ライフサイエンスコーパス: n-octanol

1 hatidylcholine (POPC) bilayer interfaces and n-octanol.

2 12, 14, and 15 between perfluorodecalin and n-octanol.

3 obtained by cocrystallizing antiamoebin with n-octanol.

4 que because it is a simpler model to explain n-octanol actions on the GABAA receptor.

5 multiple sites to exert multiple actions, or n-octanol acts as a partial agonist to manifest these ac

6 Two models were used to explain n-octanol agonistic and potentiating actions on the alph

7 A mixture of n-octanol and dithizone was introduced as an effective a

8 on ratios for selected SVOCs between air and n-octanol as well as 8 other oligomers similar in chemic

9 ns on the alpha1beta2gamma2S GABAA receptor: n-octanol binds to multiple sites to exert multiple acti

10 ilicity of each tracer was determined by the n-octanol/buffer method.

11 The measured partition coefficient in an n-octanol/buffer system of AMPO was similar to those of

12 vatized analyte was extracted using a 1.0-uL n-octanol droplet hanging from the needle tip of a GC mi

13 The n-octanol effects on the gamma-aminobutyric acid type A

14 extraction in which a synergistic mixture of n-octanol enhanced with surfactant sodium dodecyl sulfat

15 ces of phosphatidylcholine bilayers and into n-octanol, have been determined by W. C. Wimley, S. H. W

16 Coapplications of n-octanol increased peak currents evoked by 3 microM GAB

17 Conversely, the membrane intercalator, n-octanol, increased cholesterol oxidation, transfer, an

18 In addition, n-octanol modulated GABA-induced currents in a concentra

19 avior of sensitizer release in n-butanol and n-octanol occurs at an optimal temperature of 20 degrees

20 EFs) by severalfold compared with the use of n-octanol only as extractant solvent.

21 ilicity of the compounds (log P = 1.79-2.63, n-octanol/PBS).

22 One-minute preapplication of 1000 microM n-octanol slightly potentiated 3 microM GABA-induced cur

23 ne systems and finally the diisobutylamine + n-octanol system was selected to enhance the carbonation

24 Ethanol decreased the potency of n-octanol to inhibit ACh currents, possibly resulting fr

25 drophobic side-chains is larger than that of n-octanol to water transfer free energies.

26 ee energies of transferring side-chains from n-octanol to water, indicates that the magnitude of prot

27 ot observed when the peptide is dissolved in n-octanol, trifluoroethanol or sodium dodecyl sulfate mi

28 n-Octanol was also capable of evoking a small current wi

29 ations and no potentiation was observed when n-octanol was coapplied with 1000 microM GABA.

30 ctant sodium dodecyl sulfate (SDS) (0.10% in n-octanol) was applied as the extractant phase.

31 When the logarithm of the n-octanol-water partition coefficient (log K(OW)) of POP

32 ting point, vapour pressure at 20 degrees C, n-octanol-water partition coefficient and solubility in

33 in tern eggs varied inversely with log10KOW (n-octanol-water partition coefficient), shifting egg con

34 yclic PAHs, namely, water solubility (S(w)), n-octanol-water partition coefficients (K(ow)), and orga

35 positively correlated with their respective n-octanol-water partition coefficients (R(2) = 0.65).

36 tential of the chalcogenopyrylium dye or the n-octanol/water partition coefficient, log P.

37 kyl and alkyl carboxylates between water and n-octanol were determined as a measure of their lipophil