ライフサイエンスコーパス: oxirane

1 copolymerization of CO(2) and a derivatized oxirane.

2 ct to the spontaneous addition of GSH to the oxirane.

3 ring scaffold, namely, an aluminum analog of oxirane.

4 w insights into the Lewis acid activation of oxiranes.

5 vinyl-substituted oxiranes, or hydroxymethyl oxiranes.

6 idation to yield a series of A2E epoxides or oxiranes.

7 via regioselective ring-opening reactions of oxirane 12 and cyclic sulfamidate 22 with lithium dialky

8 Oxirane 12 was formed in eight steps from 4, and cyclic

9 tB(+/+) mice with L-3-trans-(propylcarbamoyl)oxirane-2-carbonyl-L-isoleucyl-L-proline (CA-074 Me) als

10 hether an ethyl-2-[6-(4-chlorophenoxy)hexyl]-oxirane-2-carboxylate (etomoxir)-induced inhibition of f

11 ( R)- and ( S)-oxirane-2-carboxylate were determined to be active site-

12 se mechanism for these enzymes, (R)- and (S)-oxirane-2-carboxylate were investigated as potential irr

13 rreversible inactivation of cis-CaaD by ( R)-oxirane-2-carboxylate with two important distinctions: t

14 ent manner and only by the (R)-enantiomer of oxirane-2-carboxylate.

15 A six-step conversion of oxirane 3 to oxetane 9 is reported.

16 Epoxidation of 29a and 29b afforded oxiranes 36a and 36b which were used in alkylation of ad

17 NP-poly(A) molecule at one end covalently to oxirane acrylic beads, an affinity column was prepared f

18 enylsulfonyl)methylthiirane (SB-3CT) and its oxirane analogue is investigated computationally.

19 ion of SB-3CT is 1.6 kcal/mol lower than its oxirane analogue, and the ring-opening reaction energy o

20 .0 kcal/mol more exothermic than that of its oxirane analogue.

21 Although reactions such as oxirane and lactide polymerizations are fairly well-know

22 The epoxides include the parent oxirane and monosubstituted analogs having -CH(3), -NH(2

23 gioselective epoxide ring-opening of alkynyl oxiranes and a stereoselective aza-Cope-Mannich reaction

24 lent oxygen and nitrogen in the formation of oxiranes and aziridines; however, such reactivity is not

25 Cu(I) catalyst and a pyridine oxide, alkynyl oxiranes and oxetanes can be converted into functionaliz

26 With the oxiranes and oxetanes, the chloro derivative gave a diff

27 Unlike the synthetically exploited oxiranes and thiiranes, aziridines that lack electron-wi

28 he biosynthesis of A2E and its conversion to oxiranes are accelerated by light.

29 on, and cationic polymerization of epoxides (oxiranes), are briefly reviewed.

30 This permits the use of readily available oxiranes as alternatives to aldehydes that are difficult

31 ariety of energetic polyoxetane binders, the oxirane-based glycidyl azide polymer (GAP) has largely s

32 d ocular tissues from abcr(-/-) mice for A2E oxiranes by mass spectrometry.

33 Optically active oxiranes can be coupled with high optical purities (>96%

34 ides or related quaternary carbon-containing oxiranes can be troublesome and difficult to achieve.

35 with exclusive attack at the least hindered oxirane carbon.

36 the POC-isomer leads to the formation of an oxirane derivative with an unexpectedly high stereoselec

37 linones were converted into highly important oxirane derivatives in good yields.

38 en developed that effectively utilize chiral oxiranes derived from Katsuki-Sharpless epoxidation of a

39 followed by stereocontrolled, regioreversed oxirane formation and reductive transposition of this in

40 Thus, the gem-dimethyl acceleration of oxirane formation for 1-3 is found to be predominantly a

41 derived from the hydroxyl group of HPP, this oxirane formation reaction is effectively a dehydrogenat

42 on-borylation reactions of 2-trifluoromethyl oxirane give densely functionalized and highly versatile

43 nt with the Jacobsen catalyst to furnish the oxirane head piece in altogether 72% yield of higher tha

44 an was developed by employing donor-acceptor oxiranes in a new reaction with gamma-hydroxyenones.

