ライフサイエンスコーパス: boric acid

1 cid of common concern in water desalination (boric acid).

2 ed of dissolved lithium, cobalt, cesium, and boric acid.

3 ples, thirty percent of boron was present as boric acid.

4 transport of the critical cell wall nutrient boric acid.

5 ing oligosaccharides through the addition of boric acid.

6 bose-containing compounds that can bind with boric acid.

7 .2 by treating monomeric RG-II (0.5 mM) with boric acid (1.2 mM); the dimer formed after 24 h at pH 3

8 Since the pKa of boric acid (8.55) lies near the pH of ocean water, chang

9 In boric acid (80mM, pH 8.0) running buffer system, not onl

10 are promising for the adsorptive capture of boric acid, a neutral contaminant that is difficult to r

11 To determine an ideal concentration of boric acid, a preclinical analysis was conducted.

12 e was linked to the surface of the sensor by boric acid affinity due to the rich hexadoxyl structure

13 proposed in glycosyl imprinting sensors via boric acid affinity.

14 r 24 h at pH 3.4 and 5.0, respectively, with boric acid and 0.5 m Sr2+, Pb2+, or Ba2+.

15 s a hydrophobic Boeseken complex formed from boric acid and a chiral polyhydroxy macrocyclic ligand.

16 actamase than 1:1 complexes of catechol with boric acid and are likely to contain penta- or hexacoord

17 partitioned into molecules of undissociated boric acid and are then volatised during roasting.

18 Boron is present in the soil solution as boric acid and it is in this form that it enters the roo

19 ed on the premise that the rejection of both boric acid and NDMA is governed by steric hindrance and

20 l-sodium alginate hydrogels crosslinked with boric acid and post-cured with sulfate (PVA-SA-BS) have

21 Our experiments with boric acid and sucrose revealed no apparent interaction

22 to crystallize a protactinium complex using boric acid and sulfuric acid.

23 Using boric acid and TES buffer systems, 500 microm was determ

24 cally evaluating the effects of selectivity (boric acid) and efficiency (linear polyacrylamide) enhan

25 d that NIP4;1 also transports ammonia, urea, boric acid, and H2O2 Thus, we propose that aquaporins NI

26 ns yeast infections in symptomatic patients, boric acid appears useful.

27 to 99% yield and >4000 TTN), with water and boric acid as the only byproducts.

28 at acquires a robust, transport activity for boric acid as well as other NIP II test solutes (glycero

29 ity of boronic and borinic acids, as well as boric acid, as catalysts for organic transformations.

30 is treated with the fluorophilic Lewis acid boric acid (B(OH)(3)) or silicon dioxide (SiO(2)), in th

31 Pure RG-II is efficiently dimerized by boric acid (B(OH)3 ) in vitro only if nonbiological agen

32 sequestration does not occur at pH 6.5 where boric acid (B(OH)3; pK(a) = 8.55) is the predominant spe

33 formed between poly(vinyl alcohol) (PVA) and boric acid (BA) for potential use as a wound dressing ad

34 investigated safety and efficacy of a novel boric acid-based vaginal anti-infective with enhanced an

35 bosome stalling is triggered specifically by boric acid, but the mechanisms are unknown.

36 of detection and quantification of boron and boric acid by concurrently employing neutron Compton sca

37 nd applied to samples such as boron carbide, boric acid, carborane, and borosilicate glass.

38 d AtNIP6;1 proteins, which form constitutive boric acid channels, AtNIP7;1 forms a channel with an ex

39 s residue, characteristic of established NIP boric acid channels, results in opening of the AtNIP7;1

40 Boric acid coated nanocrystals of camptothecin, an antic

41 Boric acid coating improved drug stability dramatically

42 The results of this study suggest that boric acid could be an alternative to chlorhexidine, and

43 stock mobile-phase composition consisted of boric acid, D-gluconic acid, lithium hydroxide, and glyc

44 However, when Tris-boric acid-EDTA (TBE, pH 9.1) buffer was used, the aggre

45 an extended light path and 101.3mmolL(-1) of boric acid electrolyte (pH 9.15, 30kV).

