ライフサイエンスコーパス: Prussian blue

1 f3b1 heterozygous knockout mice showed RS by Prussian blue.

2 and surface area than observed in dehydrated Prussian blue.

3 li metal cation) family of three-dimensional Prussian blues.

4 ) and NaCN leads to the isolation of the 3-D Prussian blue analogue (PBA) Na(2)Mn[Mn(CN)(6)].2H(2)O (

5 ) and NaCN leads to the isolation of the 3-D Prussian blue analogue (PBA) Na(2)Mn[Mn(CN)(6)].2H(2)O (

6 e structural properties of the mixed valence Prussian blue analogue CsFe(II)[Cr(III)(CN)6] has been s

7 composition of the ternary transition-metal Prussian blue analogue Na(alpha)Ni(1-x)Co(x)[Fe(CN)(6)](

8 h for the generation of 3D flower-like metal/Prussian blue analogue nanohybrids, namely PdCo/Pd-hexac

9 2+) in aqueous solution generates the porous Prussian blue analogue Ni(3)[Re(5)OsSe(8)(CN)(6)](2).32H

10 on polymer thin film heterostructures of the Prussian blue analogue Ni(II)b[Cr(III)(CN)6](0.7).nH2O (

11 y in situ decomposition of the corresponding Prussian blue analogue, which is adsorbed on carbon blac

12 Materials in the family of Prussian blue analogues (C3 H5 N2 )2 K[M(CN)6 ], where C

13 ter molecules coordinated to Co ions in CoFe Prussian blue analogues (PBA) has been used to reversibl

14 The expanded Prussian blue analogues 4-7 can be fully dehydrated, and

15 Co/Fe Prussian Blue analogues are known to display both therma

16 yed toward the design of new low dimensional Prussian blue analogues based on a rational molecular bu

17 Dehydration of the Prussian blue analogues CsNi[Cr(CN)(6)] x 2 H(2)O (1) an

18 Ultrafast spincrossover is studied in Fe-Co Prussian blue analogues using a dissipative quantum-mech

19 d ABA thin films consisting of two different Prussian blue analogues, where A is a ferromagnet and B

20 Hematoxylin and eosin, Prussian blue and ED-1, a monoclonal antibody murine mac

21 by evaluating the presence of iron by using Prussian blue and ferritin and microglia burden as deter

22 otentially an increase in oxidant stress and Prussian blue and ferritin staining to assess iron statu

23 ) was compared with histology of iron oxide (Prussian blue) and FITC-labeled sODN.

24 Cytochemical stains (Fontana-Masson, Prussian blue) and immunohistochemical probes (S-100, mi

25 dentification of unknown blue (i.e., indigo, Prussian blue) and yellow organic (i.e., Reseda lake, St

26 dissociation products including cyanide ion, Prussian blue, and [Fe(III)(CN)(5)(CH(3)OH)](2-) are obs

27 DA-approved, electroactive material known as Prussian Blue, are stable enough to release a fraction o

28 ared to PB) is due to the presence of FeHCF (Prussian Blue) as defects in the structure of noniron he

29 electrocatalytically reduced, by the use of Prussian blue, at the cathode.

30 Sensitivity and dynamic range of Prussian Blue based (bio)sensors in power generation mod

31 Prussian Blue based (bio)sensors known to operate at 0.0

32 Noiseless performances of Prussian Blue based (bio)sensors would open new horizons

33 n a planar three-electrode structure (with a Prussian Blue based H2O2 transducer modified working ele

34 We report on the Prussian Blue based lactate biosensor with the remarkabl

35 onalized graphene composites, represented by Prussian blue, because they can cost-effectively apply t

36 The reduced form of Prussian blue, called Prussian white, is transparent.

37 Full cells with potassium Prussian blue cathodes are demonstrated.

38 Prussian blue-chitosan-gold nanoparticle (PB-CS-AuNP) na

39 resentative examples of tridimensional Fe/Co Prussian blue compounds are described, focusing on the t

40 ode material is obtained by nucleating cubic prussian blue crystals at inhomogeneities in carbon nano

41 ored extensively in the past two decades the Prussian blue derivatives and their remarkable physico-c

42 In conjunction with a Prussian blue electrochromic display the anode can also

43 e structure of 4 to be a direct expansion of Prussian blue (Fe(4)[Fe(CN)(6)](3).14H(2)O), with [Re(6)

44 The ability of Prussian Blue, ferric hexacyanoferrate (FeHCF), to sensi

45 The Prussian blue film electrodeposited onto graphene doped

46 d carbon paste electrode functionalized with Prussian blue films (LACC/PB/GPE).

