ライフサイエンスコーパス: aqueous layer

1 od interface between nonpolar lipids and the aqueous layer).

2 was obtained in 21.2% overall yield from the aqueous layer.

3 striction to translational motion within the aqueous layer.

4 tioning with hexane (2 mL) and the remaining aqueous layer.

5 r osmolality at various sites, including the aqueous layer above the lung epithelium.

6 opy (cryo-EM), molecules suspended in a thin aqueous layer are rapidly frozen and imaged at cryogenic

7 egradable biopolymer that underwent a facile aqueous layer-by-layer (LbL) assembly process for the fa

8 Instead, they may result from changes in aqueous layer compounds that condition the glycoprotein.

9 oform-methanol-water mixture, where an upper aqueous layer containing gangliosides and other polar li

10 tions, in addition to an ordered interfacial aqueous layer, contribute to the delayed droplet coalesc

11 tal unit of GO colloids, and its interfacial aqueous layers critically dictate these interfacial inte

12 ding region of greater fluorescence (thicker aqueous layer), due to convergent tangential flow.

13 e and potential stability with no sign of an aqueous layer formation beneath the ion-selective membra

14 - 5 degrees , which effectively prevents the aqueous layer formation under the ISM.

15 ntly hydrophobic interface to counteract the aqueous layer formation.

16 ate is detrimental for the prevention of the aqueous layer formation.

17 While there is no evidence for an aqueous layer forming between the sensing membrane and u

18 The interfacial aqueous layer height was detected at the subnanometer le

19 to a substantial increase in the interfacial aqueous layers, improving the colloidal stability of GO

20 nvironmental behaviors of the GO interfacial aqueous layer in ion- and organic-rich water and soil.

21 stretching of the lipid layer and underlying aqueous layer, lipid movement was analyzed at five posit

22 UV radiation through a photomask with a thin aqueous layer of acrylic acid sandwiched between the PDM

23 the in situ dynamic behaviors of interfacial aqueous layers on single-layer GO.

24 Lacrimal glands function to produce an aqueous layer, or tear film, that helps to nourish and p

25 drophobic alveolar surfactant film and polar aqueous layer overlying ATII cells, and be taken up with

26 microm peak is unlikely to correspond to the aqueous layer (rather than the complete tear film).

27 an interfacial water film was assessed by an aqueous-layer test performed during potentiometric measu

28 ater film was assessed by the potentiometric aqueous-layer test.

29 sis for the establishment of a confined thin aqueous layer, the construction of disposable halide sen

30 ting a resilient response of the interfacial aqueous layer to ion-related perturbations due to intric

31 yer, while the PtdIns(4,5)P(2) moiety in the aqueous layer was specifically recognized by PtdIns(4,5)