ライフサイエンスコーパス: in confined

1 In confined 3D microenvironments, FMN2 promotes cell sur

2 Cell migration in confined 3D tissue microenvironments is critical for

3 ew studies on asymmetric reactions catalyzed in confined achiral cavities.

4 tuned for numerous vapour sensing scenarios in confined areas or as individual nodes for distributed

5 c explosion could be particularly beneficial in confined biological and nanoscale environments.

6 rtial desolvation when cations were adsorbed in confined carbon pores.

7 In confined chiral nematic liquid crystals, this self-as

8 by injection of one reactant into the other in confined conditions feature a wealth of new patterns

9 In confined conditions where films were prepared to a th

10 gram that predicts a wrinkle-scar transition in confined crystalline sheets at a critical value of th

11 Although the interest in confined crystallization, nanosized devices, and poro

12 icle facilitated by evaporation-condensation in confined domains.

13 en-bonding structure on interfacial phase or in confined environment have drawn wide attentions.

14 be useful for studying chemical reactivities in confined environments and for synthesizing molecules

15 the growth and division of individual cells in confined environments are ubiquitous, yet little work

16 is possible to differentiate slow diffusion in confined environments caused by different mechanisms.

17 llenge because such crystallization occuring in confined environments is difficult to observe directl

18 of polymorphs in recent years, polymorphism in confined environments is still poorly understood, par

19 he implications of these results for folding in confined environments such as the chaperonin cavity i

20 ue because they house seriously ill patients in confined environments where antibiotic use is extreme

21 (plane group p6mm) mesoporous carbon phases in confined environments, as thin films and within the p

22 enable fundamental studies of mass transport in confined environments, as well as more energy-efficie

23 To study slow mass transport in confined environments, we developed a three-dimension

24 to systematically study mechanotransduction in confined environments.

25 lization at complex interfaces, particularly in confined environments.

26 Quantum systems in confined geometries are host to novel physical phenom

27 forces involved and predicting flow patterns in confined geometries is lacking.

28 e-diffusive transport in the bulk region and in confined geometries of reconstructed and computer-gen

29 well-specified control of ionic interactions in confined geometries profoundly influences the transpo

30 to-optical effects can therefore be realized in confined geometries using few or even single impurity

31 ans of controlling light-matter interactions in confined geometries, resulting in a wide range of app

32 ly to be important whenever reactions happen in confined geometries.

33 s was analogous to that of colloidal systems in confined geometries.

34 imental test bed for diffusion of 2D objects in confined geometry.

35 otions and accelerate the hydration dynamics in confined groove sites.

36 devices is the skyrmions' magnetic stability in confined helimagnetic nanostructures.

37 espectively, with losses occurring primarily in confined, higher-gradient streams that provide only m

38 s, and pressure solution and crystallization in confined hydrosystems.

39 nt and specific labelling of target proteins in confined intercellular and organotypic tissues, with

40 -solid transitions (LLST) are known to occur in confined liquids, exist in supercooled liquids and em

41 explore the transport of ions and molecules in confined liquids.

42 s during gating, probes the environment even in confined locations, and introduces minimal interferen

43 We report that deposition in confined micro-/nanoreactors overcomes this difficult

44 vents damage to the nucleus during migration in confined microenvironments.

45 ation is a major mechanism of cell migration in confined microenvironments.

46 tion polymerization for surface modification in confined microgeometries with both nonfunctionalized

47 They spend much of their time in confined motion ( approximately 110 nm diameter), but

48 with fluorescent dyes or sQDs were diffusing in confined nanodomains in PSDs, which were stable for 1

49 ci, and we show that the looping time occurs in confined nanometer regions.

50 ity to incorporate different charged species in confined nanospace by ion-exchange.

51 abundance of knots in the globule phase and in confined polymers, and their rarity in the swollen ph

52 chemistry and reactivity of small molecules in confined pores using advanced diffraction and spectro

53 Scotland prohibited smoking in confined public places on March 26, 2006.

54 namic properties and phase behavior of water in confined regions can vary significantly from that obs

55 f fractured cement, was found to be enhanced in confined regions having limited access to CO2.

