ライフサイエンスコーパス: liquid-crystalline phase

1 liquid ordered phase that may coexist with a liquid crystalline phase.

2 and experimental results is very good in the liquid crystalline phase.

3 ak hydrophobic interactions, indicative of a liquid crystalline phase.

4 and on whether the bilayer was in the gel or liquid crystalline phase.

5 's TG:SE ratio, promoting SE transition to a liquid crystalline phase.

6 and is identified as a thermotropic smectic liquid crystalline phase.

7 nsport and light emission is affected by the liquid crystalline phase.

8 olate ellipsoidal type I hexagonal lyotropic liquid crystalline phase.

9 ty that averages the dipolar coupling in the liquid crystalline phase.

10 o 16:0-22:6PE-d(31)/SM (1:1) bilayers in the liquid crystalline phase.

11 umns assemble further into a two-dimensional liquid crystalline phase.

12 SM and increased acyl chain ordering in the liquid crystalline phase.

13 s from unbinding of dislocations-a 'hexatic' liquid crystalline phase.

14 ether the fluoroalkylated PC was in a gel or liquid-crystalline phase.

15 rs in bilayers of phosphatidylcholine in the liquid-crystalline phase.

16 hose in DPPC dispersions in both the gel and liquid crystalline phases.

17 nd in the design of new magnetically aligned liquid crystalline phases.

18 ular packing beneficial for the formation of liquid crystalline phases.

19 emble into nanoscale fibers, aggregates, and liquid crystalline phases.

20 ouplings for molecules dissolved in oriented liquid crystalline phases.

21 an in the SM dispersions in both the gel and liquid crystalline phases.

22 ilayers are fully hydrated and in the fluid (liquid-crystalline) phase.

23 ed by using confocal microscopy to image the liquid crystalline phases and the isotropic-nematic inte

24 ify phase transitions and classify different liquid crystalline phases and topological defects.

25 ve also confirmed uptake by the resin in the liquid-crystalline phase and release in the gel phase.

26 n to self-assemble into a hexagonal columnar liquid crystalline phase, and respond to applied electri

27 .5 A, indicating that the bilayers were in a liquid-crystalline phase, and several sharp low-angle re

28 iched CHOL, the solubility of CHOL in the CE liquid-crystalline phase (approximately 8 mol %) was mea

29 eposited from the hexagonal (H(I)) lyotropic liquid crystalline phase are shown to be excellent amper

30 amer in both the solid state and the aqueous liquid crystalline phase are well reproduced.

31 e imaging and proteomics further reveal that liquid crystalline phases are associated with selective

32 nded compounds of molybdenum and tungsten in liquid crystalline phases are described.

33 ispersed with cellulose nanocrystals to form liquid crystalline phases are developed.

34 ely little is known about how defects in one liquid crystalline phase arise from defects or deformati

35 tive magneto-LC effect in columnar hexagonal liquid crystalline phase as probed by differential scann

36 s work provides new insights into the use of liquid crystalline phases as templates for nanocrystal s

37 chain and 1 is the methyl group) do not form liquid-crystalline phases as a consequence of strong alt

38 s of the 2H NMR spectra were observed in the liquid crystalline phase at and above 0 degrees C.

39 ning calorimetry indicates a transition to a liquid-crystalline phase at 81 degrees C.

40 We also report spontaneous formation of liquid-crystalline phases at high concentrations ( appro

41 We report the discovery of a lyotropic liquid crystalline phase based on a 3-D hexagonal close-

42 The liquid crystalline phase behavior of 4-[6-(4'-cyanobiphe

43 ensions were prepared in which the lyotropic liquid crystalline phase behavior of the hybrid material

44 The aqueous, lyotropic liquid-crystalline phase behavior of the alpha-helical p

45 between them, as the baseline, we report the liquid-crystalline phase behaviors of two other related

46 The compound possesses a nematic liquid crystalline phase between 80 degrees C and 110 de

47 rface, similar to the formation of lyotropic liquid crystalline phases by common surfactants.

