ライフサイエンスコーパス: agglomerate

1 antly into spherical species that eventually agglomerate.

2 by previous healing agents such as chitosan agglomerates.

3 nce of the magnetic and optical signals from agglomerates.

4 the absence of the cages form structure less agglomerates.

5 e primary particulates that make up the soot agglomerates.

6 ption and scattering from simulated particle agglomerates.

7 s of light scattering and absorption by soot agglomerates.

8 reatment was required to reveal fibers among agglomerates.

9 ximately 100 nm in diameter but formed large agglomerates.

10 t coclustering multiple enzymes into compact agglomerates accelerates the processing of intermediates

11 These nanoparticles are mostly agglomerated, according to the microscopy analysis.

12 ant structures, a result of the nanoparticle agglomerates acting as nucleation points for polymer cry

13 tly, slow sedimentation and high mobility of agglomerated AgNP could be expected under the considered

14 Moreover, agglomerated AgNP were still detected after 7 days of ex

15 h the polycationic chitosan that was able to agglomerate all negatively charged interfering moieties

16 ces, which, when seen in a dot plot, tend to agglomerate along a diagonal but can also be disrupted b

17 ction, the initial isolated Mo oxide species agglomerate and convert into carbided Mo nanoparticles.

18 he tendency of the oxygen functionalities to agglomerate and form highly oxidized domains surrounded

19 When the contact area between the agglomerate and the substrate becomes sufficiently large

20 challenging task when the particles tend to agglomerate and their size is just a few nanometers.

21 d gold materials were prepared: hierarchical agglomerates and gold mirror composed of ultrafine smoot

22 improved stoves formed clearly defined chain agglomerates and independent spheres with little evidenc

23 elemental fractionation in siderite (C-rich agglomerates) and pyrrhotite/pyrite (S-rich spheres).

24 mblies, such as ellipsoidal clouds, dog-bone agglomerates, and ribbon bunches, were observed as inter

25 his eventually leads to accumulation of huge agglomerates, apparently possessing reduced prion formin

26 produce microcracking around larger crystals-agglomerates are associated with reduced mechanical prop

27 Post-DPF soot agglomerates are very few, typically large (>1-5 mum, ex

28 distributed in the film and exhibit obvious agglomerated areas.

29 They nonetheless accumulate as dry agglomerates at the ice surface, driven by direct intera

30 ZnO particles were mainly composed of small agglomerates (average sizes ranging from 133.6 to 172.4

31 HA content) showed less and smaller particle agglomerates but also a reduced defect bridging-rate due

32 e readily separated from the surfaces of the agglomerates by sonication and obtained as pure samples

33 lly confirm the model prediction that enzyme agglomerates can accelerate the processing of a shared i

34 embrane complex (IMC), fails to form in this agglomerate causing flawed segmentation.

35 alysis of porated MG cells confirmed the non-agglomerated distribution of MENPs inside the cell and n

36 al phase morphology with phase separation in agglomerated domains.

37 ercury ions, colloidal nanoparticles rapidly agglomerated due to changes of surface chemical properti

38 n vitro system (size distribution and formed agglomerate effective density); and (iii) robust numeric

39 In addition dtfA- cells do not agglomerate efficiently when shaken in suspension.

40 icles react and merge together to form large agglomerates following spikes in localized electric curr

41 article morphology includes both spheres and agglomerates for all ablated phases.

42 not dispersed randomly in the monolayer but agglomerate forming 2D nanocrystals with a hexagonal lat

43 ntal media, it is necessary to differentiate agglomerates from primary particles.

44 In contrast, blends with agglomerated fullerene domains show a much lower efficie

45 These NPs were then seen to agglomerate further over 48 h on-stream, and most rapidl

46 These agglomerates further transform into chained pyramids, wh

47 results show that, thereafter, the bacterial agglomerates grow to extremely large sizes owing to the

48 showed that tPA was strongly associated with agglomerates in coarse but not in fine fibrin.

49 and GFP-SEO fusion proteins formed parietal agglomerates in intact sieve elements as well as sieve p

50 a substratum and do not form tight cell-cell agglomerates in suspension.

51 tely measuring the effective density of nano-agglomerates in suspension.

52 the effective density and diameter of formed agglomerates in suspension.

53 nd in the lysosome-containing vesicles or Fe agglomerates in the intestine.

54 of spray drying, development of whey protein agglomerates induces formation of an early crust, and th

55 highlighting the importance of finger domain-agglomerate interactions.

