloid-mediated catalysis of key biological reactions has recently attracted significant

44 its versatility in studying a wide range of biological reactions, highlighting its potential as a fl

45 in real time, the progress of a chemical or biological reaction in a microdrop of a few tens of micr

46 Prenylation is a common biological reaction in all domains of life wherein preny

47 we provide a first, fundamental step towards biological reactions in air by demonstrating the acousto

48 partments and would enable the initiation of biological reactions in complex aqueous environments.

49 determining rates of physical, chemical and biological reactions in the soil.

50 accommodating a large number of chemical and biological reactions in tiny volume with precise control

51 ape, providing new opportunities to modulate biological reactions in vivo; this rationalises the comm

52 ound to proteins perform a number of crucial biological reactions, including the oxidation of water b

53 Furthermore, the ability to incorporate non-biological reactions into the final steps allows determi

54 This biological reaction involves exchange of DNA in a synapt

55 We describe a new method for studying rapid biological reactions involving dioxygen.

56 his approach can be used to study other fast biological reactions involving O(2).

57 ach provides long-awaited access to critical biological reactions involving single-stranded DNA bindi

58 ction network composed of seven interrelated biological reactions (involving a specific mRNA, the pro

59 he role of solvent dynamics in mediating the biological reaction is often left aside owing to its com

60 mechanism by which ribozymes can accelerate biological reactions is by adopting folds that favorably

61 ular actions, their practical application in biological reactions is often confined to reversible pho

62 of reagents to drops, its compatibility with biological reactions is yet to be thoroughly demonstrate

63 radical gas implicated in a wide variety of biological reactions, is a novel signaling molecule that

64 Due to the rapidity of biological reactions, it is difficult to isolate interme

65 As a result, some biological reactions may occur in an activationless fash

66 cal samples, gaining insights into unraveled biological reaction mechanisms.

67 ms that mimic the functionality exhibited in biological reaction networks is a key objective of syste

68 sed DNA components in synthetic chemical and biological reaction networks.

69 tation of protein function in the context of biological reaction networks.

70 powerful nonenzymatic catalysts of very slow biological reactions, notably pyridoxal phosphate and th

71 One of the most important biological reactions of nitric oxide (nitrogen monoxide,

72 to the study of reversible and nonreversible biological reactions on time scales as short as femtosec

73 imilar excision chemistry may apply to other biological reaction pathways requiring the coordination

74 t, frequently diverged domains found in many biological reaction pathways where they have adapted for

75 The ribosome catalyzes two fundamental biological reactions: peptidyl transfer, the formation o

76 strates and effectors is proposed to enhance biological reaction rates and efficiency.

77 Most biological reactions rely on interplay between binding a

78 are applicable to chemical, biochemical, and biological reaction systems and to genetic networks.

79 sms govern pattern formation in chemical and biological reaction systems, giving rise to structures w

80 ct, and that each protein catalyzes a unique biological reaction, taking advantage of specialized bio

81 d reactive intermediates in many organic and biological reactions that are difficult to observe.

82 Several classes of biological reactions that are mediated by an enzyme and

83 's surface redox through diverse abiotic and biological reactions that have distinctive stable isotop

84 gical reactions to these devices differ from biological reactions to metallic drug-eluting stents and

85 te a host of physiological functions such as biological reactions to stress, anxiety, mood, and drug

86 lable for BRS to understand how the vascular biological reactions to these devices differ from biolog

87 lop inhibitors, activators, and effectors of biological reactions using small molecule libraries are

88 lecule, indicated that there was a time when biological reactions were catalysed in the absence of pr

89 will allow for the first kinetic studies of biological reactions with millisecond time resolution un