ライフサイエンスコーパス: dielectrophoretic

1 ids into the suspension cells because of the dielectrophoretic accumulation of the plasmids in betwee

2 sistive sensor device was assembled using ac dielectrophoretic alignment followed by maskless anchori

3 In this approach, the dielectrophoretic amplitude response of rare target cell

4 a non-equilibrium on-off switch that employs dielectrophoretic and hydrodynamic shear forces to overc

5 epime, and doripenem, were determined by the dielectrophoretic antimicrobial susceptibility testing (

6 mes through a potential landscape exhibiting dielectrophoretic barriers.

7 Here, we introduce Dielectrophoretic Bead-Droplet Reactor as a physical met

8 city have also been developed to predict the dielectrophoretic behavior in an array of posts.

9 Here, we explore the dielectrophoretic behavior of six-helix bundle and trian

10 erties of submicron particles dominate their dielectrophoretic behavior.

11 s based on the optical discrimination of the dielectrophoretic behaviors of multiple microparticle pr

12 ic assay solution was optimized to allow for dielectrophoretic cell capture, thereby obviating the ne

13 r electrofusion of cells in suspension or in dielectrophoretic cell chains.

14 This allows high-throughput dielectrophoretic cell separation in high conductivity,

15 The study presents a dielectrophoretic cell separation method via three-dimen

16 based microfluidic Coulter counter with a dc-dielectrophoretic cell sorter, we demonstrate simultaneo

17 The data reveal that dielectrophoretic cell sorters should have the ability t

18 ottom) and indium tin oxide (at the top) for dielectrophoretic cell trapping and electrical lysis.

19 iosensors, biofuel cells, neural probes, and dielectrophoretic cell trapping.

20 Based on the length and dielectrophoretic characteristics, sorting efficiencies

21 structures has led to new techniques for the dielectrophoretic characterization and sorting of cells,

22 electrokinetic behavior to enable design of dielectrophoretic concentrators and sorters.

23 ononuclear cells (PBMC) were determined from dielectrophoretic crossover frequency measurements on a

24 rk presents a direct current-insulator-based dielectrophoretic (DC-iDEP) approach to simultaneously c

25 Characterization of the DNA's dielectrophoretic (DEP) behavior is the foundation of DN

26 ptibility test (AST) based on the changes in dielectrophoretic (DEP) behaviors related to the beta-la

27 o enhance the intensity of fluorescence in a dielectrophoretic (DEP) chip with a microelectrode array

28 Here, we outline a new dielectrophoretic (DEP) chip-based assay.

29 The phenomenon has been attributed to the dielectrophoretic (DEP) force arising from the nonhomoge

30 d solution exchange technology that utilizes dielectrophoretic (DEP) force to move all cells to one s

31 Our developed microfluidic platform utilizes dielectrophoretic (DEP) force to perform on-demand spati

32 This paper describes the dielectrophoretic (DEP) forces generated by a bipolar el

33 Dielectrophoretic (DEP) forces have been used extensivel

34 standing surface acoustic waves (SAWs), and dielectrophoretic (DEP) forces, induced by gradient elec

35 Dielectrophoretic (DEP) mechanisms integrated in microfl

36 We study the utility of a dielectrophoretic (DEP) micro-chip device for isolation

37 o optimizing micromixer design for enhancing dielectrophoretic (DEP) microconcentrator performance.

38 A novel alternating current (ac)-dielectrophoretic (DEP) microfluidic chip for continuous

39 Continuous-flow dielectrophoretic (DEP) particle separation based on siz

40 e, we present a novel approach to change the dielectrophoretic (DEP) response of nonviable yeast cell

41 that, in order to elicit particle trapping, dielectrophoretic (DEP) velocity counterbalances electro

42 r group has reported a novel insulator-based dielectrophoretic device for rapid isolation of small ex

43 Dielectrophoretic dynamic light-scattering (DDLS) spectr

44 simple means for studying electrothermal and dielectrophoretic effects, which are important in micro

45 etween live and dead cells was attributed to dielectrophoretic effects.

