ライフサイエンスコーパス: crystallisation

1 ructural surface roughness and difficulty of crystallisation.

2 Fc engineering to disfavour preferential Fc crystallisation.

3 ed and this interaction inhibited nifedipine crystallisation.

4 h incompatible elements controlled by zircon crystallisation.

5 phenomena collectively known as flow induced crystallisation.

6 lm studies reveal unique features of polymer crystallisation.

7 carrots due to ice crystals formation and re-crystallisation.

8 and chemical process design, extraction and crystallisation.

9 mation, making them promising candidates for crystallisation.

10 ents, which has allowed its purification and crystallisation.

11 tendency to aggregate, a major obstacle for crystallisation.

12 , stabilising its structure and facilitating crystallisation.

13 aged powders showed no occurrence of lactose crystallisation.

14 rove significant to our understanding of how crystallisation ages are evaluated (e.g., plagioclase-wh

15 on, solvent evaporation, liquid handling and crystallisation all while capturing reaction log data.

16 roductive, technologies (e.g. precipitation, crystallisation and aqueous solvent extraction), further

17 which facilitate the understanding of glass crystallisation and development of glass-ceramics.

18 ycerol monostearate) influences the melting, crystallisation and enthalpy of NLCs and their degree of

19 o, water fraction, and storage conditions on crystallisation and glass transition temperature (T(g))

20 and adulterated lipids in relation to their crystallisation and melting parameters were studied usin

21 The crystallisation and polymorphic properties of three sunf

22 ase-rich mushes and driving resorption, (re-)crystallisation and solid-state diffusion.

23 tes by relying on organic spacers to control crystallisation and stabilise the materials.

24 anism is developed to elucidate the periodic crystallisation and the kinetically trapped morphology a

25 etrologic history to constrain the timing of crystallisation and to interpret FAN chemical diversity.

26 ptive microtextures caused by disequilibrium crystallisation and/or melt unmixing can modify fracture

27 cted lithosphere, together favour nanometric crystallisation (and associated grain-boundary sliding)

28 a1-alpha2b, absent due to proteolysis during crystallisation, appear inessential to toxicity.

29 st part of the review, the basics of polymer crystallisation are summarized; the main factors acting

30 -the-art separation is based upon fractional crystallisation at 220 K which is highly energy intensiv

31 ics of plutons may relate to pre-emplacement crystallisation at depth, passively transported to highe

32 s they are very interesting for the study of crystallisation because diffusion, mixing and mass and h

33 nd to be a consequence of differences in the crystallisation behaviour of different TAGs.

34 d HM-lecithin was the key in controlling the crystallisation behaviour, and thereby enabled the forma

35 est that the popular view of bioactive glass crystallisation being a disadvantage for degradation, ap

36 l to a variety of molecular processes, e.g., crystallisation, biomolecular folding and condensation,

37 wo 1,4-dioxane molecules, a component of the crystallisation buffer.

38 ds are all found to be generic components of crystallisation buffers, highlighting the non-cognate li

39 Frustration of crystallisation by locally favoured structures is critic

40 t this is not due to artefacts caused by the crystallisation conditions but is most likely due to the

41 More broadly, our approach and open crystallisation data lay the foundation for accelerating

42 experiments, the largest diastereomeric salt crystallisation dataset to date.

43 A crystallisation-depletion mechanism is developed to eluc

44 ere the first to be found to undergo "living crystallisation-driven self-assembly" in solution, a con

45 -ceramics facilitated apatite nucleation and crystallisation during immersion.

46 f physical parameters (e.g., temperature) on crystallisation dynamics is of paramount importance for

47 describe various strategies employed in our crystallisation effort that could be applied to crystall

48 ture at the buried interface to modulate the crystallisation, eliminate nanovoids, passivate defects,

49 n chaperones) and the use of high-throughput crystallisation, employing "under-oil" approaches (e.g.,

50 romote layer-by-layer growth to reduce their crystallisation energy, which is comparable with Joule h

51 Magma crystallisation enhances both heterogeneous bubble nucle

52 centrations increased from 0 to 100 ppm, the crystallisation enthalpies increased from 27 to 31 J/g a

53 h all three forms were initially produced in crystallisation experiments under identical conditions,

54 Hanging-drop vapour-diffusion crystallisation experiments, using lithium sulphate as t

55 Their crystallisation extracts Fe and Ti from the melt, result

56 within an explosion cloud via rapid eutectic crystallisation from a complex Al-Fe-U-Pu-C-O melt, and

57 Nanolite crystallisation has been suggested to enhance such proce

58 osensitive channel, MscS, and its subsequent crystallisation, has provided a new paradigm for mechano

59 ed zircon record available for Toba, and the crystallisation history of Toba quartz traces an influx

60 vidence regarding the intermediate stages of crystallisation, how they manifest and further develop i

61 torial review is a basic introduction to the crystallisation in glasses and mainly focuses on silicat

62 port experimental results for rapid nanolite crystallisation in natural silicic magma and the extent

63 We thus demonstrate that oxide nanolites crystallisation increases magma bulk viscosity mainly by

64 Crystallisation is at the heart of various scientific di

65 At 140 degrees C crystallisation is retarded, prolonging the lifetime of

66 Knowing the mechanism of glass crystallisation, it is possible to predict and design a

67 Here, we investigate the perovskites crystallisation kinetics and growth mechanism in real ti

68 A deeper understanding of the crystallisation kinetics of diamond and graphite is cruc

69 The isothermal crystallisation kinetics of these fats were examined by

70 The current-induced crystallisation leads to the reduction in the correspond

71 lsification, fermentation, waste processing, crystallisation, mass transfer and production of bioacti

72 howed that SHSs and CBEs exhibited different crystallisation mechanisms according to their triacylgly

73 ntrast agents, and integral membrane protein crystallisation media.

