ライフサイエンスコーパス: fast response

1 tion with submicromolar detection limits and fast response.

2 ic capacitance (676 F cm(-3) ) combined with fast response.

3 ness, high sensitivity, good selectivity and fast response.

4 assay with high sensitivity, selectivity and fast response.

5 receptors were associated with particularly fast responses.

6 transcriptional activators that mediate the fasting response.

7 involved in gluconeogenesis and other liver fasting responses.

8 , automation, low sample volume (6 muL), and fast response (20 s).

9 (with 48-86 microg L(-1) detection limits), fast response (50 s for a three alkyl methylphosphonic a

10 ) concentration by measuring nitrogen with a fast-response analyzer.

11 Fast response analyzers, based on heterogeneous chemilum

12 The nanotube sensors exhibit a fast response and a substantially higher sensitivity tha

13 qRT-PCR revealed a very fast response and an up to 100-fold induction after tryp

14 The fast response and excellent stability of the flexible li

15 approach provides robust sensing films with fast response and extended lifetime.

16 a limit of detection (LOD) down to 1microm, fast response and good long-term stability.

17 The fabricated sensor gives fast response and is demonstrated to be of practical uti

18 ection because of their extreme sensitivity, fast response and low cost.

19 signal (up to 34% change per 100 mV) with a fast response and recovery time (0.5 ms).

20 a wide dynamic range (16 microM-136 mM) with fast response and recovery times.

21 after Pd catalyst decoration with reasonably fast response and recovery times.

22 t sensitivity with detection limit of <0.2%, fast response and recovery, and a workable temperature r

23 They are characterized by fast response and slow adaptation to varying environment

24 odel suggests that negative feedback induces fast responses and an initial overshoot of nitric oxide

25 fication in mRNA endows gene expression with fast responses and controllable protein production throu

26 ect size, both were larger for slow than for fast responses and the effects were positively correlate

27 PGC-1alpha in several aspects of the hepatic fasting response and show that HNF4alpha is a critical c

28 ration of resistors and capacitors to enable fast response, and a home-built system acquired data at

29 High sensitivity and selectivity, fast response, and excellent durability in biological me

30 o near-infrared light with high sensitivity, fast response, and good stability is reported.

31 excellent sensitivity, acceptable stability, fast response, and high electrocatalytic activity toward

32 ility, self-referenced ratiometric response, fast response, and high selectivity.

33 the trap depth of the CdTe QDs, a high gain, fast response, and low noise P3HT:CdTe nanocomposite pho

34 ble microscale roughness, ease of operation, fast response, and possibilities for programmable contro

35 (14.4 kPa(-1) ), low detection limit (2 Pa), fast response ( approximately 24 ms), low power consumpt

36 When fast responses are to be achieved, rapid decay of mRNAs

37 It is anticipated that other fast-response cell-based assays (e.g., other ion flux as

38 This decline was stronger in fast-response compared with slow-response trials, consis

39 1) were suspended in a sealed chamber with a fast response electrode to measure every second before,

40 Fast response errors indicated that stimulation increase

41 iciency of visual information processing and fast response execution.

42 The other type was a similar fast response followed by a more slowly rising and falli

43 Fasting response genes fell into multiple kinetic classe

44 s, we implicated four key TFs regulating the fasting response: glucocorticoid receptor (GR), cAMP res

45 Working with FTIR technique that possesses fast response, high sensitivity, and capability of detec

46 We found that fast responses in FEF strongly correlated with the perce

47 r Ca(2+) and that Ca(2+) gating is tuned for fast responses in neuronal BKCa-Cav complexes.

48 These receptors facilitate fast-response, inhibitory glycinergic neurotransmission

49 tronics, such as biomedical imaging, where a fast response is critical.

50 ization energy of water corresponding to the fast response is found to be higher than that obtained u

51 bsence of fetally derived DLK1, the maternal fasting response is impaired.

52 an reliably detect less than 0.05 nM CT with fast response (less than 5 min).

