ライフサイエンスコーパス: dielectrophoresis

1 in an electrical conductivity gradient using dielectrophoresis.

2 , this is the first observation of streaming dielectrophoresis.

3 ined electrophoresis and electroosmosis) and dielectrophoresis.

4 s can be manipulated and characterized using dielectrophoresis.

5 m the conventional electrofusion method with dielectrophoresis.

6 technologies, including optical tweezers or dielectrophoresis.

7 s: electrophoresis, electroosmotic flow, and dielectrophoresis.

8 from a mixture of healthy/oxidized cells by dielectrophoresis.

9 niform electric field, a phenomenon known as dielectrophoresis.

10 ing alternating current (AC) insulator-based dielectrophoresis.

11 h common theoretical models for nanoparticle dielectrophoresis.

12 , overcoming the limitations of conventional dielectrophoresis.

13 ield gradients for trapping biomolecules via dielectrophoresis.

14 of large cell clusters, taking advantage of dielectrophoresis.

15 s with DNA and other nanoassemblies based on dielectrophoresis.

16 extract cells using alternating current (AC) dielectrophoresis.

17 s are trapped on the electrode surface using dielectrophoresis.

18 at our recently developed AC insulator-based dielectrophoresis (AC iDEP) technique can direct micropa

19 orted with high purity using the multitarget dielectrophoresis activated cell sorter (MT-DACS) chip.

20 The dielectrophoresis activated cell synchronizer (DACSync)

21 mbranes, we demonstrate the roles of surface dielectrophoresis and counterion pressure in repelling P

22 iphysics model, which correctly accounts for dielectrophoresis and electrophoresis of the second kind

23 Electrokinetic phenomena such as dielectrophoresis and electrothermal fluid flow are used

24 Capitalizing on dielectrophoresis and interphase capacitance sensing, we

25 rk, such an AC signal is capable of inducing dielectrophoresis and other ACEK effects, so as to reali

26 ed water are actively trapped using wireless dielectrophoresis and positioned within the most sensiti

27 We report a microfluidic system integrating dielectrophoresis and surface enhanced Raman scattering

28 ure containing human blood cells by means of dielectrophoresis and then subjected to electronic lysis

29 on the cell velocity when submitted to pure dielectrophoresis, and it was conducted on several human

30 dering fields oscillating at low frequencies-dielectrophoresis-and high frequencies-optical tweezers.

31 The cells that experience stronger positive dielectrophoresis are streamed further in the perpendicu

32 multichannel device as a result of negative dielectrophoresis arising from the presence of the insul

33 y COMSOL model suggested electrophoresis and dielectrophoresis as likely mechanisms.

34 Cell separation using dielectrophoresis as well as electronic lysis on a silic

35 ective capture of circulating tumor cells by dielectrophoresis at arrays of wireless electrodes (bipo

36 Furthermore, the MIC determined using dielectrophoresis-based AST (d-AST) was consistent with

37 In this study we examine methods for dielectrophoresis-based cell aggregation of both suspens

38 ta myxospore polar capsules using a tailored dielectrophoresis-based microfluidic chip.

39 ntal results and modeling on the efficacy of dielectrophoresis-based single-particle traps.

40 t into the physical behavior of particles in dielectrophoresis-based traps.

41 e and differentially concentrate proteins is dielectrophoresis, but according to accepted theory, the

42 The study demonstrates that dielectrophoresis can be used to separate healthy RPE ce

43 biofuel cells, intracorporeal neural probe, dielectrophoresis cell trapping, and cell culture.

44 oof of concept with regard to a microfluidic dielectrophoresis chip thus shows the potential of immun

45 g selective chemistry, electrical breakdown, dielectrophoresis, chromatography and ultracentrifugatio

46 Here, we use direct current insulator-based dielectrophoresis (DC-iDEP) as an unbiased separation me

47 copy number, where molecules are trapped via dielectrophoresis (DEP) across the nanogap, which also s

48 c control approach that effectively combines dielectrophoresis (DEP) and alternating current electrot

49 A functionalized microwire sensor based on dielectrophoresis (DEP) and antigen-antibody reaction wa

50 Dielectrophoresis (DEP) and electrorotation (ROT) are tw

51 phenomena generated by the waveform include dielectrophoresis (DEP) and electrothermal fluid flow (E

52 sicular analysis by combining site-selective dielectrophoresis (DEP) and Raman spectroscopy.

