ライフサイエンスコーパス: cinnamaldehyde

1 ced by formalin, acetic acid, capsaicin, and cinnamaldehyde.

2 mmatory capacity was primarily attributed to cinnamaldehyde.

3 aldehydes, a hindered aromatic aldehyde, and cinnamaldehyde.

4 ctrophilic compounds such as mustard oil and cinnamaldehyde.

5 ingredients such as allyl isothiocyanate and cinnamaldehyde.

6 ctively prevented by higher release of trans-cinnamaldehyde.

7 in a chemospecific anti-aldol reaction with cinnamaldehyde.

8 duct of decarboxylation from such compounds, cinnamaldehydes.

9 for by elevated levels of benzaldehydes and cinnamaldehydes.

10 Four treatments (control, 0.1% cinnamaldehyde, 0.75% calcium chloride and combination o

11 0.31 mg GAE/g), TFC (0.50 +/- 0.01 mg QE/g), cinnamaldehyde (19.33 +/- 0.002 mg/g), eugenol (10.57 +/

12 Films containing trans-cinnamaldehyde (2-10%) showed high antifungal efficacy a

13 bes that contain 2-nitro- (1-3) and 4-fluoro-cinnamaldehyde (4-6) and applied them to the anion recog

14 ve 4-chloro-N-methyl-N-nitrosoaniline (76%), cinnamaldehyde (55%), 3-phenyl-5-hydroxyisoxazoline (26%

15 ensitive, lung-specific neurons responded to cinnamaldehyde, a TRPA1 agonist, with increases in intra

16 of 1,2,4-trimethoxybenzene, indole, and (E)-cinnamaldehyde, all blossom components, is highly attrac

17 products [e.g., allyl isothiocyanate (ITC), cinnamaldehyde, allicin, and gingerol].

18 TRPA1 activators, including cinnamaldehyde, allyl isothiocyanate (AITC), and 4-hydro

19 The cinnamaldehyde alone and a combination of cinnamaldehyde

20 Cinnamaldehyde also induced TRPA1-like inward currents (

21 included octanal, octanoic acid, octanol and cinnamaldehyde among others (all at 30microM).

22 Similarly, the oxidation of the cinnamaldehyde analogue occurs at an even higher potenti

23 75% calcium chloride and combination of 0.1% cinnamaldehyde and 0.75% calcium chloride) were used to

24 lcohol dehydrogenase subfamily that includes cinnamaldehyde and benzaldehyde dehydrogenases.

25 he cinnamaldehyde alone and a combination of cinnamaldehyde and calcium chloride treatments yielded b

26 nds with demonstrated halogenation pathways (cinnamaldehyde and citric acid) across guar gels with va

27 and evaluated in the DA reaction between (E)-cinnamaldehyde and cyclopentadiene.

28 , little to mild toxicity was seen for trans-cinnamaldehyde and eugenol, respectively, while carvacro

29 Degradation of trans-cinnamaldehyde and limonene in cucumber was evaluated un

30 wn modes) allowed for the detection of trans-cinnamaldehyde and limonene metabolites.

31 3-phenylpropionate, methyl 2-phenylacetate, cinnamaldehyde and methyl cinnamate were produced during

32 tal irritants and pungent chemicals, such as cinnamaldehyde and mustard oil.

33 ty problems with the lipophilic vanillin and cinnamaldehyde and neutralizing their volatility, produc

34 king interactions between the phenyl ring of cinnamaldehyde and phenylated SAMs allowed tuning of rea

35 ontrolling the liquid phase hydrogenation of cinnamaldehyde and related benzylic aldehydes over Pt na

36 criteria for the subsurface halogenation of cinnamaldehyde and the broad capacity for THM formation

37 The TRPA1 agonists allyl isothiocyanate and cinnamaldehyde and the TRPV4 agonist GSK1016790A caused

38 Three nanoemulsions of eugenol, cinnamaldehyde and their mixture were fabricated and tes

39 tion of the alpha,beta-unsaturated aldehyde (cinnamaldehyde) and the catalyst.

40 h three reference substrates ketoisophorone, cinnamaldehyde, and (S)-carvone.

41 rent structures, including carvone, eugenol, cinnamaldehyde, and acetophenone.

42 emicals such as allyl isothiocyanate (AITC), cinnamaldehyde, and allicin, produce nociceptive sensati

43 amon have a higher concentration of eugenol, cinnamaldehyde, and antioxidant capacity, as well as a l

44 ing nonenolizable aliphatic aldehydes, trans-cinnamaldehyde, and beta-substituted styrenes were also

45 alpha-ionone, ethyl 2-methylbutanoate, trans-cinnamaldehyde, and eugenol.

