ライフサイエンスコーパス: electrical impedance

1 cally stimulated with serial measurements of electrical impedance.

2 ly applied dexamethasone in reducing FBR and electrical impedance.

3 ion of DNA nanoballs with their detection by electrical impedance.

4 ndex and a colony size index calculated from electrical impedance.

5 ings on a new intra-operative measurement of electrical impedance (4-point impedance) which, when ele

6 yields the classification accuracy of 87.8% (electrical impedance), 70.1% (deformability), 42.7% (rel

7 Transepithelial electrical impedance analysis provides a sensitive metho

8 relaxation time were determined by means of electrical impedance and dielectric relaxation spectrosc

9 ques - high-resolution manometry, esophageal electrical impedance and intra-luminal ultrasound imagin

10 y enable optical fluorescence-based mapping, electrical impedance and pH sensing, contact/temperature

11 multaneously characterize the deformability, electrical impedance and relaxation index of single cell

12 c constrictions, during which deformability, electrical impedance and relaxation index of single cell

13 results reveal self-similarity of normalized electrical impedance as a function of the normalized fre

14 Here we present the use of electrical impedance as an indicator of cell health and

15 Our results demonstrate the utility of electrical impedance as an indicator of cell phenotype b

16 Electrical impedance assessment revealed unforeseen detr

17 eloped a microfluidic platform for measuring electrical impedance at different frequencies using the

18 y smaller than the diameter of tested cells, electrical impedance at multiple frequencies is measured

19 We here show that an electrical impedance-based device is able to get insight

20 The PFA catheter was localized by electrical impedance-based navigation.

21 Compared to existing electrical impedance-based needle methods that we have d

22 d assessment of RBC deformability, employing electrical impedance-based readout to measure RBC occlus

23 Cell proliferation was measured using an electrical impedance-based real-time cell analyzer.

24 Electrical impedance-based sensing of cell activity has

25 o activated T lymphocytes in flow through an electrical impedance-based setup.

26 Over the last decades, cell-based electrical impedance biosensors have been explored for d

27 ical recordings and wireless probing of skin electrical impedance, body temperature, and humidity, AB

28 ity has limited implementation of cell-based electrical impedance (CEI) in drug discovery.

29 cell populations have been quantified using electrical impedance cell counting.

30 The measured electrical impedance changes were those predicted on the

31 al phenotyping is implemented by single-cell electrical impedance characterization with two pairs of

32 (relaxation index) and 93.3% (combination of electrical impedance, deformability and relaxation index

33 ss in vivo the epidermal barrier function by electrical impedance (EI) spectroscopy.

34 question may involve how changes in somatic electrical impedance evoked by efferent synaptic action

35 Changes in electrical impedance have previously been used to measur

36 eading two different fluorescent sensors and electrical impedance in 24-well-plates.

37 ease, and therapy.SIGNIFICANCE STATEMENT The electrical impedance in limbic brain structures (amygdal

38 Dex-CI reduced electrical impedance in the murine model and human subje

39 cell shape changes correlate with changes in electrical impedance measured in cellular monolayers.

40 ulti-planar microelectrode design capable of electrical impedance measurement at different spatial pl

41 trapping and provides sensitive, label-free electrical impedance measurements of individual cells, e

42 he use of dielectrophoretic positioning with electrical impedance measurements to detect and discrimi

43 Time lapse electrical impedance measurements were conducted as red

44 ned locations with the capability of running electrical impedance measurements within the same device

45 The enzymatic reaction is monitored by electrical impedance measurements, evaluating variations

46 ial barrier function was determined based on electrical impedance measurements.

47 The experimental approach consisted of an electrical impedance method designed to measure cell vol

48 ng regulatory volume decrease (RVD), with an electrical impedance method for determination of cell vo

49 red its effect on astrocytic volume using an electrical impedance method.

50 Electrical impedance methods, including electrical imped

51 of graphene is imaged with plasmonics-based electrical impedance microscopy, from which the local de

52 In this study, we evaluated whether electrical impedance myography (EIM) could serve this pu

53 The non-invasive technique of electrical impedance myography (EIM) has shown potential

54 Electrical impedance myography (EIM) is a non-invasive,

55 The positioning of electrodes in electrical impedance myography (EIM) is critical for acc

56 Thus, we applied noninvasive, surface electrical impedance myography (EIM) methodology to SOD1

57 ve proposed a novel method to detect ACS via electrical impedance myography (EIM), where a weak, high

58 Electrical impedance methods, including electrical impedance myography, are increasingly being u

59 meter-scale gold electrodes that measure the electrical impedance of an ultrathin (~ 150-200 nm), two

60 ral venous catheter was developed to measure electrical impedance of blood in-vivo in the right atriu

61 at these major parameters are related to the electrical impedance of blood.

