ライフサイエンスコーパス: decomposition product

1 e was no evidence of hemosiderin, a ferritin decomposition product.

2 es, A was the sole or major (31)P-containing decomposition product.

3 d its N-unsubstituted 3,5-isoxazolidinedione decomposition product.

4 ssible indole regioisomers, along with minor decomposition products.

5 pathway to the minor isomer leads instead to decomposition products.

6 from a foaming effect during release gaseous decomposition products.

7 Fe(VI) decay was catalyzed by Fe(VI) decomposition products.

8 r acidic or basic conditions mainly gave the decomposition products.

9 g both parent chemicals and/or their thermal decomposition products.

10 erized by cross-feeding to metabolize labile decomposition products.

11 e decomposition, by incorporating more anion-decomposition products.

12 The decomposition product, 2,4,-decadienal, was also found t

13 The decomposition products, 2,6-dihydroxyanthrone and 2,6-di

14 (2+) cluster of MutY to [4Fe-4S](3+) and its decomposition product [3Fe-4S](1+).

15 ecomposition and redox reactions between the decomposition products and catalyst are measured.

16 The thermal decomposition products and mechanisms of per- and polyfl

17 To identify the thermal decomposition products and mechanisms of perfluorocarbox

18 s a means to effectively predict electrolyte decomposition products and pathways when initially unkno

19 e) inhibited the catalytic effects of Fe(VI) decomposition products and stabilized Fe(VI) in natural

20 contain a carbonyl group, (2) particle-phase decomposition products, and (3) highly oxidized organosu

21 in is also degraded during bleaching, but no decomposition products are detected.

22 Peroxynitrite and its radical decomposition products are highly reactive nitrogen and

23 the anion, dihydrodithiins and metal complex decomposition products are preferred.

24 The fungus acquired N as decomposition products, because hyphae were not 13C-enri

25 t other benzoxazinoids, rather than just the decomposition products BOA or MBOA, have been reported i

26 The oxidation compounds and/or their decomposition products can modify protein components, wh

27 y surface connecting methanol with its final decomposition products, CO and hydrogen gas.

28 Desorption of decomposition products derived from the xerogel precurso

29 very low levels of TATP vapor from its acid decomposition products (e.g., H(2)O(2)) with limits of d

30 All the decomposition products, except 2-methyl-6-(4-methylpheny

31 d into the medium from nonenzymatic peroxide decomposition), product formation and peroxide consumpti

32 ad occurrence of metallic iron whiskers as a decomposition product formed through irradiation of the

33 Soluble electrolyte decomposition products formed at both electrodes are cha

34 More importantly, the decomposition product from bis(fluorosulfonyl)imide anio

35 H5 )(CHCO)Trip] (4), which is most likely a decomposition product from the putative ruthenium-substi

36 The flush of decomposition products from a carcass creates a hot spot

37 We report an NMR study of base-induced decomposition products from three benzylimidazolium salt

38 PBEs are indirect, actually detecting their decomposition product, H(2)O(2).

39 The extent of occupational exposure to these decomposition products has not been investigated yet.

40 (LC-MS) methods for profiling heparin lyase decomposition products have been shown.

41 s should not be neglected when precursors or decomposition products have different nearest-neighbor e

42 lytical approach detected lipids, saccharide decomposition products, hexose sugars, and major royal j

43 Major decomposition products identified include difluorophosph

44 y that DCAM can persist as a long-lived DCAN decomposition product in systems using free chlorine as

45 ncluding T98g (glioma multiforme), while its decomposition products in cell culture medium were ~8-fo

46 ing provides a general approach to detecting decomposition products in extracts of cellular metabolit

47 UV-Vis and GC-MS analyses revealed pyrene decomposition products in extracts of samples treated at

48 Accumulation of decomposition products in solutions of HU may explain th

49 However, thermal decomposition products in the battery reduce its lifetim

50 ates the high complexity of phosphorus-based decomposition products in thermally treated state-of-the

51 Its thermal decomposition products include disulfur (S2), carbon mon

52 er of more hydrophilic curcumin isoforms and decomposition products, including a compound later ident

53 The release of their less toxic decomposition products into the blood will lead to decre

54 drolysis via a radical intermediate, and the decomposition product is ESR silent.