56 d versatile tool to measure ionic activities in confined samples.

57 specially important for the remaining waters in confined sites at the protein interface.

58 -dimensional (2D) substrata and individually in confined spaces and invasion in 3D matrices.

59 s of our results for the folding of proteins in confined spaces are outlined.

60 ers with remote magnetic-responsive motility in confined spaces have been developed.

61 is notoriously difficult to probe reactions in confined spaces in real time.

62 tinuing expansion of NSC-derived cell masses in confined spaces in the spinal cord and brain could pr

63 Crystals are self-assembled reproducibly in confined spaces of 100 nm diameter with pitch down to

64 Autonomous flight in confined spaces presents great scientific and technic

65 tion in tight spaces, and chemical reactions in confined spaces require an understanding of water-med

66 cts of viscogens on macromolecular processes in confined spaces should be similarly informative in ot

67 In confined spaces such as capsules and the active sites

68 platform which is important for ion sensing in confined spaces such as the medium surrounding cell c

69 nalysis of a wide range of velocity profiles in confined spaces that measure a few micrometers in dim

70 on 2D surfaces, Rho is critical for movement in confined spaces, but is largely redundant for motilit

71 es is a natural tendency of microbes growing in confined spaces, contributing to microbial pathogenes

72 flocculation, hindered behavior of particles in confined spaces, jamming and dispersion in flow.

73 number of situations such as protein folding in confined spaces, lubrication in tight spaces, and che

74 Water exhibits remarkable properties in confined spaces, such as nanometer-sized droplets whe

75 a prospective adsorbent for humidity control in confined spaces, such as space shuttles, aircraft cab

76 To define the limits of body compression in confined spaces, we conducted dynamic compressive cyc

77 lowing increasingly delicate maneuverability in confined spaces, with excellent stone clearance and e

78 ggregate formation and transport of asbestos in confined spaces.

79 to understand and predict similar processes in confined spaces.

80 ntly less is known about its effect on water in confined spaces.

81 associated with ligand-receptor interactions in confined spaces.

82 for those performing high-pressure cleaning in confined spaces.

83 atory tract, intranasal inoculation resulted in confined spread to regions corresponding to olfactory

84 Domain-wall propagation in confined structures is of basic interest and critical

85 he recent discovery of a spiral-vortex state in confined suspensions of Bacillus subtilis to study th

86 and transport of colloids and microorganisms in confined systems as well as unsaturated porous media.

87 ered composite fluids are sometimes observed in confined systems of rather chaotic initial states, fo

88 an important morphology-determining variable in confined systems, and, in biological membranes, it ma

89 rstanding of the origin of coherent rotation in confined tissues, and extracts useful insights into t

90 nal MSD analysis to measure diffusive motion in confined trajectories; and spline-curve spatial analy

91 LC state due to assembly of the chromophore in confined two-dimensional layers.

92 use of antibiotics, concentration of animals in confined units, and long distances and frequent movem

93 ng finding that reaction acceleration occurs in confined-volume solutions sets up an apparent conundr

94 thods applied to study accelerated reactions in confined-volume, high-surface-area solutions.

95 actors are noted as is reaction acceleration in confined volumes and possible future scale-up.

96 (instrumentally induced) redox cycling plays in confined volumes of enclosed microchannels.

97 crofluidic device that allows crystal growth in confined volumes to be studied in situ is used to pro

98 ability to create rapid tissue modification in confined volumes without directly contacting the myoc

99 s of random knotting of equilateral polygons in confined volumes.

100 lysis of complex bacterial self-organization in confined volumes.

101 This difference in confined water dynamics likely arises from the signif

102 ted minimum in the bulk is completely absent in confined water, independent of the droplet size since

103 as focused on the mechanism of this reaction in confined-water media and the extent of solvation need

104 We showed that islet transplantation in confined well-vascularized sites like the epididymal

105 Blinking, previously seen in confined zero- and one-dimensional systems has recent