62 Measurements of transepithelial electrical impedance of continuously short-circuited A6

63 addition, the electrical coupling due to the electrical impedance of solution is diminished by extend

64 n contributes significantly to the change in electrical impedance of solutions, in particular to thos

65 ition of its activity in RPE reduces TER and electrical impedance of the RPE monolayers.

66 P-EIM measures electrical impedance optically with high spatial resolut

67 glucocorticoid, on the intracochlear FBR and electrical impedance post-implantation in a murine model

68 lved, mutant) cell phenotypes based on their electrical impedance properties.

69 dance Cytometry (MIC) to characterise the AC electrical (impedance) properties of single parasites an

70 Esophageal electrical impedance recordings reveal abnormal transit

71 Subsequent electric circuit modeling of the electrical impedance results the capacitive properties o

72 dification, next to electrode-structures for electrical impedance sensing.

73 ed a pencil probe (diameter 5 mm) to measure electrical impedance spectra from eight points on the ce

74 Characteristics of the electrical impedance spectra of tissues can be explained

75 ns the way to deriving tissue structure from electrical impedance spectral measurements.

76 Immunosensors based on electrical impedance spectroscopy (EIS) are increasingly

77 Electrical impedance spectroscopy (EIS) based label-free

78 mpedance tomography (EIT) and multifrequency electrical impedance spectroscopy (EIS) devices.

79 Therefore, electrical impedance spectroscopy (EIS) emerges as a via

80 aper describes the improvement in the use of electrical impedance spectroscopy (EIS) for animal cell

81 SC) and applied marker-independent real-time electrical impedance spectroscopy (EIS) for cellular rea

82 athering surface plasmon resonance (SPR) and electrical impedance spectroscopy (EIS) for monitoring t

83 n this study, we investigated the utility of electrical impedance spectroscopy (EIS) for noninvasive

84 Electrical impedance spectroscopy (EIS) is a powerful to

85 Fs) and monitoring cellular responses via AC electrical impedance spectroscopy (EIS) is reported.

86 duced an electrochemical lipidomics based on electrical impedance spectroscopy (EIS) of the secretome

87 A four-electrode electrical impedance spectroscopy (EIS) setup can be rea

88 We investigated the use of electrical impedance spectroscopy (EIS) to detect skin b

89 ost-operative fracture monitoring, utilizing electrical impedance spectroscopy (EIS) to track the hea

90 Electrical impedance spectroscopy (EIS)'s utility in thi

91 c cell-substrate impedance sensing (ECIS) or electrical impedance spectroscopy (EIS), is an approach

92 s were imaged with three EM imaging methods: electrical impedance spectroscopy (EIS), microwave imagi

93 une response monitoring through non-invasive electrical impedance spectroscopy (EIS).

94 e in vivo status of epithelial barrier using electrical impedance spectroscopy (EIS).

95 vity (NR) and conductance measurements using electrical impedance spectroscopy (EIS).

96 the electrode upon hybridization by means of electrical impedance spectroscopy (EIS).

97 In this work, we use electrical impedance spectroscopy as a label-free method

98 Electrical impedance spectroscopy can be a useful tool t

99 xtracted from equivalent circuit modeling of electrical impedance spectroscopy data varied only accor

100 howed that forsterite dissolution begins and electrical impedance spectroscopy demonstrated that diff

101 his work substantiates the prominent role of electrical impedance spectroscopy for the development of

102 On-chip cell lysate electrical impedance spectroscopy has been utilized to q

103 recent years, label-free techniques such as electrical impedance spectroscopy have emerged as a non-

104 Electrical impedance spectroscopy is a rapid and reliabl

105 enchymal resistance in humans using repeated electrical impedance spectroscopy measurements in two se

106 Electrical impedance spectroscopy measurements were perf

107 Electrical impedance spectroscopy revealed VLP saturatio

108 Electrical impedance spectroscopy shows that Staphylococ

109 The obtained electrical impedance spectroscopy signal of the Cu(3)VSe

110 cells were simultaneously characterized via electrical impedance spectroscopy technique.