55 the enzyme surface to form methylglyoxal (a decomposition product) is not affected.

56 ties of oxygen-deficient phases and the full decomposition products La(2)O(3) and Ni.

57 In long extended cycles, the anion decomposition product Li(2)O encourages solvent decompos

58 mass determination based on specific thermal decomposition products linked to related polymer structu

59 to elevated glucose or its alpha-oxoaldehyde decomposition product methylglyoxal.

60 sition of CH and subsequent oxidation of the decomposition products, new pathways such as direct reac

61 ssulfuration pathway with H2S representing a decomposition product of Cys-SSH.

62 reaction product with 3-acetylacrylic acid (decomposition product of norbixin) was shown.

63 Because NO(3)(-) is known to be the ultimate decomposition product of OONO(-), these results suggest

64 ld not eliminate the formation of NO(2) as a decomposition product of peroxynitrite.

65 uanine in DNA by carbonate radical anions, a decomposition product of peroxynitrosocarbonate which is

66 nstituent in guano deposits, is an important decomposition product of struvite that is an increasingl

67 esence of calf thymus DNA, indicating that a decomposition product of the peroxo-vanadate, that is im

68 There is a considerable uptake of decomposition products of 2,4-DCBP in workers of a silic

69 rm infrared (FTIR) spectroscopy to study the decomposition products of both LiBH4 and Li2B12H12 up to

70 Further reactivity of TATB toward the final decomposition products of fluid N(2) and solid carbon is

71 is essential that the design, synthesis, and decomposition products of future materials, including po

72 e disulfide S-dioxide, and GSSG as the major decomposition products of GSNO.

73 er, ion chamber, or both, induced by thermal decomposition products of inorganic salts.

74 e shows a side reaction of ethylene with the decomposition products of NMA.

75 The decomposition products of norbixin, a component of the n

76 ibution of oxenium ions as the source of the decomposition products of other O-arylhydroxylamine deri

77 lations using ReaxFF we find initial thermal decomposition products of PDMS to be CH(3) radical and t

78 lar activated carbon (GAC) influence thermal decomposition products of PFASs, and underlying mechanis

79 anvil cell may result from these, and other, decomposition products of phosphine.

80 clarifying the origin of diborane among the decomposition products of stable borohydrides, a topic o

81 d the thermal properties and to identify the decomposition products of this substance, since it has b

82 2)O(4)) formed in these mechanisms and their decomposition product polyoxide radicals (HO(2), HO(3))

83 nce many of the detected species are thermal decomposition products rather than actual SOA molecules.

84 xide-bridged diradical, *C60-O-O-C60* or its decomposition products rather than from C60*+.

85 3) NDMA formation via ONOOH/ONOO(-) or their decomposition products reacting with (i) dimethylamine (

86 product formation stemmed from peroxynitrite decomposition products reacting with mono/dichloramine.

87 t and by mechanochemical treatment, with the decomposition products readily converting into LiAlH4 at

88 This problem is caused by the secondary decomposition product(s) of the reagent and is alleviate

89 Previous researchers suggested that decomposition products such as fatty acids trigger necro

90 ctive decomposers impacts the composition of decomposition products that can form stable SOM.

91 with alternative species viewed as off-cycle decomposition products that interfere with efficient pro

92 llow release of bisphenol A, BisGMA, and the decomposition products thereof, upon exposure to water f

93 The alkylating nature of the decomposition products was further demonstrated by trapp

94 enantiomer underwent decomposition, and the decomposition products were carefully analyzed.

95 After quenching to ambient temperature, the decomposition products were measured in the DAC at press

96 radical processes mediated by peroxynitrite decomposition products were required for triggering apop

97 s then to peroxyl radicals, tetraoxides, and decomposition products, which also promote disinfection,

98 2), respectively, are also inferred by their decomposition products, which are Cp'(2)CeF, CH(2), and

99 protein lysozyme by detecting their thermal decomposition products with matrix-assisted laser desorp