ライフサイエンスコーパス: electroosmosis

1 to the level comparable to injection through electroosmosis.

2 tens of kilovolts) still effectively altered electroosmosis.

3 e lateral vortices are created by DC-induced electroosmosis.

4 netic flows (EF) such as alternating current electroosmosis (ACEO) and the electrothermal flow (ETF)

5 AC electroosmosis (ACEO) flow and label-free electrochemica

6 mes diffusion-limited reactions with applied electroosmosis and dielectrophoresis forces.

7 yield a pressure-gradient that counteracted electroosmosis and diminished the net fluid flow in the

8 (PDMS) using methylcellulose (MC) to reduce electroosmosis and peak drift.

9 and lipophilic residues profoundly inhibited electroosmosis and, presumably, peptide flux.

10 rokinetic flow (combined electrophoresis and electroosmosis) and dielectrophoresis.

11 es of dielectrophoresis, electrophoresis, ac-electroosmosis, and Brownian motion.

12 d through the channel by electrophoresis and electroosmosis, and to be isolated according to their ch

13 ields, suggesting that mechanisms other than electroosmosis are involved.

14 results of our initial attempt to develop an electroosmosis-based nanopipettor.

15 Control of electroosmosis by an external voltage in capillaries of

16 The efficiency for the control of electroosmosis by the applied external field is improved

17 e identified, including channel passivation, electroosmosis control, and IEF linearity control.

18 ulsion induced by concentration-polarization electroosmosis (CPEO) on the particle surface and the fl

19 m this phenomenon concentration-polarization electroosmosis (CPEO).

20 phoretic velocity of the analyte exceeds the electroosmosis-driven bulk fluid flow velocity at only t

21 Electroosmosis-driven molecular translocation has been o

22 system and whose triggering derives from the electroosmosis effect.

23 low-dispersion geometries are applicable to electroosmosis, electrophoresis, and some pressure-drive

24 in which sample migration was realized using electroosmosis/electrophoresis.

25 sly developed a perfusion technique based on electroosmosis (EO), called EO push-pull perfusion (EOPP

26 Electroosmosis has been utilized to pump solutions at fl

27 both outlet channels of the tee by reducing electroosmosis in the ground channel relative to that of

28 Voltage-dependent creep seems to arise from electroosmosis in the seal.

29 are such that there is less fluid coming by electroosmosis into the cross from the sample/reagent ch

30 he sample/reagent channel than is leaving by electroosmosis into the separation and waste channels.

31 Spatially selective reduction of electroosmosis is accomplished by coating the walls of t

32 Independent control of electroosmosis is important for separation science techn

33 he solution is driven across the membrane by electroosmosis is responsible for solute accumulation.

34 Since the pump is based on electroosmosis, it has no moving parts.

35 particle manipulation but rather the sum of electroosmosis, linear and nonlinear electrophoresis.

36 erpinning the translocation mechanism (i.e., electroosmosis or electrophoresis), pulse direction (i.e

37 c coating with CTAB can be used to eliminate electroosmosis or to reverse its direction, depending on

38 Electroosmosis, originating in the double-layer of a sma

39 Results from these studies predict strong electroosmosis plays a role in driving DNA events and ge

40 ing electrokinetic flows (electrophoresis or electroosmosis) rather than pressure-driven flows becaus

41 by linear and nonlinear electrophoresis and electroosmosis reaching an equilibrium, without the pres

42 ing fluid delivery--which include valves and electroosmosis--require sophisticated microfabrication o

43 We demonstrate that electroosmosis theory compares well with the observed pn

44 hanism that leverages localized field-effect electroosmosis to create dynamic flow patterns, allowing

45 Using electroosmosis to drive flow through microfluidic channe

46 ocessor, a global flow field generated by ac electroosmosis transports the embedded particles to the

47 Electroosmosis was used to pull perfusate containing sec

48 were placed in wells on the microchips, and electroosmosis was used to transport aliquots of these r

49 ted which provides more efficient control of electroosmosis with an applied external voltage field.