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1 s does not alter 5-HT1A segregation into the liquid disordered phase.
2 that electropores form preferentially in the liquid disordered phase.
3 main boundaries before it accumulates in the liquid-disordered phase.
4 at EqtII pores form predominantly within the liquid-disordered phase.
5 ed state versus cholesterol-free LUVs in the liquid-disordered phase.
6 where septin polymerized selectively on the liquid-disordered phase.
7 talline and a gel, or a liquid-ordered and a liquid-disordered phase.
8 antly higher than for extracting it from the liquid-disordered phases.
9 ndensed phases as well as liquid-ordered and liquid-disordered phases.
10 re is coexistence between liquid-ordered and liquid-disordered phases.
11 ble blue shift in liquid-ordered relative to liquid-disordered phases.
12 diffusion of fluorescently tagged lipids in liquid-disordered phase 1-palmitoyl-2-oleoyl-sn-glycero-
13 the different lipid membranes (DOPC for the liquid disordered phase and DPPC for the gel phase), and
14 These liquid-ordered domains coexist with a liquid-disordered phase and form in monolayers prepared
15 rresponding to the liquid-ordered phase, the liquid-disordered phase, and coexistence of the two phas
16 60 nm in liquid-ordered phases compared with liquid-disordered phases, and shows strong second harmon
18 measured as (7.3+/-0.8)x10(-3) s(-1) in the liquid-disordered phase at 36 degrees C is 35-times fast
20 undulations of membranes with liquid ordered/liquid disordered phase coexistence and near-critical co
21 ch differentiates liquid-ordered phases from liquid-disordered phases coexisting in model membranes u
22 ows strong second harmonic generation in the liquid-disordered phase compared with the liquid-ordered
23 Upon collapse, bilayer folds formed in the liquid (disordered) phase; curved domains shifted the nu
24 e diffusion of lipids is similar in l(o) and liquid-disordered phase domains and is not affected by t
27 ing of n-alcohols between liquid-ordered and liquid-disordered phases evolves as the chain length of
30 r spectral change between liquid-ordered and liquid-disordered phases in model membranes and distingu
31 liquid phases similar to the liquid-ordered/liquid-disordered phases in phospholipid/cholesterol mon
32 inimal peptide markers of liquid-ordered and liquid-disordered phases, indicating that ordered-domain
33 branes made from DPPC and cholesterol in the liquid-disordered phase (ld), in the liquid-ordered phas
35 regation of 5-HT1A into the cholesterol-poor liquid disordered phase of the membrane, contradicting p
36 the coexistence region of liquid-ordered and liquid-disordered phases of cholesterol containing terna
37 id-ordered phases and for all X(PGPC) in the liquid-disordered phase; POPC and PGPC form randomly mix
38 d DENV capsid proteins bound to liposomes at liquid-disordered phase regions, docked exogenous membra
40 a novel analysis, and are found to connect a liquid-disordered phase rich in diphytanoyl PC with a li
41 e of domain registration in a liquid-ordered/liquid-disordered phase-separating lipid mixture consist
42 ickness of the coexisting liquid-ordered and liquid-disordered phases, suggesting a dominant role for
43 is changed into a bilayer resembling a fluid-liquid-disordered phase surrounding ordered microdomains
45 various chain anchors in liquid-ordered and liquid-disordered phases utilizing a theoretical model o
47 erties of liquid-ordered, solid-ordered, and liquid-disordered phases were investigated by steady-sta
48 vidual tethered proteins colocalize with the liquid-disordered phase, whereas ordered protein domains