ライフサイエンスコーパス: resonance structure

1 the larger contribution of the zwitterionic resonance structure.

2 more closely approaching the Fe(III)(NO(-)) resonance structure.

3 hOBtz adopts the para-quinone methide (p-QM) resonance structure.

4 ical regions defined by the nuclear magnetic resonance structure.

5 lative stabilities of the corresponding Clar resonance structures.

6 ndscape of a molecule that sums all possible resonance structures.

7 form should be replaced by two more accurate resonance structures.

8 reduced forms of FMN-Na being stabilized by resonance structures.

9 evolves aromaticity in open-shell diradical resonance structures.

10 the LSi horizontal linePH <--> LSi(+)-PH(-) resonance structures.

11 which gives rise to significantly different resonance structures.

12 wed us to examine the energies of individual resonance structures.

13 to anion, and Fe(II) keto pi neutral radical resonance structures.

14 ctron delocalization and relate to canonical resonance structures.

15 d determined their x-ray or nuclear magnetic resonance structures; 15 of these were very close to the

16 oaches are (1) Clar's prediction of aromatic resonance structures, (2) thermodynamic stability of all

17 pectroscopy at the boundary reveals a strong resonance structure absent in the interior of the sample

18 ere, we report the solution nuclear magnetic resonance structure and dynamics of Sma0114 from the bac

19 ed as the difference between the most stable resonance structure and that of the delocalized species.

20 c delocalization between pyramidal diradical resonance structures and associated bent bonds, as it ap

21 interfere, and the characteristic asymmetric resonance structures appear in the continuum.

22 esult, ylide-like, rather than carbene-like, resonance structures are most important in the anions de

23 Resonance structures based on quintuple M-M bonding domi

24 Although many resonance structures contribute to the resonance hybrid

25 tion is reminiscent of the doubly degenerate resonance structure depiction of polyacetylene.

26 ure determination including nuclear magnetic resonance structure determination and comparative model

27 High-resolution crystal and nuclear magnetic resonance structure determinations unravel that the acti

28 This work highlights that more resonance structures do not always lead to a more stabil

29 ocalized state and its contributing covalent resonance structure for the Th(3) core bond.

30 Dominant forms of resonance structures for the aforementioned tautomeric s

31 Theoretical studies of 2 suggest a resonance structure having dominant Ti-C triple-bond cha

32 This behavior is rationalized by resonance structures hindering fast radical reactions.

33 This chromophore possesses a zwitterionic resonance structure in the ground state, as evidenced by

34 s supported by a three dimensional (3D) HCGs resonance structure in the microwave regime is presented

35 s; rather, it is composed of a collection of resonance structures in a dynamic equilibrium.

36 The resonance structures in the reduced product endow the mo

37 linear system best described by a B=N=B=N=B resonance structure involves chemical transformation of

38 The validity of this resonance structure is discussed in terms of experimenta

39 The preferred resonance structure is Fe(II)<--{:C(X)Y}(0) and not Fe(I

40 y a strong contribution of the triply bonded resonance structure [LnMn identical withSnR]Cl and were

41 The nuclear magnetic resonance structure of [C117S]YmoB and the homology mode

42 We determined that the nuclear magnetic resonance structure of a peptide containing the CTD sequ

43 Here we describe the nuclear magnetic resonance structure of a region encompassing the second

44 ed model generated from the nuclear magnetic resonance structure of a related protein, NK lysin, sugg

45 In the nuclear magnetic resonance structure of an archaeal HAMP domain, residues

46 Previous modeling on the nuclear magnetic resonance structure of CCP15-16 in the serum C3 converta

47 Since the nuclear magnetic resonance structure of MA showed that these Thr residues

48 Here, the solution nuclear magnetic resonance structure of ParG is reported.

49 as constructed based on the nuclear magnetic resonance structure of PMP-C.