46 A dielectrophoretic "electric bottle" confines colloids, e

47 The nanopatterning technique combines dielectrophoretic enrichment and deep surface-energy mod

48 The dielectrophoretic enrichment of bacteria allows for obta

49 Dielectrophoretic enrichment was performed by collecting

50 Dielectrophoretic field-flow fractionation (DEP-FFF) has

51 Dielectrophoretic field-flow-fractionation (DEP-FFF) was

52 In this work, dielectrophoretic field-flow-fractionation (DEP-FFF), a

53 threshold DC electric field for single-line dielectrophoretic focusing of particles in a constricted

54 rochemical impedance measurement followed by dielectrophoretic force and antibody-antigen interaction

55 The applied dielectrophoretic force and the corresponding increase i

56 suspension and a field direction-independent dielectrophoretic force for particle/cell focusing in a

57 ncy of aqueous droplets and highly localized dielectrophoretic force generated by interdigitated elec

58 The highly localized and enhanced dielectrophoretic force generated by the IDEs on the cha

59 ing (DL) architectures to precisely quantify dielectrophoretic force invoked on microparticles in a t

60 Dielectrophoretic force is employed to enrich the bacter

61 Dielectrophoretic force microscopy (DEPFM) and spectrosc

62 Dielectrophoretic force microscopy is shown to allow for

63 erences in magnitude and/or direction of the dielectrophoretic force on different populations of part

64 The periodic optical field modulates the dielectrophoretic force on the membrane at the overtones

65 The magnitude and direction of the dielectrophoretic force on the particle depends on its d

66 Dielectrophoretic force spectra were obtained in situ in

67 e tips are structurally modified to create a dielectrophoretic force that attracts mRNA molecules wit

68 The dielectrophoretic force that results from the electric f

69 DEP-based microconcentrators use the dielectrophoretic force to collect particles on electrod

70 parallel sidewall 3D electrodes to produce a dielectrophoretic force which traps cells inside the cap

71 Label-free dielectrophoretic force-based surface charge detection h

72 report, we demonstrate and characterize this dielectrophoretic force-based surface charge detection m

73 iDEP and could be easily misinterpreted as a dielectrophoretic force.

74 local pinning points for DNA segments due to dielectrophoretic force.

75 the electric field and, therefore, different dielectrophoretic forces acting on exosomes suspended in

76 malous frequency effects, not explainable by dielectrophoretic forces alone, were also encountered an

77 onfine single PC-3 cells in microwells using dielectrophoretic forces and perform the impedance measu

78 d in which cell mixtures are fractionated by dielectrophoretic forces and simultaneously collected in

79 nce between controllable acoustophoretic and dielectrophoretic forces applied on cells through surfac

80 rticularly, the balanced acoustophoretic and dielectrophoretic forces can trap cells at equilibrium p

81 This not only validates our ability to model dielectrophoretic forces in these traps but also gives i

82 The balancing of surface, hydrodynamic and dielectrophoretic forces makes the self-assembly process

83 ory or orientation using electrophoretic and dielectrophoretic forces to a specific location with sub

84 ned the contributions of electrophoretic and dielectrophoretic forces to the trapping and concentrati

85 expression of the stress-related gene c-fos, dielectrophoretic forces were shown to have little effec

86 to confined oil droplet concentration under dielectrophoretic forces, and (3) increased collision ef

87 Dielectrophoretic forces, caused by the interaction of n

88 o experience different strengths of positive dielectrophoretic forces, in response to the 3D nonunifo

89 processor then utilizes electrophoretic and dielectrophoretic forces, which are effective in short r

90 er the periodic action of electrokinetic and dielectrophoretic forces.

91 s within a photopolymerizable hydrogel using dielectrophoretic forces.

92 In an array of posts, dielectrophoretic forcing within repeated rows adds cohe

93 New dielectrophoretic fractionation methods have great poten

94 As a result, dielectrophoretic frequency analysis can enable the inde

95 arget cells captured on microspheres through dielectrophoretic funneling.

96 Dielectrophoretic/gravitational field-flow fractionation

97 The characterization of a dielectrophoretic/gravitational field-flow-fractionation

98 article and cell focusing in insulator-based dielectrophoretic (iDEP) microdevices, where a large fie

99 ting the feasibility for frequency-selective dielectrophoretic isolation of cells to aid the discover

100 This paper presents a novel device for the dielectrophoretic manipulation of particles and cells.

101 Semiconducting SWNTs were imaged during dielectrophoretic manipulation with fluorescence microsc

102 he microelectrode surface using programmable dielectrophoretic manipulations.