46 ymethylfurfural, anisaldehyde, benzaldehyde, cinnamaldehyde, and phenylaldehyde are commonly generate

47 rovided good encapsulation and protection of cinnamaldehyde, and the controlled release of cinnamalde

48 The cinnamaldehyde- and crotonaldehyde-derived phosphonates

49 reboxetine from commercially available trans-cinnamaldehyde are described.

50 (hydroxycinnamoyl-SCoAs) to cinnamaldehydes; cinnamaldehydes are then reduced to cinnamyl alcohols by

51 lic plant compounds, such as mustard oil and cinnamaldehyde, are TRPA1 agonists, it is unknown whethe

52 nylmethyl benzenesulfonamide and beta-chloro-cinnamaldehyde as an intermediate.

53 trophilic compounds allyl isothiocyanate and cinnamaldehyde as well as heat.

54 One refill fluid contained cinnamaldehyde at ~34% (343 mg/ml), more than 100,000 ti

55 ilic reactivity of iminium ions derived from cinnamaldehyde by a factor of 14.

56 ral properties on the hydrogenation of trans-cinnamaldehyde by using a cobalt phosphide catalyst.

57 Additionally, SJNP releases cinnamaldehyde (CA) upon CT linkage cleavage, elevating

58 This study aimed to produce cinnamaldehyde (CA)-loaded nanostructured lipid carriers

59 sunflower oil (HOSO), tricaprylin (TC), and cinnamaldehyde (CA).

60 rations of proanthocyanidins (PAC) and trans-cinnamaldehyde (CA).

61 th most other common oral irritants, such as cinnamaldehyde, capsaicin, and alcohol, which irritate m

62 ti-component coating via layer deposition of cinnamaldehyde (CIN)-doped chitosan/poly(vinyl alcohol)/

63 f base of O-carboxymethyl chitosan (CMC) and cinnamaldehyde (CIN).

64 d cinnamic acids (hydroxycinnamoyl-SCoAs) to cinnamaldehydes; cinnamaldehydes are then reduced to cin

65 MS), highlighting the bioactive potential of cinnamaldehyde, cinnamic acid, benzoic acid, coumarin, l

66 such as allyl isothiocyanate (mustard oil), cinnamaldehyde (cinnamon), and allicin (garlic).

67 ed that 2,3-butanediol, hexanal, hexanol and cinnamaldehyde contributed the most to classification of

68 However, no additional cinnamaldehyde coupling products could be detected in th

69 tives of two such compounds, mustard oil and cinnamaldehyde, covalently bind mouse TRPA1.

70 vestigated the impact of halogen radicals on cinnamaldehyde degradation rates.

71 nylmethyl benzenesulfonamide and beta-chloro-cinnamaldehyde, depending on whether one uses either NaI

72 The Passerini coupling of cinnamaldehyde derivatives affords allylic esters that m

73 vation, this study presents the synthesis of cinnamaldehyde derivatives i.e., chalcones and pyrazoles

74 lation of 2-arylimidazo[1,2-a]pyridines with cinnamaldehyde derivatives to construct fused N-heterocy

75 Wadsworth-Emmons reaction, were treated with cinnamaldehyde derivatives, acetic acid, and borohydride

76 ratio when 20 mol % of the chiral imidazole-cinnamaldehyde-derived carbamate was utilized in the rea

77 Higher release of trans-cinnamaldehyde enhanced bread crystallinity but gave low

78 Here, we investigated the toxicity of trans-cinnamaldehyde, eugenol, and carvacrol after intramuscul

79 ), antioxidant activity, and key bioactives (cinnamaldehyde, eugenol, and cinnamic acid) using two ex

80 Cinnamaldehyde, eugenol, caryophyllene, cinnamyl acetate

81 ivo vagal innervated mouse lung preparation, cinnamaldehyde evoked action potential discharge in mous

82 In both studies, trans-cinnamaldehyde followed a second-order degradation kinet

83 imp preservation, where headspace release of cinnamaldehyde from emulsions at non-contact mode was mo

84 We report here that peptidyl cinnamaldehydes function as reversible, slow-binding inh

85 ch-turnip peel extract (PS-TPE) and guar gum-cinnamaldehyde (GG-CA) for freshness monitoring and enha

86 Among the eight tested compounds, cinnamaldehyde had the greatest anti-neuroinflammatory c

87 Cinnamaldehyde halogenation proceeded most readily in bo

88 In this work, cinnamaldehyde has been encapsulated in chitosan nanopar

89 ly are salicylic acid, tannic acid and trans-cinnamaldehyde have been identified.

