ライフサイエンスコーパス: oxygen transfer

1 tonation of uric acid, activating it for the oxygen transfer.

2 ound I, followed by hydrogen abstraction and oxygen transfer.

3 p-hydroxybenzoate in the transition state of oxygen transfer.

4 and electrochemical, high surface area, and oxygen transfer ability, which have attracted considerab

5 yond electron transfer and electron transfer-oxygen transfer aerobic transformations, there a few exa

6 e areas: bioreactor designs for increases in oxygen transfer and decreases in shear stress; bioreacto

7 high catalytic activity and surface area to oxygen transfer and fluorescent quenching capabilities a

8 2NC10H6)2TeO with acetonitrile proceeds with oxygen transfer and gives rise to the formation of the n

9 Oxygen transfer and hydrogen migration almost coincide i

10 mechanistic peculiarities of stereoselective oxygen transfer are given attention.

11 lavin-dependent halogenases, and an array of oxygen transfer catalysts.

12 used by the FeTPP and P450 systems, with all oxygen transfers coming from an FeO entity.

13 The effect of villi density on oxygen transfer efficiency is assessed by numerically so

14 solved oxygen (DO) concentration can improve oxygen transfer efficiency, thereby reducing energy use.

15 al lineO](2+) occurs by an electron transfer-oxygen transfer (ET-OT) mechanism as supported by the ob

16 O-Au-->Au-OOH-->Au-OH-->Au-H, via successive oxygen-transfer events.

17 pentacoordinate heme sites capable of inert oxygen transfer evolved from hexacoordinate hemoglobins

18 The reaction cascade is initiated by an oxygen transfer from a N-oxide onto a gold-activated alk

19 mation is suggested following intermolecular oxygen transfer from a peroxythiocarbonyl intermediate t

20 The previously obtained ICR data of oxygen transfer from NO(2)(+) to the aromatic ring are a

21 nylamidines readily undergo enantioselective oxygen transfer from sulfur to carbon atom in the presen

22 As a biomarker for oxygen transfer from the lungs into the blood, the oxyge

23 sulfide-containing peptide cation results in oxygen transfer from the reagent anion to the peptide ca

24 The Gibbs free energies of oxygen transfer from these heterocyclic hydroperoxides t

25 surface Bronsted acidity, and rate-limiting oxygen transfer from this intermediate to alkenes, favor

26 transfer from the lungs into the blood, the oxygen transfer function ( OTF oxygen transfer function

27 he blood, the oxygen transfer function ( OTF oxygen transfer function ) was calculated.

28 OTF oxygen transfer function and volume over threshold are n

29 orrelation (r = 0.65, P = .0001) and the OTF oxygen transfer function at 6 hours showed an inverse co

30 Oxygen transfer function may serve as an early marker fo

31 with the standard dose of allergen, the OTF oxygen transfer function was decreased at 6 hours in ast

32 The oxygen transfer function was significantly lower in pati

33 alues at room air and at 100% oxygen and the oxygen transfer function were calculated.

34 Consequently Au-OH compounds are capable of oxygen-transfer generating gold hydrides, a key reaction

35 may not be sufficient to accurately describe oxygen transfer in the BMHC.

36 An oxygen transfer mechanism can explain the formation of N

37 ing hydrogen-abstraction (H-abstraction) and oxygen-transfer (O-transfer) reactivity of a series of n

38 esmethyl-TRA (ca. 40%), whereas the proposed oxygen transfer prevails for O(3) attack resulting in N-

39 O-labeling studies revealed that the S-to-C2 oxygen-transfer process involves initial formation of a

40 Four oxygen transfer rate conditions (0.8, 1.9, 8.0, and 11.9

41 oppers, ranging from 0.2 to 1.8 mg/L/year of oxygen transfer rate.

42 Studies were then conducted into a unique oxygen transfer reaction between O6-(benzotriazol-1-yl)i

43 The oxygen transfer reaction pathway was determined to be th

44 positional selectivity, as well as observed oxygen transfer reactions in the gas phase.

45 its analogues can mediate electron transfer-oxygen transfer reactions where oxygen atoms are transfe

46 nctional theory (DFT) studies and allows for oxygen-transfer reactions with electron-deficient organi

47 rticipate in hydroxylation, the mechanism of oxygen transfer remains controversial.

48 Most innovations addressed either oxygen transfer, shear induced by stirring, control of w

49 t in stabilizing the transition state of the oxygen transfer step by forming a hydrogen bond between

50 B substrate and to properly align it for the oxygen transfer step.

51 he catalyst surface, for which the selective oxygen-transfer step becomes feasible.

52 After additional proton transfer and oxygen transfer steps, benzylic alcohols are formed that

53 f the model that considers tradeoffs between oxygen transfer to eggs versus water loss from them.

54 rin consumption vary 6-fold, consistent with oxygen transfer to the amino acid being partially or ful

55 iron-oxo double bond of CYP3A4, resulting in oxygen transfer to the ortho position, is proposed.

56 N-methylquinolinium are used, while in cage oxygen transfer to the photoexcited (thio)pyrylium deriv

57 to the flavin-C4a-hydroxide with concomitant oxygen transfer to the substrate, and the dehydration of

58 mbination of electron-transfer mediation and oxygen transfer which was related to the acid/base chemi

59 ascorbic acid degradation was related to the oxygen transfer with higher losses in standard PET (53%)