ライフサイエンスコーパス: micropipet

1 , followed by partial enclosure into a glass micropipet.

2 ulated with chemoattractant delivered from a micropipet.

3 by repositioning of a chemoattractant-filled micropipet.

4 n source of error is usually the accuracy of micropipets.

5 s convenient and less costly than the use of micropipets.

6 n-limited delivery of chemoattractant from a micropipet allowed for maintaining an almost constant ch

7 The micropipet also serves as the tip of transient SECM to d

8 d electric field on the distance between the micropipet and the surface are measured, and the results

9 sing an etched Pt wire inside a pulled glass micropipet and then coating with cellulose acetate.

10 emitters are laser-pulled borosilicate glass micropipets and have tapers of around 4 microm i.d.

11 myocytes were introduced into the chamber by micropipetting and subsequently capped with a layer of m

12 In cylindrical tethers pulled from micropipet-aspirated giant unilamellar vesicles, reparti

13 simulate the dynamics of neutrophils during micropipet aspiration using various plausible assumption

14 microscopy, Fourier transform analysis, and micropipet-aspiration experiments to assess mechanical p

15 The ability of the micropipet assay to establish a well-defined chemoattrac

16 equipped with an array of 16 silicon nitride micropipet-based ion-selective microelectrodes with a di

17 A large tip resistance of the micropipets causes prolonged charging current so that th

18 With this laser-micropipet combination, it will be possible to measure t

19 A scanning micropipet contact method (SMCM) is described which prom

20 The micropipet contains a reference-counter electrode, and t

21 The micropipet delivery-substrate collection (MD-SC) mode of

22 id/liquid interfaces supported at the tip of micropipet electrodes for direct determination of the di

23 Voltammetric ion-selective micropipet electrodes for use in scanning electrochemica

24 Cyclic voltammetry at micropipet electrodes is applied to the kinetic study of

25 Cyclic voltammetry and chronoamperometry at micropipet electrodes were applied to study the phase tr

26 Using both organic- and water-filled micropipet electrodes, the reaction mechanism was studie

27 nses based on the interfacial recognition at micropipet electrodes.

28 roelectrode is fabricated in a tapered glass micropipet filled with a low melting point alloy.

29 The method is based on the use of a micropipet filled with fluo-3.

30 ts in which ions are ejected from one of two micropipets ("generator") into the external solution and

31 A triple-barrel micropipet injector was used to exogenously apply three

32 monstrated by extruding egg cytoplasm from a micropipet into SW.

33 Often, iontophoretic ejections from micropipets into brain tissue are confined to millisecon

34 The tip of a conventional heat-pulled micropipet is milled using the focused ion beam (FIB) te

35 icroscopy for Ca(2+) wave activity following micropipet mechanical stimulation of a single cell.

36 ld an automated liquid handler that controls micropipetting of liquids in 3D space at speeds and posi

37 DEX droplets were formed either by manual micropipetting or within a continuous PEG phase by compu

38 ing the ion-selective SECM tips based on the micropipet- or nanopipet-supported interfaces between tw

39 is created by putting an electrode inside a micropipet positioned over the electrode and applying a

40 ration uses microelectrodes, capillaries, or micropipets positioned near single, adherent cells to in

41 In SMCM, a moveable micropipet probe (diameter 300 nm to 1 microm) containin

42 substrate and at a ring electrode tip on the micropipet probe.

43 he fabrication and characterization of novel micropipet probes for use in scanning electrochemical mi

44 Micropipet solid-phase extraction (SPE) tips have been u

45 External calibration curves were prepared by micropipetting standards with internal standard (IS) on

46 We apply ion-transfer voltammetry at a micropipet-supported interface between aqueous and organ

47 res into amperometric SECM tips based on the micropipet-supported interface between two immiscible el

48 We report the use of a micropipet-supported ITIES (interface between two immisc

49 ific nucleic acid (NA) detection utilizing a micropipet tapered to a 2 mum diameter pore and 3 mum di

50 ll-sized microwell trapping and cell-picking micropipet techniques.

51 ked by chemical secretagogues delivered from micropipets that were calibrated with respect to respons

52 gration of the metallic nanostructure with a micropipet, the nanoblade generates a micrometer-sized m

53 mes of sample without the need of commercial micropipets; this device did not damage the nitrocellulo

54 novalent ions is determined using FIB-milled micropipet tips to establish a theoretical formula for t

55 cked into capillaries that can be affixed to micropipet tips.

56 Novel curves were identified by micropipetting U-dHRM reactions and Sanger sequencing am

57 owth cone by local application of MST with a micropipet was equally effective.

58 The pseudopod extension induced using micropipets was oscillatory even in the presence of a co

59 ct voltammetric responses of ET reactions at micropipets were investigated.

60 Glass micropipets were used to record the extracellular activi

61 ucted by insulating gold-coated borosilicate micropipets with electrophoretic paint and exposing a ri