48 e addition of equimolar CHOL in the lamellar liquid crystalline phase causes a smaller increase in or

49 -like') macromolecules often exhibit nematic liquid crystalline phases characterized by orientational

50 N-H dipolar couplings, measured in uniaxial liquid crystalline phases, clearly establishes the relat

51 bient temperature (293 K), at which gel- and liquid-crystalline phases coexist in the peptide-free PO

52 responsible for the formation of the layered liquid crystalline phase consisting of hexagonally order

53 The liquid crystalline phase consisting of the potassium sal

54 unts of DP and other lipid components in the liquid-crystalline phase, correlating with a dramatic in

55 The bilayer periodicity in both the gel and liquid-crystalline phases decreases significantly at hig

56 e change between two distinct regions on the liquid-crystalline phase diagram: (i) a higher density h

57 g of graphene oxide flakes in self-assembled liquid-crystalline phases enables laser patterning of co

58 Thermotropic and enantiotropic liquid-crystalline phase formation of 1PnX salts is favo

59 type of lipid bilayer disk or bicelle, and a liquid crystalline phase formed by a cationic lipid.

60 tanding diverse functionalities of lyotropic liquid crystalline phases found in nature and industry a

61 n lipid bilayer in the biologically relevant liquid crystalline phase has been examined by performing

62 Both WD and ED resulted in lamellar liquid-crystalline phases, however, of different topolog

63 e with C16:0-SM bilayers in both the gel and liquid-crystalline phases; however, 30 mol % C16:0-SM re

64 suggested that freezing the LDL core into a liquid crystalline phase imposes structural constraints

65 ) to reconfigure the photonic chiral nematic liquid crystalline phase in hydroxypropyl cellulose (HPC

66 ences of the formation of a novel electronic liquid crystalline phase in its vicinity.

67 They form lyotropic liquid crystalline phases in helicogenic solvents.

68 han that of this spin label in SM in gel and liquid crystalline phases (in absolute values), indicati

69 mol % PCer, PSM and PCer mix ideally in the liquid crystalline phase; in the gel phase, PCer becomes

70 redistributes from LDs to the ER, suggesting liquid crystalline phases influence ER-LD interorganelle

71 When cooled from the untilted L(alpha) liquid-crystalline phase into the tilted gel phase, vesi

72 The liquid crystalline phase is a necessary requirement for

73 These data suggest that the LDL core in the liquid crystalline phase is characterized by the appeara

74 Interestingly, a smectic-type liquid crystalline phase is observed at temperatures bet

75 For liquid crystalline phases, it is important to understand

76 oundaries between the ordered and disordered liquid crystalline phases (L and L) were similar for SM

77 known to self-assemble into a chiral nematic liquid crystalline phase, leading to solid-state nanostr

78 ng uniform lattice orientation in frustrated liquid-crystalline phases, like cubic blue phases, is a

79 ional constraints obtained from samples in a liquid-crystalline phase lipid bilayer.

80 nment tensors through steric interactions, a liquid crystalline phase of cetylpyridinium bromide alig

81 The chiral nematic liquid crystalline phase of d(GpG) consists of long colu

82 in the simultaneous presence of a lyotropic liquid crystalline phase of nonionic surfactants as meso

83 The fully hydrated liquid crystalline phase of the dimyristoylphosphatidych

84 deposited from the hexagonal (H1) lyotropic liquid crystalline phase of the nonionic surfactant octa

85 ese copolymers form uncrosslinked, lyotropic liquid crystalline phases of large micelles between whic

86 The liquid crystalline phases of matter each possess distinc

87 Liquid crystalline phases of matter permeate nature and

88 C(n)PyPtSnSe were templated by the lyotropic liquid-crystalline phase of alkylpyridinium surfactant [

89 ese measurements point to the formation of a liquid-crystalline phase of P3HT solutions within a spec

90 TP-I and TPF4 are both highly mobile in the liquid-crystalline phase of the membrane while the inact

91 to the trends mentioned for the 1PnX salts, liquid-crystalline phases of mPnYX are found more freque

92 The observation that the liquid-crystalline phases of mPnYX salts have lower clea

93 Liquid-crystalline phases of stacked lipid bilayers repr

94 It is based on the formation of a lyotropic liquid crystalline phase on the surface of the liquid fi

95 ed to approximately 5-15 microm, whereas the liquid-crystalline phase P-d31OPC permeated to substanti

