ライフサイエンスコーパス: Chelex

1 alysis of Fur against EDTA or treatment with Chelex.

2 emplate DNA was prepared by boiling cells in Chelex.

3 mpared the use of Empore chelating disks and Chelex 100 resin for the selective removal of unchelated

4 umn containing a strong metal binding resin (Chelex 100).

5 deferrated with the cationic exchange resin Chelex 100.

6 sis (PCA-LDA), it was demonstrated that both Chelex-100 and Metsorb form chemical bonds with ZnO NP a

7 e DGT binding agents, commercially available Chelex-100 and Metsorb, to investigate whether these mat

8 (DGT) technique with a mixed binding layer (Chelex-100 and the titanium dioxide based adsorbent Mets

9 The water passed through a Chelex-100 cation exchange column to collect dissolved l

10 The thermal cycler and Chelex-100 extraction method yielded DNA capable of ampl

11 Thermal cycler and Chelex-100 extraction of nucleic acid is reliable, quick

12 These were Chelex-100 for EDTA and CyDTA, Amberlite CG50 for TmDTA

13 40-70% lower than predicted, suggesting that Chelex-100 is not suitable for Al measurements at high p

14 or samples treated by the thermal cycler and Chelex-100 method.

15 in freshwater and marine water using either Chelex-100 or Metsorb (a titanium dioxide-based binding

16 After treatment with Chelex-100 to remove traces of paramagnetic ions, at pH

17 Chelex-100 treatment of the reaction mixture produced ma

18 % of sections versus 54% using microwave and Chelex-100, 15% with classical xylene-based extraction a

19 commercial availability of both Metsorb and Chelex-100, the higher accuracy of Metsorb for measuring

20 Mutation of znuACB caused a growth defect in Chelex-100-treated PMH2 growth medium, which was allevia

21 ed by the treatment of phosphate buffer with Chelex-100.

22 efficient complex disruption was achieved by Chelex 110 resin (Na+ form) treatment of copper-complexe

23 n addition of Ag+ to Zn7MT in the absence of Chelex, a Ag18MT species forms as the kinetically-favore

24 The MBL that consists of a combination of Chelex and ferrihydrite at a ratio of 1:2 has the greate

25 h a mixed-binding layer (MBL), consisting of Chelex and ferrihydrite for measurements of both metals

26 R) demonstrated that retention of ZnO NPs by Chelex and Metsorb binding layers occurs through chemiso

27 In this work the penetration into the Chelex binding layer of complexes of Ni with nitrilotria

28 diffusive gradients in thin films (DGT) and Chelex column, were used to understand whether differenc

29 een MBL-DGT measurements and ferrihydrite or Chelex DGT were obtained for As, Cd, Cu, Pb, and Zn in w

30 Metsorb-DGT (CMBL/CMetsorb = 0.84-0.94) and Chelex-DGT (CMBL/CChelex = 0.88-1.11) measurements.

31 generally agreed well with those measured by Chelex-DGT (DMBL/DChelex = 0.97-1.05), Metsorb-DGT (DMBL

32 MBL) DGT technique was evaluated against the Chelex-DGT and Metsorb-DGT techniques, and all elution e

33 rmed that Metsorb-DGT was more accurate than Chelex-DGT for the measurement of dissolved Al in typica

34 Conversely, deployment of Chelex-DGT in synthetic seawater and freshwater (pH >/=7

35 h (0.001-0.7 mol L(-1) NaNO(3)), whereas the Chelex-DGT measurement was only independent of ionic str

36 significant advantages over the ferrihydrite-Chelex-DGT method reported previously.

37 rately over the entire 4 day period, whereas Chelex-DGT only measured Mn accurately up to 2 days.

38 Similar deployments of Chelex-DGT showed linear uptake at pH 5.05 (R(2) = 0.994

39 The formation of Ag18MT in the absence of Chelex explains why more than 12 equiv of Ag+ is require

40 Pooled Chelex extraction of DNA, followed by nested PCR of cyto

41 The amounts of DNA in Chelex extracts from stains on two untreated high-purity

42 h larger but somewhat more variable than the Chelex extracts.

43 but also somewhat less variable than for the Chelex extracts.

44 ng Fe, which would not be possible using the Chelex-ferrihydrite binding layer.

45 The superior uptake kinetic for Chelex indicates that it is a better candidate for furth

46 radients in thin films (DGT) equipped with a Chelex or ferrihydrite binding gel has been designed to

47 sted commercially available DGT devices with Chelex resin for plutonium bioavailability measurements

48 eaction of Ag+ with Zn7MT in the presence of Chelex resin include Zn4Ag6MT and Ag12MT.

49 Chelex resin influences the titration reaction either by

50 The use of Chelex resin to remove unbound metal ions was found to i

51 he addition of a metal chelator, by previous chelex resin treatment of the buffer, or by the addition

52 diffusive gradients in thin film (DGT) with Chelex resin, which binds free mineral ions, sprouting w

53 We have developed an efficient and rapid Chelex resin-based ChIP procedure that dramatically redu

54 Second, the addition of manganese to the Chelex-treated BSK-II enhanced SodA expression.

55 cells incubated in medium supplemented with Chelex-treated fetal bovine serum, to remove metal ions,

56 Chelex treatment and iron chelators decreased H(2)O(2) g