74 present work was to assess the mechanism of crystallisation, more precisely the dominant component r

75 main areas of modern small organic molecule crystallisation, namely the inclusion of molecules withi

76 Non-classical crystallisation (NCC) pathways are widely accepted, howe

77 This unique observation is possible since crystallisation occurs below the Neel temperature of the

78 present an in situ study of the solvothermal crystallisation of a new MOF [Yb2(BDC)3(DMF)2]H2O (BDC=b

79 Crystallisation of bioactive glasses has been claimed to

80 important dietary factors for inhibiting the crystallisation of calcium oxalate kidney stones in susc

81 te micro and streak seeding allows selective crystallisation of form I or form II crystals.

82 provide suitable model systems for studying crystallisation of long chain polymers, making distinct

83 o occur via particle attachment and stepwise crystallisation of metastable precursor phases.

84 Syn-eruptive crystallisation of nanolites and their interaction is es

85 The crystallisation of nanolites impacts magma rheology, asc

86 stallisation effort that could be applied to crystallisation of other RNP particles.

87 s and slows the water molecules prevents the crystallisation of protein hydration water upon cooling.

88 owing a summary of classical methods for the crystallisation of small organic molecules, this review

89 ar crystals can be prepared by the simple co-crystallisation of tetraphenylporphyrin (TPP) with octa(

90 diffraction data are collected to follow the crystallisation of the Ru(V)-containing high temperature

91 ied surfactant layer of HM-lecithin inducing crystallisation of the shell by interfacial heterogeneou

92 hine that permits to fingerprint the primary crystallisation of triacylglycerols (TAGs) molecules and

93 e report on the counter intuitive reversible crystallisation of two-dimensional monolayer of Trisilan

94 ity of suitable, high-quality crystals, thus crystallisation often becomes the major bottleneck in pr

95 The crystallisation onset point increased (P<0.05) with incr

96 Crystallisation peaks in the DSC thermograms of the oil

97 During the crystallisation period, the nucleation possibility in dr

98 ring from repeated expansion-contraction and crystallisation pressures from precipitated salts.

99 cle simulations-including the time-consuming crystallisation process (from digital "zeroes" to "ones"

100 e parameters and electron density during the crystallisation process and Rietveld analysis shows that

101 lloidal particles, which in turn dictate the crystallisation process and the film quality.

102 onal rearrangement of the Cu site during the crystallisation process due to the presence of a trace r

103 hlight both the critical role of the initial crystallisation process in determining the operational s

104 During the crystallisation process, organic compounds from surround

105 ructures are produced dynamically during the crystallisation process.

106 Preliminarily, it is stated why the crystallisation processes are relevant in polymer scienc

107 Crystallisation processes have evolved to practical meth

108 Saccharomyces cerevisiae live cells, in the crystallisation processes of lysozyme, with different co

109 overs the basic principles behind asymmetric crystallisation processes, with an emphasis on Viedma ri

110 ies can offer towards the study of different crystallisation processes.

111 All samples studied displayed a two-step crystallisation profile that could be fitted to an expon

112 Same observation was depicted from the crystallisation profiles of BT adulterated by LD doses r

113 ams showed that DAGs changed the melting and crystallisation profiles of lard.

114 with LD did not exhibit clear changes on its crystallisation profiles.

115 of properties for these sequences including crystallisation propensity, protein disorder and post-tr

116 and diacylglycerols affected the melting and crystallisation properties in a solid fat system.

117 es of emulsifier all had an influence on the crystallisation properties of fat in the emulsions.

118 The crystallisation properties of milk fat emulsions contain

119 The melting and crystallisation properties were investigated by the dete

120 engineering steps that eventually yielded a crystallisation-ready construct which recently led to th

121 t is a consequence of the 2D precursor phase crystallisation route, which simultaneously avoids reten

122 A crystallisation screen of the purified protein led to th

123 Nucleotide co-crystallisation screening revealed that this groove bind

124 tous binding of a sulphate molecule from the crystallisation solution has facilitated an accurate des

125 pproaches that have been employed so far for crystallisation studies for the uninitiated in these tec

126 Indeed, crystallisation studies of different types of crystallin

127 of the glass transition temperature and the crystallisation temperature above T(g) is shown.

128 increased from 27 to 31 J/g and the maximum crystallisation temperature increased from -64 to -62 de

129 ating that the influence of particle size on crystallisation temperature is more pronounced in the su

130 In general, the crystallisation temperature of emulsified fats decreased

131 ed that the presence of fish oil reduced the crystallisation temperature, melting temperature, and me

132 ts of up to 5 wt% rice bran wax (RBX) on the crystallisation, tempering and storage stability of coco

133 cations, from a host matrix for proteins for crystallisation, to templates for nanoscale structures.

134 ich is capable of undergoing crosslinking or crystallisation, two competing processes that can be ada

135 rch and findings on the phenomena of polymer crystallisation under processing conditions, with partic

136 and below 10 degrees C and also the onset of crystallisation was considerably lowered.

137 Macromolecular protein crystallisation was one of the potential tools to accele

138 e most critical factor in our success in the crystallisation was the introduction of various tertiary

139 y materials can be induced using rapid photo crystallisation with circularly polarised laser light.