96 This liquid crystalline phase reflects right-handed circular

97 phase in equilibrium with an ordered nematic liquid crystalline phase, results in a clear phase separ

98 ly, at >= 10(1) mum scale, such as in liquid-liquid crystalline phase separation (LLCPS) of anisotrop

99 hydroxypropyl cellulose, into a cholesteric liquid crystalline phase showing structural coloration b

100 hous and that they transition into a smectic liquid-crystalline phase surrounding an amorphous core a

101 he expression of metastability, a feature of liquid crystalline phases that might be exploited in low

102 on of the known classes of lipidic lyotropic liquid crystalline phases, their structure, and their oc

103 esicle dispersions, even though the lamellar liquid crystalline phase thickness of C20BAS is only 32

104 The half-time for the liquid crystalline phase to switch is very fast and prop

105 This is the first new inverse lyotropic liquid-crystalline phase to be reported for two decades

106 rature below 43 degrees C, we attributed the liquid-crystalline phase to CE.

107 se of NFA-CER during the transition from the liquid-crystalline phase to the stable gel phase.

108 rimetry (DSC) was used to monitor the gel-to-liquid crystalline phase transition as a function of the

109 Kdo(2)-Lipid A suspensions revealed a gel-to-liquid crystalline phase transition at 36.4 degrees C (T

110 uld exert noticeable influence on the gel-to-liquid crystalline phase transition behavior of the lipi

111 The gel-to-liquid crystalline phase transition is successively weak

112 ented, with which the behavior of the gel-to-liquid crystalline phase transition observed for lipid b

113 But below the gel-to-liquid crystalline phase transition temperature, an addi

114 chain of C(20):C(20)PE can affect the gel-to-liquid crystalline phase transition temperature, Tm, of

115 roup mobility of SM both above and below the liquid crystalline phase transition temperature, whereas

116 ly efficient (3.8 +/- 2.1%) above the gel to liquid crystalline phase transition temperature.

117 ent 31P NMR was used to determine the gel-to-liquid crystalline phase transition temperatures of the

118 metry, we found that the width of the gel-to-liquid crystalline phase transition was 2 degrees C broa

119 rature during treatment was above the gel to liquid crystalline phase transition.

120 eta was examined below and above the gel-to-liquid crystalline phase transition.

121 tidylcholine phospholipids during the gel-to-liquid crystalline phase transition.

122 ospholipid alone undergoes a lamellar gel to liquid-crystalline phase transition at 66 degrees C duri

123 greater reduction in the enthalpy of gel to liquid-crystalline phase transition of DMPC MLV, (iv) hi

124 e conducted at temperatures below the gel to liquid-crystalline phase transition of the membrane lipi

125 ring has confirmed the retention of a gel to liquid-crystalline phase transition of the surfactant, o

126 C24 acyl chains, both having similar gel to liquid-crystalline phase transition temperatures).

127 oss-linked polymer is controlled by a gel to liquid-crystalline phase transition.

128 The gel-to-liquid-crystalline phase-transition temperature (T(m)) o

129 Both chiral liquid crystalline phase transitions and competing inter

130 The Tm values associated with the gel-to-liquid crystalline phase transitions for these PEs are f

131 ructural specificity effect of polyamines on liquid crystalline phase transitions of DNA and suggest

132 bility and monitor the gel-to-gel and gel-to-liquid crystalline phase transitions of SM as a function

133 The gel-to-liquid crystalline phase transitions of these 15 mixed-c

134 ing of highly unsaturated acyl chains in the liquid crystalline phase was examined for a series of sy

135 ibed here, large vesicle preparations in the liquid crystalline phase were most effective.

136 Films deposited from the hexagonal liquid crystalline phase were shown to be ion selective,

137 on could be suppressed, and room-temperature liquid crystalline phases were obtained.

138 The morphologies of three dilute liquid crystalline phases, which are widely used for bio

139 cular model for phosphocholine lipids in the liquid-crystalline phase, with a rigid backbone in the c