53 Detailed understanding of the mechanism of dielectrophoresis (DEP) and the drastic improvement of i

54 Temperature increases during dielectrophoresis (DEP) can affect the response of biolo

55 proof of concept of utilizing a microfluidic dielectrophoresis (DEP) chip was conducted to rapidly de

56 This technique utilise the advantage of dielectrophoresis (DEP) force which is generated by non-

57 electronic tweezers (OET) or light-patterned dielectrophoresis (DEP) has been developed as a microman

58 Dielectrophoresis (DEP) has been widely explored to sepa

59 Dielectrophoresis (DEP) has shown great promise for part

60 ety of SnO(2) nanobelt motions induced by ac dielectrophoresis (DEP) in an innovative microfluidic se

61 ting methodology was developed that exploits dielectrophoresis (DEP) in microfluidic channels.

62 Dielectrophoresis (DEP) is a powerful tool to manipulate

63 Dielectrophoresis (DEP) is a versatile tool for the prec

64 the influence of direct current (DC) fields, dielectrophoresis (DEP) is not the main electrokinetic m

65 ate particles in microfluidic devices, where dielectrophoresis (DEP) is often the driving force.

66 Dielectrophoresis (DEP) is the motion of particles under

67 Here, dielectrophoresis (DEP) is used to assemble, align, and

68 Dielectrophoresis (DEP) is widely utilized for trapping

69 Electric field approaches such as dielectrophoresis (DEP) offers a more viable method for

70 Dielectrophoresis (DEP) offers many advantages over conv

71 Among label-free techniques, dielectrophoresis (DEP) offers the capability to separat

72 rofluidic enrichment system employs dialysis-dielectrophoresis (DEP) technology to rapidly isolate pa

73 In this paper, we used dielectrophoresis (DEP) to analyze the electrophysiologi

74 We used dielectrophoresis (DEP) to observe changes in the electr

75 The reported method uses dielectrophoresis (DEP) to selectively capture tumor cel

76 We demonstrate negative dielectrophoresis (DEP) trapping of particles from high-

77 Dielectrophoresis (DEP) utilizes a spatially varying non

78 In this study, dielectrophoresis (DEP) was used to vertically align car

79 Dielectrophoresis (DEP), a nonlinear electrokinetic tran

80 des via sequential DC electrophoresis and AC dielectrophoresis (DEP), and with single-CNT electron tu

81 ains or crystals from repulsive particles by dielectrophoresis (DEP), but these structures fall apart

82 in AC electrokinetics (ACEK), especially in dielectrophoresis (DEP), we are able to develop an ACEK

83 We present a dielectrophoresis (DEP)-based cell-separation method, us

84 In this study, taking advantage of a dielectrophoresis (DEP)-based Laboratory-on-a-chip platf

85 We present a dielectrophoresis (DEP)-based microfluidic chip that is

86 is could be used to enrich these cells using dielectrophoresis (DEP).

87 e describe a lab-on-a-chip platform based on dielectrophoresis (DEP).

88 This means that in such a medium, dielectrophoresis, despite its great versatilities for m

89 is fluid elasticity-enhanced insulator-based dielectrophoresis (E-iDEP) in very dilute PEO solutions

90 We demonstrate that electrodeless dielectrophoresis (EDEP) can be used for concentration a

91 el that considers the relative magnitudes of dielectrophoresis, electrophoresis, ac-electroosmosis, a

92 o describe AC-electrokinetic effects such as dielectrophoresis, electrorotation, and electroorientati

93 The dielectrophoresis experiments demonstrated the importanc

94 w longitudinal gradient feature to insulator dielectrophoresis, extending the technique to separation

95 bility of using an ultrahigh-frequency range dielectrophoresis fluidic biosensor as a detector.

96 odes in a nanochannel by frequency-selective dielectrophoresis for 10 s or by electrochemical adsorpt

97 We present the use of dielectrophoresis for label-free quantification of intra

98 active microfluidic platform that integrates dielectrophoresis for the control of silver nanoparticle

99 ded concentration for detection by employing dielectrophoresis for the first time in a G-FET, allowin

100 c field degradation and, hence, reduction in dielectrophoresis force due to the presence of the insul

101 In this paper with the aid of negative dielectrophoresis force in conjunction with shear force

102 ased on a Hsp60-coated biochip by 60% when a dielectrophoresis force was applied for 5 min at the beg

103 By increasing the strength of the negative dielectrophoresis force, we demonstrated a significantly

104 n highly concentrated samples using positive dielectrophoresis force.

105 surface, upon applying the improved negative dielectrophoresis force.

106 these different final states is achieved by dielectrophoresis forces selectively polarising the dipo

107 ed reactions with applied electroosmosis and dielectrophoresis forces.

