ライフサイエンスコーパス: electrical impedance

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

2 Transepithelial electrical impedance analysis provides a sensitive metho

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

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

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

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

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

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

9 The measured electrical impedance changes were those predicted on the

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

11 Changes in electrical impedance have previously been used to measur

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

32 Esophageal electrical impedance recordings reveal abnormal transit

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

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

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

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

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

38 Electrical impedance spectroscopy (EIS) based label-free

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

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

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

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

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

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

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

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

47 Electrical impedance spectroscopy measurements were perf

48 Electrical impedance spectroscopy revealed VLP saturatio

49 Electrical impedance spectroscopy shows that Staphylococ

50 cells were simultaneously characterized via electrical impedance spectroscopy technique.

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

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

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

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

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

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

57 We used electrical impedance tomography and dynamic computed tom

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

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

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

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

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

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

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

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

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

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

68 Electrical impedance tomography measures lung volume in

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

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

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

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

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

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

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

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

77 Regional electrical impedance tomography-derived compliance of th

78 Regional electrical impedance tomography-derived compliance was u

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

80 Electrical impedance tomography-derived maps might becom

81 Electrical impedance tomography-derived maps of pressure

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

83 Electrical impedance tomography-derived maps were comput

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

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

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

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

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

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

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

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

92 Electrical impedance tomography-guided ventilation resul

93 lung volumes and ventilation homogeneity by electrical impedance tomography.

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

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

96 th acute respiratory distress syndrome using electrical impedance tomography.

97 lation evidence from computed tomography and electrical impedance tomography.

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

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

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