46 rabidopsis improves the plants' tolerance to boric acid excess by triggering high-B-dependent lignifi

47 CsiLAC4 contributes to plant tolerance to boric acid excess via high-B-dependent lignification of

48 2))(BO(3)) were grown out of mixed hydroxide/boric acid flux and found to crystallize in the orthorho

49 Boric acid ([Formula: see text] [Formula: see text], BA)

50 tion, competing equilibria of boroxines with boric acid generate hydroxyboroxines, and direct associa

51 to the formation of boron NPs together with boric acid (H(3)BO(3)) as an oxidation by-product coatin

52 doping and a carbon precursor as well, while boric acid H3BO3 is used as an oxidizing agent in the N2

53 on and exploiting three synergistic roles of boric acid has allowed the development of a general cata

54 tically characterise the nuclear dynamics of boric acid in an isotope-resolved manner across a broad

55 ined as arising from partial dissociation of boric acid in capillary water of green beans, where (11)

56 the purification of boron NPs from residual boric acid in deionized water, followed by their coating

57 e complex formation between ellagic acid and boric acid in ethanol solution.

58 ued by supplementing the soil with exogenous boric acid, indicating that rte is crucial for boron tra

59 5-0.1 pH unit), consistent with diffusion of boric acid into the cell followed by B(OH)(4)(-).

60 chlorhexidine irrigation (CHX); and 3) SRP + boric acid irrigation (B).

61 linical trial was to evaluate the effects of boric acid irrigation as an adjunct to scaling and root

62 The concentration of boric acid is 0.75% in this study.

63 Because boric acid is both an essential nutrient as well as a to

64 enes and alkynes at ambient temperature, and boric acid is the sole byproduct.

65 Boric acid is used in various regimens for non-albicans

66 s on the assumption that only borate, and no boric acid, is present.

67 rresponding borates by treatment either with boric acid or with diborane.

68 Boric acid permeation of the plasma membrane vesicles wa

69 profiles for human serum separated in 100 mM boric acid (pH 10), 100 mM arginine (pH 11), and 20 mM C

70 The lower rejection of neutral boric acid provided strong evidence of a less cross-link

71 s embedded with two reagents, phenol-acetone-boric acid reagent (PABR) and phenol-acetone reagent (PA

72 ial brackish water RO elements with superior boric acid rejection.

73 The reactions of LnCl(3) with molten boric acid result in the formation of Ln[B(4)O(6)(OH)(2)

74 Under acidic pH, boric acid self-assembled on the surface of drug nanocry

75 Coating driven by boric acid self-assembly had negligible effects on drug

76 eved with calmodulin in solutions containing boric acid-sodium borate (concentration > or = 0.2 M), a

77 DEAE-cellulose chromatography performed in a boric acid-sodium borate buffer removes most of the cont

78 8 or below where boron exists as the neutral boric acid species and NDMA is also a neutral solute.

79 ing to (10)B and (11)B of samples to natural boric acid standard.

80 d in 2F-Fuc-treated seedlings by addition of boric acid, suggesting that the growth phenotype caused

81 lower concentrations of total boron and free boric acid than Arabidopsis when grown with excess boron

82 and virtually no energy is expended removing boric acid, the most abundant species in solution.

83 ms a channel with an extremely low intrinsic boric acid transport activity.

84 ons of AnCl(3) (An = Pu, Am, Cm) with molten boric acid under the same conditions yield Pu[B(4)O(6)(O

85 dine, and it might be more favorable because boric acid was superior in whole-mouth BOP as well as PD

86 ers (lake water, tap water, waste water with boric acid, waste water with H2SO4) and food samples (po

87 y, non-covalent polymers from self-assembled boric acid were used as the capping reagent to replace s

88 where evaporation alters the dissociation of boric acid, which triggers the formation of acidic evapo

89 ng non-covalent polymers from self-assembled boric acid will have wide biomedical applications especi