47 , the solvent-associated Fe(III) species and Prussian blue form on a 130 and 320 ps time scale, respe

48 Ruthenium Purple (RP), an analogue of Prussian Blue, has potentially advantageous electrochemi

49 Histological staining (Perls' Prussian blue), hepatic iron concentration (HIC), and he

50 en method to synthesize interlocked graphene-Prussian Blue hybrid composites as high-performance mate

51 cid at the anode leads to a reduction of the Prussian blue in the display.

52 molecular analogue of photoresponsive Co/Fe Prussian blues is described within this report.

53 ice is largely improved using a carbon black/Prussian Blue nanocomposite as a working electrode modif

54 phene oxide (rGO) was thus functionalized by Prussian blue nanocubes via chemical bonding to form a k

55 High quality Prussian blue nanocubes with no or little coordinated wa

56 the MEK inhibitor, PD-0325901 (PD901), with Prussian blue nanoparticles (PBNPs) as PTT agents, to bl

57 nnel array (NC) device that operates through Prussian blue nanoparticles (PBNPs) as redox indicator f

58 Y-shaped mixing channel was used to prepare Prussian blue nanoparticles (PBNPs) under flow rates of

59 sistance of the powered system, comprising a Prussian blue nanotubes (PB-nt) membrane cathode and a p

60 As in Prussian blue, one out of every four hexacyanide units i

61 insertion of cations into materials with the Prussian Blue open-framework crystal structure.

62 soluble Fe(CN)6(3-/4-) redox pair and solid Prussian blue particles as active materials for the two

63 A novel core-shell nanomaterial based on prussian blue (PB) coating on peculiar surface active ma

64 Epitaxial Prussian blue (PB) films are deposited electrochemically

65 ls have been synthesized simply by annealing Prussian blue (PB) microcubes.

66 conceptually new method for the synthesis of Prussian blue (PB) nanoshells with tunable size using mi

67 Success with Prussian Blue (PB) provided an appearance of contradicto

68 f the template-engaged reactions between the Prussian blue (PB) template and different alkaline subst

69 RS-based identification of insoluble indigo, Prussian blue (PB), and mixtures thereof in aged painted

70 Ferric hexacyanoferrate, also known as Prussian blue (PB), has been the most powerful material

71 deposition of the transition metal catalyst, Prussian Blue (PB), on Pt microelectrodes as the electro

72 Tumor sections were stained for Prussian blue (PB), platelet-derived growth factor (PDGF

73 abricated based on paper fluidics and uses a Prussian blue spot electrodeposited on an indium-doped t

74 the sample initiates the color change of the Prussian blue spot.

75 e primary sensors have largely relied on the Prussian Blue stain that labels cells rich in ferric iro

76 sed, intracytoplasmic particles stained with Prussian blue stain were detected for all cell lines wit

77 tensity correlated well with alpha-actin and Prussian blue stain- and DiI-positive areas (P < .01), w

78 zation of DiI fluorescence, alpha-actin, and Prussian blue stain-positive cells.

79 MR imaging of labeled cell suspensions, and Prussian blue staining for iron assessment.

80 from the scaffolds, a finding verified using Prussian blue staining for iron containing macrophages o

81 MM-OCT are validated by MRI, ex vivo MM-OCT, Prussian blue staining of histological sections, and imm

82 ized HPF in endosomes, which we confirmed by Prussian blue staining of labeled cells.

83 Prussian blue staining of skin biopsies confirmed iron-l

84 Perls' Prussian blue staining showed iron accumulation on the a

85 y transmission electron microscopy (TEM) and Prussian Blue staining, and quantified using an iron spe

86 ake was evaluated with 3,3'-diaminobenzidine-Prussian blue staining, lysosomal staining, and inductiv

87 Compounds 1d and 2d maintain the Prussian blue structure, and N(2) adsorption measurement

88 cting it to the biocathode which returns the Prussian blue to its oxidized form.

89 ity of SAMNs, superficially derivatized with prussian blue, to produce an efficient and extremely sta

90 ) complexes for the synthesis of microporous Prussian blue type solids with adjustable porosity.

91 y found in a cobalt hexacyanoferrate (CoHCF) Prussian blue-type coordination polymer.

92 incorporate these new complexes in magnetic Prussian blue-type solids are ongoing.

93 Cobalt-iron Prussian blue-type thin films, formed by chemical etchin

94 This maghemite supported nanostructured prussian blue was applied to develop a sensor, based on

95 acytoplasmic nanoparticles were stained with Prussian blue when the ferumoxides-PLL complex had magne