ライフサイエンスコーパス: turbid

1 .e., turbid states, with State 5 as the most turbid).

2 lear streams have recently turned orange and turbid.

3 rochemical-microfiltration (MF) process from turbid (15 NTU) surface water containing moderate amount

4 in contrast to fibrils grown at pH 7.4, the turbid aggregate generated at pH 5.8 is incapable of see

5 ng polylysine-pectin complexes were slightly turbid and relatively stable to aggregation at high mass

6 biomass and light availability, whereas the turbid and shaded states had higher nutrient concentrati

7 e has displayed all the three states (clear, turbid and shaded) to investigate how species richness,

8 aining polylysine-carrageenan complexes were turbid and unstable to aggregation and precipitation.

9 orpoises) hunt and navigate through dark and turbid aquatic environments using echolocation; a key ad

10 HEPES buffer, experiments were performed in turbid aqueous solution.

11 that allows clear imaging through extremely turbid biological tissue, such as the skull, over an ext

12 nly P. acnes and produced clear plaques with turbid centers, but it lacked any obvious genes for lyso

13 Despite some limitations with turbid clinical samples, this method presents a potentia

14 lied for quantitative analysis in unmodified turbid/colored samples that included red wine, coke, cof

15 er's amyloid peptide Abeta(1-40) generates a turbid, Congo re-binding aggregation reaction product wi

16 te, clustered-vesicle structure leading to a turbid dispersion.

17 ets smaller than 100nm, contrasting with the turbid emulsions prepared with individual emulsifiers.

18 ization vision, such as enhanced contrast in turbid environments, are also possible [7, 8].

19 embrane protein crystals grown in opaque and turbid environments.

20 ter viscosity and produced more cohesive and turbid gels with less syneresis compared to PGCS.

21 ich is ascribed to the delivery of dense and turbid glacier meltwaters mixing PFAS throughout the Lak

22 iable flight reactions in the fish's dim and turbid habitat as compared with fish lacking this retina

23 we present an approach for detecting fish in turbid, highly productive estuarine systems.

24 he reduced scattering coefficient, u(s)', of turbid homogeneous samples using Spatially Offset Raman

25 ansmission distance of 27 m in PS and 4 m in turbid HR II water, demonstrating the effectiveness of t

26 ulting acylhydrazones can self-organize into turbid hydrogels or bigger microcrystals depending on th

27 ioning strength and signal-to-noise ratio in turbid (i.e. thick) samples for selection of the optimum

28 was low, 20-45 mg C m(-2) d(-1), in the more turbid inner half of the fjord, increasing 10-fold to ar

29 corresponding to mixed micelles were visibly turbid, irrespective of the eluant used.

30 Also a more turbid juice with a higher content of suspended solids c

31 phic state in both clear water and naturally turbid lakes.

32 ately predict TP concentrations in naturally turbid lakes.

33 A turbid layer found on the flanks of the volcano (in 2004

34 n is obtained and directly conjugated to the turbid layer in a noninvasive manner.

35 times of fluorescent markers hidden behind a turbid layer.

36 ic, and forensic sciences where thin, highly turbid layers mask chemically distinct subsurface struct

37 t noninvasively the presence of thin, highly turbid layers within polymers, wheat seeds, and paper.

38 ns of micrometers thick diffusely scattering turbid layers.

39 oral bleaching, we explore whether corals at turbid localities, with reduced light, are less likely t

40 The turbid, low-light waters characteristic of aquaculture p

41 cetamol) and to the overall thickness of the turbid matrix (PE) with a root mean square error of pred

42 racetamol (acetaminophen) inclusion within a turbid matrix consisting of polyethylene (PE) by monitor

43 ogy, the manner in which light propagates in turbid media has been of central importance for many dec

44 light propagation near the point-of-entry in turbid media has never been analytically described, unti

45 High-resolution imaging through turbid media is a fundamental challenge of optical scien

46 stablished ability of direct imaging through turbid media provides fundamental and practical advantag

47 ments in its ability to probe deeply through turbid media such as biological tissues.

48 ectroscopy of a heterogeneous sample through turbid media using a novel technique based on the wavele

49 jects embedded in thick (6.4 cm) tissue-like turbid media using early-arriving photons.

50 large amplitude light scattering changes in turbid media using multiwavelength analysis.

51 g the depth of optically thick layers within turbid media using spatially offset Raman spectroscopy (

52 ications, dependent on photon propagation in turbid media with general impact across fields such as b

53 ermination of the depth of buried objects in turbid media with potential applications including deter

54 work enables widefield imaging through thick turbid media, and opens new avenues in non-invasive test

55 m walks are typical of photon propagation in turbid media, scattering of particles, i.e., neutrons in

56 efficient detection of enzymatic activity in turbid media, the properties of the electron paramagneti

57 ation for increased light incident angles in turbid media, while the performance of reflectors degrad

58 h enable applications such as seeing through turbid media.

59 imaging and dealing with objects embedded in turbid media.

60 e measurement of pH in either transparent or turbid media.

61 thylacrylamide enables the detection even in turbid media.

62 temporal dynamics of nonlinear processes in turbid media.

63 f the echoes of electromagnetic radiation in turbid media.

64 ce temperatures within diffusely scattering (turbid) media in combination with high chemical selectiv

65 s to image fluorescent objects embedded in a turbid medium and its potential in clinical applications

66 d- and reverse-propagation paths through the turbid medium be identical.

