ライフサイエンスコーパス: NIRS

1 NIRS analysis of milk samples allowed to estimate FA con

2 NIRS could also distinguish roots with high or low cyano

3 NIRS could be used by chocolate manufacturers as a routi

4 NIRS findings in pre-existing stents were indistinguisha

5 NIRS has also been used to assess systemic perfusion in

6 NIRS has the potential to be a valuable clinical tool in

7 NIRS is a green chemistry, low cost, fast response techn

8 NIRS measurements of the oxidation state of mitochondria

9 NIRS offers noninvasive monitoring of cerebral oxygenati

10 NIRS or chromameter improve selection protocols, allowin

11 NIRS predictions were highly satisfactory for dry matter

12 NIRS probes and an NMR coil were placed on the liver and

13 This difference allows a NIRS signal classifier to serve successfully as a reinfo

14 d the development of a reliable and accurate NIRS calibration to determine NH(3) content.

15 ith ACS) undergoing invasive angiography and NIRS, 68 target lesions were identified.

16 EEG, EOG, ECG and NIRS signals have been measured during a simulated drivi

17 Statistical tests were performed on EEG and NIRS signals to find the most informative parameters.

18 uce a new approach, a combination of EEG and NIRS, to detect driver drowsiness.

19 eculated to indicate neoatherosclerosis, and NIRS findings in a control group of freshly implanted st

20 The correlation between Conway results and NIRS spectra enabled the development of a reliable and a

21 This study validated a FA, VOC and NIRS model for use in the authentication of Arnad PDO la

22 The 20 years of clinical experience at NIRS can help guide strategic decisions on the design an

23 and to all updated clinical data produced at NIRS.

24 ted peer review of the carbon ion therapy at NIRS.

25 han 8000 patients have had this treatment at NIRS, and the centre thus has by far the greatest experi

26 lp NIRS investigators design and plan better NIRS experiments, head probes and instruments.

27 imation of percent time of coherence between NIRS SctO2 and aEEG for 78 hours after birth.

28 o sleep there was a coordinated fall in both NIRS parameters, we call the Switch Point, that lasted a

29 This study demonstrates that both NIRS and Raman technology can be successfully applied as

30 nd mineral oil were characterised using both NIRS and Raman spectroscopy.

31 We used a broadband NIRS system to measure changes in oxCCO, in addition to

32 strate the tremendous potential of broadband NIRS as a non-invasive, in vivo means to study mechanism

33 or above the median of 43.0, as assessed by NIRS in a nonculprit coronary artery, had a 4-fold risk

34 roportion of cheeses correctly classified by NIRS and visible spectra was respectively 0.96 and 0.91

35 ion parameters were measured continuously by NIRS; 31P-NMR spectra obtained at 1 min intervals from e

36 At the site of LRP detected by NIRS in a cohort of pre-existing stents, intravascular u

37 ntimal tissue at the site of LRP detected by NIRS, intravascular ultrasound may provide some insight

38 detection of LRP in a pre-existing stent by NIRS alone is not reliable evidence of neoatherosclerosi

39 In addition, cerebral NIRS can function as a first-alert monitor to warn of pr

40 dies suggest that implementation of cerebral NIRS monitoring during LVAD and ECMO implantation may re

41 utput, cerebral blood flow and thus cerebral NIRS may be better preserved than in somatic tissue site

42 ts and minimal risks in relation to cerebral NIRS, it is recommended that it be utilized during the o

43 s the practical approaches to using cerebral NIRS for LVAD and ECMO implantation.

44 ible beneficial effect of utilizing cerebral NIRS during LVAD and ECMO implantation.

45 ndings in pre-existing stents and to compare NIRS findings in pre-existing stents, in which an increa

46 ng stents implanted 5.5+/-4.0 years earlier, NIRS detected LRP in 33%.

47 ive techniques, supporting the concept of FD-NIRS/DCS as a promising technology to monitor cerebral p

48 quency-domain near-infrared spectroscopy (FD-NIRS) and diffuse correlation spectroscopy (DCS).

49 rder to increase their accuracy before final NIRS implementation at mills.

50 of systemic oxygen delivery and blood flow, NIRS can certainly assist in the detection of low-flow s

51 r results support the notion that functional NIRS has a potential utility as an objective measure of

52 Here we used functional NIRS to evaluate brain activation to an innocuous and a

53 ely sources of NIRS signals, as well as help NIRS investigators design and plan better NIRS experimen

54 y and number of subsamples to be measured in NIRS measurement.