56 The development of these tissue agglomerates is dependent on the function of the dorsal

57 redominantly through nanoparticle-containing agglomerates larger than the 1-100-nm aerosol fraction.

58 oxide fly ash, mineral dust, NaCl-containing agglomerates (likely from road salt), and Ca-S containin

59 (likely from road salt), and Ca-S containing agglomerates (likely from slag, a byproduct of steel pro

60 of enhancers devoid of suppressive effect of agglomerated methyl-cytosines.

61 DPF probably promotes breakout of large soot agglomerates (mostly ash-bearing) by favoring sintering.

62 CNTs was lower for nanocomposites containing agglomerated MWCNTs.

63 o these nanoobjects and their aggregates and agglomerates (NOAA).

64 At levels above 10%, toc-encap agglomerates occurred, which deteriorated the properties

65 One example of a newly discovered agglomerate of hypermethylated DMRs associated with gene

66 omplete segmentation resulting in a residual agglomerate of partially divided cells.

67 Weakly bound agglomerates of dust are present in the soil near the Co

68 Finally, very few agglomerates of Fe-oxide nanoparticles form newly from e

69 Within the agglomerates of functional groups, the primary decomposi

70 Such agglomerates of hypermethylated and hypomethylated DMRs

71 Furthermore, agglomerates of magnetic particles were found to be defl

72 opy showed that these plume UFPs were mostly agglomerates of spherules of 30-50 nm in diameter.

73 cted by enJS56A1, with or without JSRV, show agglomerates of tightly packed intracellular particles m

74 Soot agglomerates of variable sizes (<0.5-5 mum) are abundant

75 Notably, in one of these samples, larger agglomerates of ZnSt2 expanding toward the support of th

76 sly considered to comprise irregular, fluffy agglomerates on the basis of interpretations of remote o

77 sed to follow the morphological evolution of agglomerates over time during the agglomeration process.

78 controls the search space by hierarchically agglomerating partial assignments and employing statisti

79 The average agglomerate relative density and fractal dimension were

80 collapses the nano-porosity of products and agglomerates silicon domains into large crystals.

81 and without fluorescent protein tags formed agglomerates similar in structure to native P-protein bo

82 at high particle concentrations showed large agglomerate sizes and significant particle losses throug

83 cked capillary columns are best packed using agglomerating solvents.

84 TEM photomicrographs showed highly agglomerated states of nanoparticles in the products.

85 e the small aggregates with more compact and agglomerated structures outnumber the large aggregates w

86 lent salts resulted in weaker gels formed by agglomerates, suggesting a neutralization of the protein

87 ociated to single particles (tau1) and small agglomerates (taun), the key units associated to the pro

88 VID Gene Concept, a single-linkage method to agglomerate tens of millions of diverse gene/protein ide

89 The results reveal the formation of coke in agglomerates that span length scales from tens of nanome

90 of Pb(2+), AgNPs are slow to reversibly form agglomerates (the time scale of the reverse deagglomerat

91 ve- and threefold symmetries in higher order agglomerates, the supposition is that nanoparticles will

92 , inducing compaction of fibrin into bundled agglomerates tightly associated with activated platelets

93 However, when vacancies and SIAs agglomerate to form planar clusters, the migration mode

94 on of Ag atoms reaches supersaturation, they agglomerate to form seeds that then grow into Ag nanostr

95 These initial clusters are agglomerated to make hierarchical predictions of structu

96 uble modulin (PSM) surfactant peptides cause agglomerates to grow to exceptional dimensions.

97 r MD simulation, the amorphous nanoparticles agglomerate together with their periodic neighbors to fo

98 ginal amorphous spherical colloids, and then agglomerated truncated pyramids are formed.

99 quency, when detecting the signal due to MNP agglomerates (turn-on detection strategy).

100 ICPMS analysis to analyze gold nanoparticles agglomerated under controlled conditions.

101 The highest signal from agglomerates was found in the optomagnetic signal at low

102 ealed that free-standing individual CNTs and agglomerates were emitted during abrasion.

103 e (48% HA content) formed oversized particle agglomerates which supported the defect bridging but lef

104 n of about 8%, whatever the stiffness of the agglomerate, which corresponds to the beginning of shear

105 ediate (flaming) phase was dominated by soot agglomerates with AAE 1.0-1.2 and 85-100% of absorption

106 or example, steady combustion phase produced agglomerates with effective density of roughly 1 g cm(-3