45 ve alpha-oxazolidinonylallenylstannanes with oxiranes in the presence of BF3.OEt2 produced beta-hydro

46 onal study of the rearrangement reactions of oxiranes initiated by lithium dialkylamides is presented

47 lving rate-limiting formation of a transient oxirane intermediate that opens in water to give alpha-d

48 e-limiting formation of a 1,2-anhydro sugar (oxirane) intermediate.

49 Finally, we showed that the formation of A2E oxiranes is strongly suppressed by treating the abcr(-/-

50 ide the intrinsic anti tendency of the vinyl oxirane moiety and forces the cuprate to undergo syn add

51 ction media, it is possible to hydrolyze the oxirane moiety leading to 21 % yield of alpha,beta-dihyd

52 et pathway consists of a dissociation of the oxirane moiety to give a triplet carbene and aldehyde, w

53 Oxirane opening enables A-ring proton exchange, as does

54 are within hydrogen bonding distance to the oxirane or phosphonate oxygens of fosfomycin resulted in

55 y either epoxy-methoximes, vinyl-substituted oxiranes, or hydroxymethyl oxiranes.

56 five atoms inclusively, the combinations of oxirane, oxetane, and tetrahydrofuran are rather extensi

57 The relative rates of attack of ammonia on oxirane, oxetane, thiirane, and thietane were determined

58 e reaction involves Mn(II) activation of the oxirane oxygen and E44 acting as a general base.

59 ing the negative charge that develops on the oxirane oxygen in the transition state.

60 ylative 1,5-substitution of conjugated enyne oxiranes provides a diastereoselective route to (E)-conf

61 uggested as the exclusive mechanism by which oxiranes react in the presence of organolithium bases.

62 These oxiranes react with DNA in vitro, suggesting a potential

63 ynthesis of isopeptide analogues in which an oxirane replaces the scissile peptide bond.

64 etones are formed through the opening of the oxirane ring after alpha-substitution.

65 d radical-stabilizing groups adjacent to the oxirane ring for the deoxygenation reaction to occur.

66 hed by treatment of mCPBA, and the resulting oxirane ring in resin 9 was opened with various nucleoph

67 with an initial attack of phosphorane at the oxirane ring of epichlorohydrin.

68 zes the addition of glutathione (GSH) to the oxirane ring of the antibiotic, rendering it inactive.

69 N-methylamine with subsequent intramolecular oxirane ring opening and (b) a carbene insertion reactio

70 168 Hz; and when this hydrogen is cis to the oxirane ring, ((1)J[C(1)-H(1)] = 171-174 Hz.

71 catalyzes the addition of glutathione to the oxirane ring, rendering the antibiotic inactive.

72 olyl azido alcohols from terminal alkyne via oxirane ring-opening of epichlorohydrin, followed by cli

73 stereoselective epoxide formation/reductive oxirane ring-opening strategy is presented.

74 e molecules that can undergo both pyrone and oxirane ring-opening via deformylation to produce hydrox

75 undergoing Cp(2)Ti(III)Cl-mediated reductive oxirane-ring opening with concomitant intramolecular 5-e

76 hodology, developed by Miyashita, allowed an oxirane-ring-opening reaction with a double inversion of

77 ent at the C-2 position, and the presence of oxirane rings.

78 However, oxiranes such as glycidyl azide (GA) allow two ring-open

79 The oxirane synthon is obtained with an anti configuration f

80 favorable for the alkoxide obtained from the oxirane than for the thiolate obtained from the thiirane

81 attack of an active site carboxylate on the oxirane to give an ester intermediate followed by hydrol

82 al Lewis-acid-catalyzed rearrangement of the oxirane to the corresponding aldehyde via an alkyl, aryl

83 this work, we demonstrate that the forbidden oxirane-type photoproduct (the cyclopropyl ketone photop

84 omes strongly affected, making the forbidden oxirane-type photoproduct to decay more efficiently to t

85 Alternatively, the oxirane undergoes a nucleophilic substitution reaction w

86 In one mechanism, the oxirane undergoes acid-catalyzed ring opening followed b

87 at its nonheme-iron cofactor to install the oxirane "warhead" of the antibiotic fosfomycin.

88 Both (E)-cinnamyl acetate and vinyl oxirane were efficiently used to form the anti-branched

89 Unlike A2E, the oxiranes were more abundant in albino vs. pigmented abcr

90 stereospecific C-N and C-O bond formation of oxiranes with diaziridines has been accomplished to furn