55 Overall, the results indicated NIRS has a good potential to determine different GSLs in

56 Interestingly, NIRS analysis allowed direct prediction of the Atherogen

57 long-term prognostic value of intracoronary NIRS as assessed in a nonculprit vessel in patients with

58 Although, it is concluded that the on-line NIRS prediction results were acceptable for the three pa

59 nt of the near infrared spectroscopy method (NIRS) is to indicate which factor significantly influenc

60 to detect systemic hypoperfusion, multisite NIRS such as a combination of cerebral and somatic site

61 New NIRS systems are being introduced to the market and tech

62 ctors with significant influence on obtained NIRS results were indicated, as well as pointed the pote

63 Despite shortcomings in the ability of NIRS technology to accurately reflect validated and dire

64 The applicability of NIRS was evaluated for Arabica and Robusta varieties fro

65 e of interest in the clinical application of NIRS following studies that have quantified the benefits

66 studies that have quantified the benefits of NIRS-guided management of cerebral oxygenation during ca

67 complex head model, and (iii) the effect of NIRS instrument sensitivity on detecting brain activatio

68 sent work was to evaluate the feasibility of NIRS reflectance (oven-dried milk using the DESIR method

69 e layers, and they can enhance the impact of NIRS for cerebral hemodynamics and oxygenation assessmen

70 tive power thus aiding the interpretation of NIRS signals in individuals.

71 Optimization of NIRS is prerequisite for accurate prediction of grain qu

72 amples was used to evaluate the potential of NIRS and chromameter devices to predict root quality tra

73 view will briefly describe the principles of NIRS and examine current evidence for its clinical appli

74 uate: (i) the spatial sensitivity profile of NIRS to brain tissue as a function of source-detector se

75 anted in order to clearly define the role of NIRS in children at risk for low perfusion.

76 Thus, while the depth sensitivity of NIRS is not strictly limited, NIN signals in adult human

77 dance for interpreting the likely sources of NIRS signals, as well as help NIRS investigators design

78 ailable on the long-term prognostic value of NIRS in patients with coronary artery disease (CAD).

79 in the present work confirm the viability of NIRS as a fast, reliable and effective analytical method

80 evelop algorithm-based therapies centered on NIRS monitoring.

81 2)=0.92) and pH value (R(2)=0.94) presenting NIRS as fast and reliable alternative in routine quality

82 nd nutritional components of rice bran (RB), NIRS can be an effective tool for high throughput screen

83 National Institute of Radiological Sciences (NIRS) Chiba, Japan, has been treating cancer with high-e

84 In this sense, NIRS has been used in combination with chemometric metho

85 inal site seems preferable to the flank site NIRS (kidney region) application.

86 s a combination of cerebral and somatic site NIRS has been suggested.

87 evelopment of a near infrared spectroscopic (NIRS) method for routine analytical prediction of bioche

88 aken to describe near-infrared spectroscopy (NIRS) and intravascular ultrasound findings in pre-exist

89 et Perry] using near-infrared spectroscopy (NIRS) and partial least squares (PLS).

90 echniques such a near-infrared spectroscopy (NIRS) are used in industry to monitor and establish prod

91 e application of near infrared spectroscopy (NIRS) as a noninvasive monitor of cerebral oxygenation.

92 is work presents near-infrared spectroscopy (NIRS) as an in-line process analyzer for monitoring prot

93 Near-infrared spectroscopy (NIRS) being a portable, non-invasive and inexpensive met

94 e development of near-infrared spectroscopy (NIRS) calibration to determine individual and total gluc

95 Near infrared spectroscopy (NIRS) can be used to assess changes in hemoglobin concen

96 Near-infrared spectroscopy (NIRS) can measure tissue oxyhemoglobin (HbO2), deoxyhemo

97 dies showed that Near Infrared Spectroscopy (NIRS) could distinguish between Roundup Ready(R) (RR) an

98 the potential of near-infrared spectroscopy (NIRS) for the prediction of antioxidant compounds in sum

99 While near-infrared spectroscopy (NIRS) haemodynamic measures have proven to be vastly use

100 Cerebral near-infrared spectroscopy (NIRS) has been recognized clinically as a valid, continu

101 ta on the use of near infrared spectroscopy (NIRS) in children at risk for low perfusion.