108 new class of microwires can be assembled by dielectrophoresis from suspensions of metallic nanoparti

109 Dielectrophoresis has a negligible impact on 200-nm-diam

110 Applications of dielectrophoresis have included the selective spatial ma

111 heory of direct-current (DC) insulator-based dielectrophoresis (iDEP) considers that, in order to eli

112 The application of insulator-based dielectrophoresis (iDEP) for biological samples, however

113 Insulator-based dielectrophoresis (iDEP) has been demonstrated as a powe

114 Insulator-based dielectrophoresis (iDEP) integrated into a microfluidic

115 Insulator-based (electrodeless) dielectrophoresis (iDEP) is an innovative approach in wh

116 Insulator-based dielectrophoresis (iDEP) provides an efficient and matri

117 Alternatively, insulator-based dielectrophoresis (iDEP) uses small micrometer-scale ins

118 In insulator-based dielectrophoresis (iDEP), the required nonuniform electr

119 d the phenomenon is known as insulator-based-dielectrophoresis (iDEP).

120 ous solutions manipulated by insulator-based dielectrophoresis (iDEP).

121 non-viable human stromal cells using remote dielectrophoresis, in which an electric field is coupled

122 As expected, the application of dielectrophoresis increased the specific and the nonspec

123 ental agreement with these predictions using dielectrophoresis-induced spreading of stripes of 1,2 pr

124 Insulator-based dielectrophoresis is a relatively new analytical techniq

125 ts in bead detachment, whereas when negative dielectrophoresis is off, the beads remain attached.

126 Dielectrophoresis is one manipulation method for separat

127 Dielectrophoresis is widely used for cell characterizati

128 e show approximately 10-fold higher positive dielectrophoresis levels at 0.5 MHz for cells with a hig

129 arent from the significantly higher positive dielectrophoresis levels in the 0.5-15 MHz range.

130 phoresis, dielectrophoresis, travelling-wave dielectrophoresis), magnetic tweezers, acoustic traps an

131 ved from less invasive tumor cells, based on dielectrophoresis measurements.

132 source for combined trapping using negative dielectrophoresis (nDEP) and AC electroporation.

133 Microfluidic chips integrated with negative dielectrophoresis (nDEP) and electrochemical impedance s

134 e phase-controlled (VPC) method and negative dielectrophoresis (nDEP) theory in high conductivity phy

135 et to one side of the droplet using negative dielectrophoresis (nDEP), followed by asymmetric droplet

136 ells under continuous perfusion via negative dielectrophoresis (nDEP).

137 0 min that was required for the microfluidic dielectrophoresis of 1 mL of sample.

138 configurable circuitry through light-induced dielectrophoresis on lithium niobate.

139 Dielectrophoresis on the DMF device between two parallel

140 efficient cell separations were achieved by dielectrophoresis on this 5 x 5 array, which included se

141 Here we show that liquid dielectrophoresis or electrowetting can produce wetting

142 thin-film finger pairs to generate positive dielectrophoresis (p-DEP) to force the bacteria moving t

143 port a microfluidic device that utilizes the dielectrophoresis phenomenon to synchronize cells by exp

144 Graphene-edge dielectrophoresis pushes the physical limit of gradient-

145 Here we present an optical image-driven dielectrophoresis technique that permits high-resolution

146 ed in atrial tissue using several methods: a dielectrophoresis technique with isolated cells and impe

147 The interdigitated electrodes use positive dielectrophoresis to attract particles to the surface, w

148 We describe here modules using dielectrophoresis to control the position of cells flowi

149 ree membrane potential estimation which uses dielectrophoresis to determine the cytoplasm conductivit

150 and the BD-UNCD surface chemistry and apply dielectrophoresis to improve the specific and the nonspe

151 ographically defined microelectrodes, we use dielectrophoresis to manipulate individual bacterial spo

152 These traps use dielectrophoresis to stably confine cells and hold them

153 ers, electrokinetic forces (electrophoresis, dielectrophoresis, travelling-wave dielectrophoresis), m

154 and sodium hydroxide concentration, negative dielectrophoresis turned on results in bead detachment,

155 ofluidic channels by nanoscale electrodeless dielectrophoresis under physiological buffer conditions.

156 dividual micro-solder-beads in real-time via dielectrophoresis, we demonstrate rewritable electrical

157 osition of the anisotropic particles through dielectrophoresis, whereas a rotating magnetic field is

158 ving the cells that experience weak positive dielectrophoresis, which continue to traverse the microe

159 s study, Raman spectroscopy is combined with dielectrophoresis, which enables the direct translationa

160 between DC microchannel electrophoresis and dielectrophoresis, which typically utilizes frequencies

161 nded SWNTs showed both positive and negative dielectrophoresis, which we attribute to their zeta pote