ライフサイエンスコーパス: herringbone

1 he helicity of the helix and the form of the herringbone.

2 thicker than 10 nm, coexistence of both the herringbone and brickstone arrangements was found.

3 mechanisms via the competing channels in the herringbone and parallel dimers.

4 ons, including the slanted groove, staggered herringbone, and herringbone mixers.

5 l revealed enveloped virus with the typical "herringbone" appearance of helical nucleocapsids in para

6 ties for self-inclusion leading to polymeric herringbone arrangement in one direction and that pack i

7 ing on the film thickness: for thin films, a herringbone arrangement was observed, whereas for films

8 gement, revising the previously hypothesized herringbone arrangement.

9 s revealed that Phe(11) shields Phe(6) in a "herringbone" arrangement.

10 ce reconstructions of Au (e.g., the Au(111)-'Herringbone,' Au(110)-(1 x 2)-'Missing-Row,' and Au(100)

11 The investigation of the underlying herringbone basic element and its folding to a noncanoni

12 The microfluidic device is based on a herringbone channel design, and exhibits an estimated ce

13 h-throughput microfluidic mixing device, the herringbone-chip, or "HB-Chip," which provides an enhanc

14 In contrast to the herringbone crystal packing observed for nonfused oligot

15 orted and fluid elements are stretched using herringbone features and the parabolic flow profile bein

16 molecular packing models-bricklayer (BL) and herringbone (HB)-have been proposed to explain the struc

17 Instead of a canonical helix, a noncanonical herringbone helix is formed.

18 interdimer offset face-to-face pi-pi and/or herringbone interactions, 1(2+), 1(3+), and 2(2+) show e

19 interdimer offset face-to-face pi-pi and/or herringbone interactions, all complexes show extended 1-

20 ng one-dimensional (1D) sinusoidal wrinkles, herringbone, labyrinth, and checkerboard.

21 ermal treatment, resulting in a crystalline, herringbone-like columnar structure.

22 sly distributed in a matrix with pronounced "herringbone-like" nanostructure associated with very low

23 Our self-buffering herringbone material yields an ultrahigh uniform tensile

24 When incorporated in a herringbone microfluidic device, the 3D DNA network not

25 xamine the experimental use of the staggered herringbone mixer (SHM) for the signal enhancement of a

26 is study we examine the use of the staggered herringbone mixer (SHM) to increase the efficiency of an

27 lled reactor I) and the other with staggered herringbone mixers (called reactor II), were studied for

28 e slanted groove, staggered herringbone, and herringbone mixers.

29 s facilitated by flow-mediated mixing over a herringbone mixing region in the device.

30 A fibrous herringbone-modified helicoidal architecture is identifi

31 these molecules, the phenyl groups block the herringbone motif and further guide the arrangement of t

32 ents, the solid-state assembly switches to a herringbone motif characteristic of the linear acenes.

33 crystal forms (alpha and beta), which show a herringbone motif.

34 signed with self-assembled three-dimensional herringbone nanopatterns can detect low levels of tumour

35 ucture, with a decrease of 35 degrees in the herringbone nearest neighbour angle.

36 ; there are two molecules per unit cell with herringbone packing (49-59 degree angle) and tilted abou

37 The familiar herringbone packing is characterized by large roll disto

38 tituted compound was oriented in an intimate herringbone packing motif, which allowed for p-type mobi

39 ular CT interaction resulting from a slipped herringbone packing was confirmed by X-ray crystallograp

40 centrosymmetric bilayer with an orthorhombic herringbone packing.

41 anization, including both stacked sheets and herringbone packing.

42 Examples of the layered and herringbone-packing motifs are observed for both the par

43 ases, the inserted cations expand the parent herringbone packings by reorienting the molecular anions

44 The herringbone pattern formation via intercluster interacti

45 Here, we focus on a herringbone pattern occurring in fetal intestinal tissue

46 pH of 6.0, the E proteins are arranged in a herringbone pattern with the pr peptides docked onto the

47 Our device leverages a staggered herringbone pattern, nanoparticle surface coating, and p

48 ng the fibril axis in a fashion resembling a herringbone pattern.

49 embrane (M) proteins arranged in the classic herringbone pattern.

50 Microfluidic devices with pure wavy and wavy-herringbone patterns suitable for capture of circulating

51 Ordered herringbone patterns with deterministic long and short w

52 iferromagnet at low densities to the striped herringbone phase of planar quadrupoles at higher densit

53 We propose a modified structure for the herringbone phase with a larger monoclinic beta angle, w

54 The beta-herringbone polymorph is stable, preserves its structure

55 ymer that grows almost exclusively along the herringbone reconstruction pattern, has a two component

56 tom extraction from dislocation sites of the herringbone reconstruction, mobile Au-CO complex formati

57 Chlorine adsorption initially lifts the herringbone reconstruction.

58 he formation of a Au-Cd alloy on the Au(111) herringbone reconstruction.

59 "simple" metal shows a long-range, periodic "herringbone" reconstruction, observed in 2- and 3- (but

60 The herringbone structure characteristic of the adsorption o

61 netic field, a polymorph is formed in a beta-herringbone structure instead of the ubiquitous gamma-he

62 idified alloy has a hierarchically organized herringbone structure that enables bionic-inspired hiera

63 Powder diffraction showed that this single-herringbone structure was similar to two low-energy stru

64 ne structure instead of the ubiquitous gamma-herringbone structure, with a decrease of 35 degrees in

65 2 nm in size) were seen at the elbows of the herringbone structure.

66 or the analysis of IgG capture in simple and herringbone-structured microchannels, it can be readily

67 tamaterial, consisting of monolithic silicon herringbone structures, exhibits a broadband operation i

68 robability of O2 on the reconstructed, Au111-herringbone surface is dramatically increased by the pre

69 s deposited on the clean reconstructed Au111-herringbone surface using electron bombardment of conden

70 orine atoms in the peri-positions packs in a herringbone type arrangement, while the isomer (2,3,9,10

71 nds form pi-stacking structures instead of a herringbone-type of packing motif.

72 superstructure of this cyclophane reveals a herringbone-type packing motif, leading to two types of

73 etween dense, highly branched vs less-dense, herringbone-type root systems, are important secondary d

74 w that the molecular packing motif (that is, herringbone versus slip-stacked) plays a decisive part i