111 Electrical impedance spectroscopy via microelectrode arr

112 Electrical impedance spectroscopy was able to assess epi

113 udy, we introduced a novel method, combining electrical impedance spectroscopy with dynamic mechanica

114 aging techniques-near-infrared spectroscopy, electrical impedance spectroscopy, and microwave imaging

115 n pigmented lesion evaluation tools, such as electrical impedance spectroscopy.

116 tegration of sensing through transepithelial electrical impedance (TEEI) measurements and transparent

117 Here, we consider electrical impedance to directly access bacterial metabo

118 edance cardiography uses changes in thoracic electrical impedance to estimate hemodynamic variables,

119 edles bring closer the application of needle electrical impedance to patients with neuromuscular dise

120 Diffusion tensor magnetic resonance electrical impedance tomography (DT-MREIT) and electrode

121 Fast neural electrical impedance tomography (EIT) allows fascicular

122 utilized electrical impedance via commercial electrical impedance tomography (EIT) and multifrequency

123 iratory inductance plethysmography (RIP) and electrical impedance tomography (EIT) are two monitoring

124 We aimed to describe the use of Electrical Impedance Tomography (EIT) as a clinical tool

125 We demonstrate electrical impedance tomography (EIT) as a portable meth

126 aeration in neonates and young infants using electrical impedance tomography (EIT) as part of the lar

127 Electrical impedance tomography (EIT) can be used to pro

128 Electrical impedance tomography (EIT) has recently been

129 studies by means of a spatio-temporal based electrical impedance tomography (EIT) imaging on a condu

130 Electrical impedance tomography (EIT) is a bedside imagi

131 Electrical impedance tomography (EIT) is a radiation-fre

132 ilation/perfusion (V/Q) mismatch measured by electrical impedance tomography (EIT) is associated with

133 In past few years' electrical impedance tomography (EIT) is considered to b

134 To evaluate the ability of electrical impedance tomography (EIT) to monitor a PEEP

135 PES measurements and electrical impedance tomography (EIT) were performed bef

136 ventilated patients with ARDS monitored with electrical impedance tomography (EIT) who received NMBAs

137 , offering high mapping capabilities through electrical impedance tomography (EIT).

138 cts of pronation by the means of CT scan and electrical impedance tomography (EIT).

139 er and lower 95% limits of agreement between electrical impedance tomography and computed tomography

140 We used electrical impedance tomography and dynamic computed tom

141 ectional and whole lung volume changes using electrical impedance tomography and respiratory inductiv

142 nd simultaneously measured by, respectively, electrical impedance tomography and respiratory inductiv

143 istration was insufficient for analysis (two electrical impedance tomography and six respiratory indu

144 areas in the supine position, monitoring by electrical impedance tomography and the oxygenation resp

145 Our results support that electrical impedance tomography appears predictive to de

146 ss-sectional lung volume changes measured by electrical impedance tomography are representative for t

147 Both computed tomography and electrical impedance tomography can help titrate positiv

148 water content, and lung ultrasound (LUS) and electrical impedance tomography changes are related to t

149 to counteract dorsal lung collapse, whereas electrical impedance tomography could guide positive end

150 At the same time, electrical impedance tomography data (regional distribut

151 Electrical impedance tomography data for individual brea

152 Methods: Analysis of electrical impedance tomography data from a previous ran

153 afterward, lung mechanics, gas exchange, and electrical impedance tomography data were collected.

154 apse and overdistention were estimated using electrical impedance tomography during a decremental PEE

155 ation-delay can be noninvasively measured by electrical impedance tomography during a slow inflation

156 t dependent lung region was increased in the electrical impedance tomography group (1.78 mL/cm H(2)O

157 animals to define the anatomic correlates of electrical impedance tomography imaging (n = 5).

158 Electrical Impedance Tomography is a clinically useful t

159 Electrical impedance tomography is a potential tool for

160 Electrical impedance tomography is an imaging technique

161 was ventilated using guidance with real-time electrical impedance tomography lung imaging.

