ライフサイエンスコーパス: pulse radiolysis

1 ion spectroscopy with chemical reduction and pulse radiolysis.

2 injected into these polymers in solution by pulse radiolysis.

3 2-, Mn(II)PDTA2-, and Mn(II)beta-EDDADP2- by pulse radiolysis.

4 roperoxo intermediate previously observed by pulse radiolysis.

5 ch higher proportion of active sites than by pulse radiolysis.

6 roethane (DCE) solution, respectively, using pulse radiolysis.

7 tivity by stopped-flow spectrophotometry and pulse radiolysis.

8 dy-state constants for catalysis measured by pulse radiolysis.

9 e, and enzymatic activity measurements using pulse radiolysis.

10 rmined by stopped-flow spectrophotometry and pulse radiolysis.

11 me-resolved infrared detection combined with pulse radiolysis.

12 rbance of superoxide at 250-280 nm following pulse radiolysis and by stopped-flow spectrophotometry.

13 ytic activity of ScMnSOD was investigated by pulse radiolysis and compared with human and two bacteri

14 solved emission spectroscopy, accompanied by pulse radiolysis and complemented by quantum chemical in

15 Classic studies with pulse radiolysis and laser flash photolysis had shown th

16 Using pulse radiolysis and observing the UV absorbance of supe

17 Here we report the use of pulse radiolysis and spectroelectrochemistry to generate

18 nate and thiocyanate anions, as evaluated by pulse radiolysis and stopped flow techniques.

19 Pulse radiolysis and stopped-flow spectrophotometry reve

20 y addition of primary amines, as measured by pulse radiolysis and stopped-flow spectrophotometry.

21 By coupling pulse radiolysis and time-resolved infrared spectroscopy

22 Using electron pulse radiolysis and transient absorption spectroscopy,

23 Pulse radiolysis and transient absorption studies reveal

24 The NiSOD activity was determined by pulse radiolysis, and a value of kcat = 1.3 x 10(9) M-1

25 Transient absorption and pulse radiolysis data for dihydroacridine provided evide

26 lated fit of the model of Bull et al. to the pulse radiolysis data.

27 x equilibria with pyrene and terthiophene by pulse radiolysis established reversible one-electron red

28 impaired by exposure to radiation during the pulse radiolysis experiment.

29 From rate constants determined by pulse radiolysis experiments (k((*)OH+Gd-DTPA) = 2.6 +/-

30 ith phenylalanine as a reference compound in pulse radiolysis experiments yielded rate constants of (

31 ifferent from the value of 4.7 reported from pulse radiolysis experiments.

32 (*)OH radicals and with OH-adducts by using pulse radiolysis, fluorimetric determination of phenolic

33 r time-resolved infrared detection following pulse radiolysis has been used to measure the nu(C ident

34 the Fe(III) absorption band observed through pulse radiolysis indicates that iron may react with Cl(2

35 the first reaction intermediate observed by pulse radiolysis is a ferrous-iron superoxo species, in

36 Flash photolysis and pulse radiolysis measurements demonstrate a conformation

37 Pulse radiolysis of aqueous solutions of alpha-(methylth

38 However, the o-semiquinone 1S generated by pulse radiolysis oxidation of the eumelanin precursor 5,

39 Here, time-resolved pulse radiolysis (PR) and stopped-flow spectroscopic stu

40 d infrared (TRIR) spectroscopy combined with pulse-radiolysis (PR-TRIR), infrared spectroelectrochemi

41 Pulse radiolysis provided a direct means to generate sin

42 In conjunction with pulse-radiolysis results, the data show that each polaro

43 ry, UV-vis and resonance Raman spectroscopy, pulse radiolysis, stopped flow, and electrospray ionizat

44 Pulse radiolysis studies demonstrate that, under identic

45 Here we report extensive pulse radiolysis studies on recombinant two-iron SOR (2F

46 Pulse radiolysis studies provided evidence for bond form

47 lectrode whereas in laser photoionization or pulse radiolysis studies, where electrons are ejected fr

48 ps and a ruthenium core were investigated by pulse radiolysis techniques.

49 Here, we show by pulse radiolysis that the mutation of the well-conserved

50 zinc chlorins (ZnChls) in the solid state by pulsed radiolysis time-resolved microwave conductivity m

51 Using pulse radiolysis to generate superoxide, we have determi

52 and G93A (hG93A) CuZn-SOD, and we have used pulse radiolysis to measure their superoxide dismutase a

53 the catalysis of the resulting mutant using pulse radiolysis to produce O(2)(*)(-).

54 ral catalytic cycle of CYP101Fe(3+) by using pulse radiolysis to rapidly supply the second electron o

55 gative polaron transport is studied by using pulse radiolysis/transient absorption at the Brookhaven

56 Pulse radiolysis was used to generate superoxide, and me

57 in NMP were measured at room temperature by pulse radiolysis with 10-11 s time resolution.

58 Using a new technique, which combines pulse radiolysis with nanosecond time-resolved infrared