50 esent the three-dimensional nuclear magnetic resonance structure of the CBP bromodomain in complex wi

51 Here we report the nuclear magnetic resonance structure of the complex between the regulator

52 resent the de novo solution nuclear magnetic resonance structure of the La domain of HsLARP6 in the b

53 The nuclear magnetic resonance structure of the lipid-bound state of this cyt

54 We report here the nuclear magnetic resonance structure of the major intramolecular G-quadru

55 The nuclear magnetic resonance structure of the major VEGF G-quadruplex shows

56 We describe the solution nuclear magnetic resonance structure of the Moloney murine leukemia virus

57 ations of a recent micellar nuclear magnetic resonance structure of the natural killer (NK) cell-acti

58 The nuclear magnetic resonance structure of the prohead RNA E-loop hairpin, r

59 urpose, we first solved the nuclear magnetic resonance structure of the RING domain of TRIM5alpha and

60 Nuclear magnetic resonance structure of the TMH in bicelles shows distinc

61 We present here the nuclear magnetic resonance structure of the TRIM5 B-box 2 domain and iden

62 sistent with the crystal or nuclear magnetic resonance structure of these or related interactions.

63 Nuclear magnetic resonance structures of 9 of 12 designed 7- to 10-residu

64 Nuclear magnetic resonance structures of apolipoprotein-detergent complex

65 -resolution radiographic or nuclear magnetic resonance structures of isolated components into lower r

66 re, we describe crystal and nuclear magnetic resonance structures of KaiB-KaiC,KaiA-KaiB-KaiC, and Ci

67 at ca. 1200 K, sulfinyl isocyanate, bearing resonance structures of O=C-N=S=O and O=C=N-S=O, has bee

68 The crystal and nuclear magnetic resonance structures of p16 from Escherichia coli and Ba

69 etworks within the nanoclusters resemble the resonance structures of polycyclic aromatic hydrocarbons

70 l analysis of the available nuclear magnetic resonance structures of PrP(C), we explore the propensit

71 The resonance structures of the derivatives rationalize thei

72 ps to reconcile the crystal/nuclear magnetic resonance structures of the TonB carboxy terminus with c

73 bution of all the 38 native nuclear magnetic resonance structures on the obtained FES, analyzing inte

74 of bond localization in accordance with the resonance structure predicted by the Clar model.

75 these and related derivatives delineate the resonance structures predominant in these molecules.

76 ce analysis demonstrated the significance of resonance structures, reducible functional groups, reduc

77 in cyclic ketones with and without aromatic resonance structure representations, in tautomers and pe

78 mbrane (PM), and a previous nuclear magnetic resonance structure showed that both tyrosines of the CD

79 u-H)W] core can be described by a variety of resonance structures, some of which possess multiple bon

80 The indolo[3,2-b]carbazole core has a larger resonance structure that includes 3 phenyl rings, and th

81 species by disrupting the equilibrium of the resonance structures that constitutes the proposed CR mo

82 nalized by evaluating the aromaticity of the resonance structures that contribute to spin-delocalizat

83 s, and capable of supporting tunable plasmon resonance structures that span the entire visible spectr

84 ed in these transformations are described by resonance structures that suggest beta-elimination.

85 In these charge-separated resonance structures, the uranium center is oxidized to

86 In the CheA(S) 'P1-CheZ nuclear magnetic resonance structure, these residues form an interaction

87 ansfer property of PT-TPA forms a stabilized resonance structure to accept electrons from perovskites

88 sures the stabilization from the most stable resonance structure to the delocalized energy-minimum st

89 increased contributions of the zwitterionic resonance structures to the overall hybrid.

90 The dual-resonance structure used in this study introduces low-re

91 rpes virus zinc ring domain nuclear magnetic resonance structure was used for homology-based modeling

92 (one pi and three sigma MOs), an analysis of resonance structures was performed for the O(h)Al(6)(2-)

93 g Na(V)1.5 carboxy terminus nuclear magnetic resonance structure, we construct a model of the predict

94 We found that the Clar's resonance structures were able to predict the least stab

95 at 1105 cm(-1), which can be explained by a resonance structure with an O(2) double bond.

96 ier dynamics are studied on the same plasmon resonance structure with and without adsorbates.

97 B-N fusion in BNPz1-BNPz3 induces a quinoid resonance structure with significant C-N(py) double bond

98 preferential oxidation of a cyclohexadienyl resonance structure with the unpaired electron localized