162 posterior parts of the lung was observed on electrical impedance tomography measurements when increa

163 Electrical impedance tomography measures lung volume in

164 by an esophageal catheter and a 32-electrode electrical impedance tomography monitor underwent two po

165 ated for lung quadrants and for every single electrical impedance tomography pixel, respectively.

166 An electrical impedance tomography recording was made in su

167 e was calculated in relation to the previous electrical impedance tomography recording.

168 h nasal continuous positive airway pressure, electrical impedance tomography recordings were performe

169 ntilation were extracted for each of the 228 electrical impedance tomography recordings.

170 Electrical impedance tomography showed that increasing p

171 Our objectives were use electrical impedance tomography to describe lung impedan

172 The aim was to evaluate the ability of electrical impedance tomography to help the physician to

173 e acute respiratory distress syndrome, using electrical impedance tomography to measure the effects o

174 f positive end-expiratory pressure guided by electrical impedance tomography versus transpulmonary pr

175 any positive end-expiratory pressure level, electrical impedance tomography was obtained during a sl

176 Methods: Electrical impedance tomography was used to image intrat

177 d-expiratory lung volume changes measured by electrical impedance tomography were significantly corre

178 tient with injured lungs, we observed (using electrical impedance tomography) a pendelluft phenomenon

179 anics and regional aeration and ventilation (electrical impedance tomography) were measured throughou

180 l parameters, distribution of ventilation by electrical impedance tomography, and breathing patterns

181 tomography, lung magnetic resonance imaging, electrical impedance tomography, bronchoscopy, and other

182 of local pressure-volume curves derived from electrical impedance tomography, for computing maps that

183 lung areas collapse (> 13.5%), monitored by electrical impedance tomography, has an excellent positi

184 ion in dependent lung regions assessed using electrical impedance tomography, noninvasive continuous

185 During all study phases, we measured, by electrical impedance tomography, the proportion of tidal

186 e end-expiratory pressure levels selected by electrical impedance tomography- and transpulmonary pres

187 Regional electrical impedance tomography-derived compliance of th

188 Regional electrical impedance tomography-derived compliance was u

189 Significant correlations between electrical impedance tomography-derived maps and positiv

190 Electrical impedance tomography-derived maps might becom

191 Electrical impedance tomography-derived maps of pressure

192 izing global elastance and driving pressure, electrical impedance tomography-derived maps showed nonn

193 Electrical impedance tomography-derived maps were comput

194 oorly aerated regions (r = 0.43; p < 0.001); electrical impedance tomography-derived overdistension w

195 elations with CT measurements were observed: electrical impedance tomography-derived tidal recruitmen

196 This is the first prospective use of electrical impedance tomography-derived variables to imp

197 xpiratory pressure levels were higher in the electrical impedance tomography-guided group (14.3 cm H(

198 ratory system compliance was improved in the electrical impedance tomography-guided group (6.9 mL/cm

199 fibrin (AF) was significantly reduced in the electrical impedance tomography-guided group (HMEIT 42%

200 ventilated using ARDSnet guidelines, and the electrical impedance tomography-guided group (n = 6) was

201 igher and oxygenation index was lower in the electrical impedance tomography-guided group (Pao(2)/FIO

202 Electrical impedance tomography-guided ventilation resul

203 tion of ventilation was measured by means of electrical impedance tomography.

204 th acute respiratory distress syndrome using electrical impedance tomography.

205 lation evidence from computed tomography and electrical impedance tomography.

206 neity, and potential for lung recruitment by electrical impedance tomography.

207 at lower positive end-expiratory pressure by electrical impedance tomography.

208 assessed with pulmonary artery catheter and electrical impedance tomography.

209 sitive end-expiratory pressure chosen by the electrical impedance tomography.

210 nd-expiratory lung volume were assessed with electrical impedance tomography.

211 lung volumes and ventilation homogeneity by electrical impedance tomography.

212 ation heterogeneity, as measured by thoracic electrical impedance tomography.

213 raphy (Pleth), and the test systems utilized electrical impedance via commercial electrical impedance

214 eter, which measures platelet aggregation by electrical impedance, was adapted to test platelet funct

215 gnitude of the Schottky barrier and altering electrical impedance, whereas atomic scale metal junctio

216 uencies, indicative of a higher paracellular electrical impedance with respect to the static cultures

217 The resistance component of the electrical impedance, Zre, measured between these two el