103 ual giant unilamellar vesicles (GUVs) inside dielectrophoretic microfield cages.

104 rstanding of the underlying polarization and dielectrophoretic migration is essential.

105 gami species, which is responsible for their dielectrophoretic migration.

106 ls were observed to have significantly lower dielectrophoretic mobility than live cells, whereas the

107 entiation factor (ratio of electrokinetic to dielectrophoretic mobility) has been used to characteriz

108 re specialized approaches based on affinity, dielectrophoretic mobility, and inertial properties of c

109 link differential sorting to differences in dielectrophoretic mobility.

110 The field induces macromolecules to undergo dielectrophoretic motion, which is detected by the modul

111 icle probes for Hg(2+) and Ag(+), label-free dielectrophoretic multiplex detection of these species i

112 Here, we extend dielectrophoretic nanowire assembly to achieve a 98.5% y

113 particles, including cells, using a positive dielectrophoretic (p-DEP) trapping array.

114 We introduce a new dielectrophoretic particle microconcentrator that combin

115 elasticity effects on the electrokinetic and dielectrophoretic particle motions.

116 We have developed a dielectrophoretic platform using a disposable 3D electro

117 We combine the use of dielectrophoretic positioning with electrical impedance

118 igration times correlate to the depth of the dielectrophoretic potential barrier and the escape chara

119 actors contributing to the migration through dielectrophoretic potential landscapes, which can be exp

120 f electrical biosensors with BD-UNCD so that dielectrophoretic preconcentration can be performed dire

121 iamond (BD-UNCD) electrode in a microfluidic dielectrophoretic preconcentrator.

122 with sodium deoxycholate (NaDOC) show unique dielectrophoretic properties at low frequencies (<1 kHz)

123 ced for long SWNTs (>=1000 nm) with negative dielectrophoretic properties compared to short (<=300 nm

124 ared to short (<=300 nm) SWNTs with positive dielectrophoretic properties.

125 reactive oxygen species (ROS) production and dielectrophoretic repulsion.

126 Here, the dielectrophoretic response of B cells infected with Kapo

127 lectrodes; this enumeration was based on the dielectrophoretic selection of cells.

128 erformed on a theoretical microfluidic-based dielectrophoretic separation chip using these parameters

129 ubcellular biophysical information and their dielectrophoretic separation conditions, without the nee

130 iology of unknown cell types or to benchmark dielectrophoretic separation metrics of novel device str

131 The system features the use of microfluidic dielectrophoretic separation of bacteria that adhere to

132 Dielectrophoretic separation of cells followed by electr

133 the electrodes to create the conditions for dielectrophoretic separation of cells.

134 is briefly compared with immunomagnetic and dielectrophoretic separations.

135 000 V across the length of the main channel, dielectrophoretic size-based separation of exosomes was

136 loped a microfluidic device that facilitates dielectrophoretic sorting of heterogeneous particle mixt

137 tive droplets are subsequently recovered via dielectrophoretic sorting, and the TaqMan amplicons are

138 agreement was observed between the measured dielectrophoretic spectra and predictions using a single

139 cells were characterized by recording their dielectrophoretic spectra, and electric cell parameters

140 ic field gradients enable demonstration of a dielectrophoretic spectrometer that separates particles

141 esent the development of a continuous-flow, "dielectrophoretic spectrometer" based on insulative DEP

142 el multiple cell types with unique synthetic dielectrophoretic tags that modulate the complex permitt

143 e orientation of both origami species in the dielectrophoretic trap and discuss the influence of diff

144 We present a novel microfabricated dielectrophoretic trap designed to pattern large arrays

145 small as 10-20 nm, which can be used for the dielectrophoretic trapping of DNA and proteins.

146 Dielectrophoretic trapping of molecules is typically car

147 d high-field regions for electrophoretic and dielectrophoretic trapping of particles.

148 ul, method based on coupling single-molecule dielectrophoretic trapping to nanopore sensing.

149 In this paper we demonstrate dielectrophoretic trapping using insulating constriction

150 markable stability, and can be combined with dielectrophoretic trapping, enabling active analyte tran

151 is comparable to that of optical tweezers or dielectrophoretic traps, without requiring an external f