90 anistic insight from kinetic mapping reveals cinnamaldehyde hydrogenation is structure-insensitive ov

91 at halogenated products of additives such as cinnamaldehyde (i.e., a-chlorocinnamaldehyde and a-bromo

92 to selectively orient the reactant molecule cinnamaldehyde in a configuration associated with hydrog

93 omprised key character aroma compounds, e.g. cinnamaldehyde in cinnamon.

94 he conjugate addition of nitromethane with a cinnamaldehyde in the presence of the Jorgensen-Hayashi

95 ns are capable of forming E,E,E-trienes from cinnamaldehydes in good yield.

96 in, sinapic acid, cinnamic acid, eugenol and cinnamaldehyde) in multilevel ratios.

97 Cinnamaldehyde inhalation in vivo mimicked capsaicin in

98 nnamaldehyde, with ozone having no effect on cinnamaldehyde-insensitive fibres.

99 ic analysis of an isolated Au(iii)-activated cinnamaldehyde intermediate.

100 For the catalytic hydrogenation of cinnamaldehyde, intermediate amounts of sulfur with inte

101 rocess evolves through a [3 + 2] 1,3-DC when cinnamaldehyde is used in the presence of an azomethine

102 ic acid were tentatively identified as trans-cinnamaldehyde metabolites.

103 Interaction of trans-cinnamaldehyde modified CO functional groups of PLA and

104 Saturating activation by cinnamaldehyde or mustard oil occluded potentiation but

105 They add to cinnamaldehyde or paraformaldehyde, for example, to prod

106 Treatment with allyl isothiocyanate, cinnamaldehyde, or GSK1016790A caused an increase in ATP

107 s did not result in selective degradation of cinnamaldehyde over other compounds (i.e., benzoate and

108 Products from radical coupling of cinnamaldehydes, particularly sinapaldehyde, which were

109 uinone and the electrophilic TRPA1 activator cinnamaldehyde produced antinociception that was lost in

110 innamaldehyde, and the controlled release of cinnamaldehyde promoted sustained antibacterial efficacy

111 alf-life values (DT(50) or t(1/2)) for trans-cinnamaldehyde ranged from 2.02 to 2.49 h, while for lim

112 Trans-cinnamaldehyde reduced bacterial and fungal growth in br

113 ty in enhancing C = O hydrogenation (through cinnamaldehyde reorientation), a general phenomenon exte

114 ipeptide Gly-Glu-Glu to the para position of cinnamaldehyde resulted in an inhibitor (Cinn-GEE) of su

115 urons that express TRPA1, a mustard oil- and cinnamaldehyde-sensitive channel, and that these respons

116 inate (CAS) and two natural aldehydes (trans-cinnamaldehyde (TC) and citral) were studied by evaluati

117 t-based oregano essential oil (OR) and trans-cinnamaldehyde (TCA) was studied.

118 Trans-cinnamaldehyde (TCA), carvacrol, and eugenol were assess

119 elivery of natural antimicrobial using trans-cinnamaldehyde (TCIN) as a model compound.

120 al Diabrotica to structural analogues of (E)-cinnamaldehyde, the major attractant for Diabrotica unde

121 Cinnamaldehyde, the most specific TRPA1 activator, excit

122 ng linoleic acid (LA) to SN38 and JQ-1 via a cinnamaldehyde thioacetal (CT) bond, facilitating co-del

123 d cyclization between beta-keto enamines and cinnamaldehydes to furnish the functionalized biphenyls.

124 were present in 50% (menthol, triacetin, and cinnamaldehyde) to 80% (ethyl maltol) of the samples.

125 T60/PLA40 (PBAT/PLA) with incorporated trans-cinnamaldehyde using cast-extrusion.

126 in essential oils i.e. carvacrol, thymol and cinnamaldehyde was developed following the Quality by De

127 Cinnamaldehyde was encapsulated in chitosan nanoparticle

128 Trans-cinnamaldehyde was more compatible in PLA which exhibite

129 Vanillin and trans-cinnamaldehyde were bound to chitosan by Schiff base rea

130 yed to install a pyridyl to the alkene trans-cinnamaldehyde while Ag(I) ions are used in a second ste

131 The reaction of cinnamaldehyde with iodonium ylide 1a catalyzed by (5S)-

132 eatment of the tosylhydrazone sodium salt of cinnamaldehyde with transition metal catalysts.

133 ansient receptor potential (TRP) A1 agonist, cinnamaldehyde, with ozone having no effect on cinnamald