67 collection of spatial information through a turbid medium by coherent Raman microspectroscopic imagi

68 the depth of a single buried object within a turbid medium combining spatially offset Raman spectrosc

69 tical properties and the phase function of a turbid medium from the profile of subdiffusive and diffu

70 using the multiple scattering of light in a turbid medium, enhanced light-matter interaction can be

71 hese systems exist in a highly scattering or turbid medium, the optical scattering effects reduce the

72 r the geometry of the optical interface of a turbid medium, thereby drastically enhancing the couplin

73 dicative of the 'twist of light' through the turbid medium.

74 tool for studying the dynamics of gain in a turbid medium.

75 rs, reflectors, and retroreflectors within a turbid medium.

76 s with varying topological charges through a turbid multiple scattering environment.

77 f development within the more poorly studied turbid nearshore areas (<10 m depth), and show that cora

78 We hypothesized that some turbid nearshore environments may act as climate-change

79 We suggest that these turbid nearshore environments may provide some refuge th

80 The turbid nearshore refuges identified in this study were l

81 Thus, protecting the turbid nearshore refuges identified in this study, parti

82 nformation from layers that are covered by a turbid (nontransparent) layer.

83 ace of thick specimens or imaging samples in turbid or opaque liquids since the optical path doesn't

84 Regime shifts towards a turbid or shaded state negatively affect the taxonomic d

85 onship became flatter after the shift to the turbid or shaded state.

86 sive images of thin sublayers through highly turbid overlayers.

87 bidity, with a 10-fold increase in the inner turbid part of the fjord.

88 cculant for removing dispersed MPs, NOM, and turbid particles from water.

89 lved natural organic matter (NOM), and other turbid particles is ubiquitous in water treatment.

90 e cell receptor-binding site and expressed a turbid plaque phenotype in BHK-21 cells.

91 eplicates in BHK and CHO cells, and a large, turbid-plaque virus that only grows in BHK cells.

92 orm small, turbid plaques on serotype 2a(2); turbid plaques appear translucent rather than transparen

93 ate effectively; low virus yields and small, turbid plaques indicated that cooperation was poor.

94 serotype Y strains but can also form small, turbid plaques on serotype 2a(2); turbid plaques appear

95 ossible by providing optical clearing of the turbid porous matrix, resulting in improved transmittanc

96 can substantially improve signal quality in turbid preparations like plant cells and deep cell layer

97 cts of localization and focusing of light in turbid randomly inhomogeneous tissue-like scattering med

98 y turbidity and biominerals formed in a high turbid reef show a more organized crystal orientation an

99 m shells Tridacna squamosa from high and low turbid reefs in the Coral Triangle.

100 responses to acute bleaching disturbances on turbid reefs off Singapore, at two depths over a period

101 ence and potential as conservation hotspots, turbid reefs-projected to expand throughout the 21st cen

102 s (P1small) and the other large plaques with turbid rims (P1large), had broader host range and produc

103 habiting a wide range of reef habitats, from turbid river deltas and stagnant back reefs to high-ener

104 n events, when sediments are remobilized and turbid runoff components enter the rivers.

105 any specific spatial offset when analyzing a turbid sample or, in turn, what magnitude of spatial off

106 arner that links the scattering pattern of a turbid sample to its thickness and scattering parameters

107 interrogating the subsurface composition of turbid samples noninvasively.

108 Current methods for detecting LM in turbid samples require multistep and complex-liquid extr

109 the scattering of emission photons in thick turbid samples severely degrades image quality at the ca

110 le variations and often arises in complex or turbid samples such as biological tissues.

111 Turbid samples were plated.

112 estimate the u(s)' coefficient of different turbid samples with an error (RMSEP) below 18%.

113 the characterization of light absorption in turbid samples.

114 al probe, termed PL-AFc, for detecting LM in turbid samples.

115 heir whiskers to hunt their prey in dark and turbid situations.

116 ater dominated by submerged macrophytes to a turbid state dominated by phytoplankton or a shaded stat

117 hreshold for regime shifts between clear and turbid states of the water column.

118 gh concentrations of suspended solids (i.e., turbid states, with State 5 as the most turbid).

119 om surface erosion, increased the density of turbid streams.

120 Epi-GLIM enables studying turbid structures that are hundreds of microns thick and

121 on (few micromolar to submicromolar), highly turbid subglacial meltwater could be filtered and colori

122 ring material-specific temperatures within a turbid sublayer of poly(tetrafluoroethylene) (PTFE) thro

123 light transport properties of a homogeneous turbid system.

124 is limited by STED laser propagation through turbid tissue.

125 o alter the optical scattering properties of turbid tissues.

126 hly resolved direct numerical simulations of turbid underflows that involve nearly 1 billion degrees

127 hypothesizes that higher-level consumers in turbid upstream regions may face heightened risks of MeH

128 om 11% to 40% of the total areal activity in turbid versus DOC-colored rivers, respectively.

129 disrupting effects observed in organisms in turbid water could be attributed to direct exposure of c

130 Fore-reef, turbid water encruster assemblages calcified at a mean r

131 Facial vibrissae are used to forage in a turbid water environment, and the largest perioral vibri

132 y either clear water with abundant plants or turbid water where phytoplankton dominate.

133 systems may not operate reliably in fresh or turbid water, or both.

134 ms may not function reliably in fresh and/or turbid water.

135 ow-through spray chamber is most suitable in turbid waters and to applications where high flow rates

136 ion, reduced water depth and wind speed, and turbid waters were the main drivers of the high temperat

137 sport and storage, (3) filters often clog in turbid waters, reducing the eDNA captured, and (4) grab

138 hat SEAS-DIC performs well in biofouling and turbid waters, with a DIC accuracy and precision of appr

139 the deposition patterns and rates of MPs in turbid waters.

140 re, rapid flushing and longer submergence in turbid waters.