53 osensor for OPs shows a wide linear range, a fast response (less than 5s) and limits of detection (S/

54 ke immunity to electromagnetic interference, fast response, low cost and capability of online monitor

55 th high transmission, low voltage (<2 Vrms), fast response (<1 sec), diffraction efficiency > 90%, sm

56 We made fast response measurements of size-resolved particle num

57 a glucose sensor material with a linear and fast response, minimal hysteresis, and good stability un

58 hottky contact to achieve supersensitive and fast response nanowire-based nanosensors.

59 metabolism to fatty acid oxidation, and the fasted response occurs much more rapidly in pregnant wom

60 ed on the signal-to-noise ratio (S/N=3) with fast response of 15min.

61 Moreover, the fast response of the LBCO thin film, as the p-type gas s

62 xplains-on a microscopic level-the extremely fast response of this material to ultrafast optical exci

63 The fast responses of four AP2/ERF genes, ERF6, RRTF1, ERF10

64 1) were suspended in a sealed chamber with a fast response P(o)(2) electrode to measure V(o)(2) every

65 Second, an ultrasensitive, fast-response, polarographic cell and detection system w

66 equipped Google Street View vehicles with a fast-response pollution measurement platform and repeate

67 ys of the silicon transistor, new printable, fast-response polymer electrolytes are expanding the pot

68 We have developed a carbon-based, fast-response potentiometric pH microsensor for use as a

69 The use of fast-response, pressure-driving pumps allows the microfl

70 and numerically linking our understanding of fast-response processes of soil gas exchange with longer

71 Finally, GN/BCN sensors demonstrate fast response/recovery times and a wide range of alcohol

72 cient information to keep the network in the fast-response regime without sliding into the instabilit

73 Thus, with a fast response, significant stability and repeatability,

74 characteristics with structural simplicity, fast response speed, silent operation, and low power con

75 Field-type EAPs can exhibit fast response speeds, low hysteresis and strain levels f

76 Our characterization of a fasting response system and our finding that nhr-49 regu

77 NIRS is a green chemistry, low cost, fast response technique without the need of sample proce

78 ATP evoked 'fast' responses that underwent rapid activation and dese

79 ed (ATM)-dependent pathway that controls the fast response, there is an ATM-independent pathway that

80 Extremely robust (photogain > 1,000) and fast (response time < 1 ms) photoresponse allow us to st

81 The electrode showed a fast response time ( 10 s) and a detection limit of 1.3

82 The heterojunction device shows a fast response time ( approximately 45 ms) and a signific

83 lity, lower detection limit (3.87 mg/dL) and fast response time (>10s).

84 h sensitivity (0.23 A M(-)(1) cm(-)(2)), and fast response time (<1 s).

85 he sensor possesses numerous advantages like fast response time (<15s), simple, low cost, highly sele

86 With their fast response time (<200 ms) and high reversibility, the

87 ited linear response to glucose up to 31 mM, fast response time (<3 s) and a low detection limit of 1

88 PAA-rGO/VS-PANI/LuPc2-MFH biosensor showed a fast response time (1s) to the addition of glucose with

89 It showed a reasonably fast response time (4-5 min).

90 2)mM), good reproducibility (RSD=2.1%) and a fast response time (4s).

91 ining a low detection limit (0.0625mg/L) and fast response time (61s).

92 and with high sensitivity (down to ~20 ppb), fast response time (down to ~1 s), and low power consump

93 een found, including simple instrumentation, fast response time (e.g., 3.6 s in the case of dopamine

94 MC3-based chloride sensors show a fast response time (in the order of few seconds), as wel

95 de: miniaturization, operational simplicity, fast response time (less than 5min), useful sensitivity.

96 The biosensor operated at 0.450 V, had a fast response time (t90% < or = 3 s), and was free of ty

97 nar sensors for creatinine and creatine have fast response time (t95 = 1 min), linear response up to

98 cope (SECM) probes because of their inherent fast response time and ease of miniaturization.

99 reprogrammable in any desired fashion, with fast response time and high efficiency.