102 Near-infrared spectroscopy (NIRS) is capable of identifying lipid core-containing pl

103 coffee based on near infrared spectroscopy (NIRS) is proposed.

104 of non-invasive near-infrared spectroscopy (NIRS) measurements to brain tissue-i.e., near-infrared n

105 requency-domain, near-infrared spectroscopy (NIRS) method to measure the optical coefficients of two-

106 We exploited a Near-Infrared Spectroscopy (NIRS) method to monitor the onset of fat phase transitio

107 t study used the Near Infrared Spectroscopy (NIRS) technique to describe the intracerebral hemodynami

108 ely coupled with near-infrared spectroscopy (NIRS) to measure online hemodynamic responses within the

109 e used broadband near-infrared spectroscopy (NIRS) to measure the LLLT-induced changes in CCO and hem

110 We used near-infrared spectroscopy (NIRS) to test the hypothesis that reducing oxygen availa

111 y, intracoronary near-infrared spectroscopy (NIRS) was used to determine the frequency of LCP at targ

112 acity made using near-infrared spectroscopy (NIRS) with the current gold standard, namely in situ mea

113 Near infrared spectroscopy (NIRS), a rapid and efficient tool, was used to analyze N

114 as measured with near-infrared spectroscopy (NIRS), can be applied as reinforcers to an adaptable art

115 he usefulness of near infrared spectroscopy (NIRS), combined with volatile compound (VOC) and fatty a

116 tongue (ET) and near-infrared spectroscopy (NIRS), were investigated in order to develop a rapid met

117 xygenation using near infrared spectroscopy (NIRS).

118 using 52-channel near-infrared spectroscopy (NIRS).

119 with near-infrared reflectance spectroscopy (NIRS) as a feasible method to determine the total anthoc

120 sing Near Infrared Reflectance Spectroscopy (NIRS).

121 In this prospective, observational study, NIRS imaging was performed in a nonculprit coronary arte

122 and Optical measurements suggests that such NIRS methods can be used to improve dosimetry and to min

123 or predictions, but with lower accuracy than NIRS.

124 We conclude that NIRS is able to classify cheese samples from different r

125 Relative errors around 5% show that NIRS can be a valuable analytical tool to be used by cof

126 The results show that NIRS, together with chemometric methods, provides a rapi

127 this study provides evidence to suggest that NIRS could be used to identify biomarkers of social cogn

128 ocarp tissues, respectively, supporting that NIRS is able to predict in a rapid way these components

129 The NIRS calibration was established based on modified parti

130 The NIRS model obtained sensitivity and specificity values o

131 tion of source-detector separation, (ii) the NIRS sensitivity to brain tissue as a function of depth

132 e number of subsamples to be measured in the NIRS measurement (1), environmental temperature (2), sam

133 its performance to exceed the limits of the NIRS classifier decoding accuracy.

134 The assessment of robustness of the NIRS method included variation of certain operational an

135 LCP was defined as a 2-mm segment on the NIRS block chemogram having a strong positive reading in

136 These findings suggest that the NIRS and PLS algorithms can be used to determine TCA and

137 d results highlighted the necessity that the NIRS instruments should work through a voltage regulator

138 Applying chemometrics to the NIRS and Raman spectral data, very good calibration and

139 olyphenol indices (IP), classified using the NIRS procedure, and three grain qualities.

140 d by invasive angiography who also underwent NIRS before intervention.

141 Using NIRS, R(2) values greater than 0.99 were obtained with c

142 tro measurements of optical scattering using NIRS and the MR signal parameters (T2*) as well as spect

143 assessed during a working memory task using NIRS.

144 etermined in 21 healthy adults in vivo using NIRS to measure the recovery kinetics of muscle oxygen c

145 Vis/NIRS signals of 150 fruit were obtained immediately afte

146 The use of chemometrics to analyse Vis/NIRS signal collected from intact 'Nules Clementine' man

147 monstrated the potential applications of Vis/NIRS to predict postharvest behaviour of mandarin fruit.

148 The results indicate that in vivo NIRS corresponds well with the current gold standard, in

149 ameters and muscle oxygenation measured with NIRS were continuously monitored.

150 Here, the spectral data obtained with NIRS were analysed using a supervised pattern recognitio