100 ver sensor system that has high specificity, fast response time and is easily applicable by user for

101 ear range, high sensitivity and selectivity, fast response time and low oxygen-, temperature- and pH-

102 ent sensitivity (detection limit as 0.1 nM), fast response time and wider linear range (from 0.02 to

103 or offers a large phase change while keeping fast response time due to the decoupling between phase c

104 The high sensitivity in combination with fast response time is unprecedented when compared to rec

105 with a maximum sensitivity of 8.4 kPa(-1), a fast response time of <10 ms, high stability over >15,00

106 5.12+/-0.05 muA/muM cm(2)) and stable with a fast response time of 4 s; it could detect cholesterol e

107 zations show prominent photoresponse, with a fast response time of 500 mus, faster than all the direc

108 (0.83-16.65 Mm) of urea concentrations with fast response time of 5s.

109 rbic acid, a storage stability of 3 weeks, a fast response time of 6 s, and good, linear sensitivity

110 high photoresponsivity of >100 A W(-1) and a fast response time of approximately 100 mus.

111 approximately 5 orders of magnitude) with a fast response time of few seconds and provides great pot

112 fied sample and an indicator solution with a fast response time of ~22 s.

113 ATP in a continuous-flow system exhibiting a fast response time, 4s, and a full recovery to the base

114 The fast response time, and the ease of fabrication of these

115 This work presents a novel, fast response time, plastic optic fiber (POF) biosensor

116 Fast response time, signal stability, high sensitivity,

117 carrier mobility, broadband absorption, and fast response time, the semi-metallic graphene is attrac

118 e behavior with high regulatory capacity and fast response time.

119 onth with accuracy of about 0.02 pH unit and fast response time.

120 e to their high sensitivity, portability and fast response time.

121 r-sensitivity, ultra-selectivity, as well as fast response time.

122 and stretchable graphene oxide coatings with fast response time.

123 metric sensors exhibit linear response, have fast response times (< or = 0.25 s), and are completely

124 /- 0.09 microM, signal-to-noise ratio of 3), fast response times (T90 approximately 1 s), and excelle

125 h high levels of sensitivity (~0.005 Pa) and fast response times (~0.1 ms).

126 The fast response times coupled with the low sample volumes

127 he combination of both high responsivity and fast response times makes these photodetectors suitable

128 anical flexibility, high contrast ratios and fast response times, along with colour tunability throug

129 e of the protein-based biosensors, including fast response times, excellent selectivity, and complete

130 The devices showed very fast response times, indicating that the improved perfor

131 tors demonstrated high photoresponsivity and fast response times.

132 f roughly 5.5-10.5 with good sensitivity and fast response times.

133 ion from flies to humans, evolved to allow a fast response to changes in nutrient availability while

134 imentally, showing high sensitivity and very fast response to millimetre-wave radiation.

135 meric transmembrane proteins involved in the fast response to numerous neurotransmitters.

136 emory T cells to promote their longevity and fast response to rechallenge.

137 cenarios, because it assures an accurate and fast response to stimuli that resemble the original stim

138 or to activate insulin signaling, allowing a fast response to the hormone after each meal.

139 ased the proportion of cells displaying only fast responses to ATP (10 microM) suggesting that cross-

140 i.e. the proportion of cells displaying only fast responses to ATP was increased significantly.

141 velopment of sensors that can give large and fast responses to changes in transmembrane potential.

142 Additionally, AIV neurons exhibit fast responses to disruptive auditory feedback presented

143 These results explain fast responses to envelope stress; demonstrate that the

144 a second electroencephalography experiment: Fast responses to temporally unpredictable interruptions

145 The relatively fast responses to uric acid suggest that preformed secon

146 ation between conflict and error likelihood: fast response trials are associated with low conflict bu

147 search task: distractors triggered the PD on fast-response trials, but on slow-response trials they t

148 ) humidity sensors with high sensitivity and fast response using graphene oxide sensing layer.

149 al line-scan imaging in conjunction with the fast response voltage-sensitive dyes ANNINE-6 and ANNINE

150 The location of the fast response was sensitive to stimulation position in t

151 Consistent with a fast guess account, fast responses were strongly biased toward the higher-pa

152 EPPG also showed a fast response, with little indication of passivation wit