ライフサイエンスコーパス: raster

1 (SCIs) in Romania, and landscape resistance rasters.

2 delberg Engineering) with a dense horizontal raster (15 x 10 degrees , 97 sections) centered on the o

3 d 45 degrees fundus images and two undilated raster 3D-OCT scans (512 x 128) covering the macula and

4 nderwent digital FA and 512 x 128 horizontal raster 3D-OCT scans on the same day in a retina subspeci

5 images of the pore openings were obtained by rastering a glass-sealed conically shaped Pt tip (approx

6 eration of laser beam parameters (spot size, rastering across the sample surface) and actual sample c

7 In this method, a large diameter laser beam rasters across the surface of a partly aligned CNT texti

8 ack, and South Asian origin underwent SD OCT raster and enhanced depth imaging scan.

9 SERAPHIM ("Studying Environmental Rasters and PHylogenetically Informed Movements") is a s

10 Circular, raster, and radial scans of left eye optic nerves were a

11 ed methodologies (spot ablation, single line raster, and two-dimensional imaging) were also used to d

12 yers were deposited at various predetermined raster angles.

13 uniquely suited to scan times typical of the raster approach that is ubiquitous in TPLSMlaboratories.

14 al from various surface locations on a 4 x 4 raster array (50 mum pitch distance, ablation crater dia

15 The raster assembly can also improve throughput as foils con

16 The raster assembly provided a 5.7 fold increase in the surf

17 In contrast to raster assembly that assigns optical tweezers to each pa

18 n is statistically comparable to the 25-line raster at detecting fluid in DME, BRVO/CRVO, and central

19 ons and highlights the need to acquire dense raster B-scans with the grading neighboring B-scans when

20 sing a massive road dataset-137 million 1-ha raster cells drawn from three different sources arrayed

21 serous chorioretinopathy (91 scans), 25-line raster confirmed fluid in 4 scans (P=.13) and 1 scan (P=

22 VO (123 scans) and BRVO (126 scans), 25-line raster confirmed fluid on 2 (P=.25) and 4 scans (P=.13),

23 Baseline SD-OCT scans included raster cubes centered on the optic nerve and macula, and

24 racterization factors are provided as global raster data sets at high spatial resolution (~1 km) and

25 lood scenarios consisting of high-resolution raster datasets featuring flood-water depth generated by

26 Data were acquired with MALDI-MS by rastering each hair individually.

27 All eyes underwent macular 5-line raster evaluation using spectral-domain OCT before and a

28 of RCM mosaics (RCM images concatenated in a raster fashion to extend the field view) at 4-5 specific

29 The design for a desired shape is made by raster-filling the shape with a 7-kilobase single-strand

30 In computer graphics, raster graphics encodes images on a single-pixel level,

31 drawings and scenes that can be rendered as raster-graphics images, allowing for easy generation of

32 Manual choroidal segmentation on a 25-raster horizontal scan protocol was performed.

33 Here the bioimaging approaches Raster Image Correlation Spectroscopy (RICS) and image-M

34 phages using two fluorescence-based methods: raster image correlation spectroscopy (RICS) and single

35 e cell within the same experiment by using a raster image correlation spectroscopy (RICS) based analy

36 Raster image correlation spectroscopy (RICS) is a fluore

37 Raster image correlation spectroscopy (RICS) is a noninv

38 fluctuation imaging methods (PIE-FI) such as raster image correlation spectroscopy (RICS) or number a

39 1 interactions by employing a combination of raster image correlation spectroscopy (RICS), fluorescen

40 imaging with correlation spectroscopy, as in raster image correlation spectroscopy (RICS), makes it p

41 This novel method, called raster image correlation spectroscopy (RICS), rapidly me

42 mploying overlapping time series analysis to raster image correlation spectroscopy (RICS), we observe

43 Using raster image correlation spectroscopy and number and bri

44 Here we apply an extended version of raster image correlation spectroscopy to determine direc

45 concentration and DNA binding, we performed raster image correlation spectroscopy, a method that can

46 int FCS, photon-counting histogram analysis, raster image correlation spectroscopy, and two-color flu

47 fluorescence fluctuation approaches, notably raster image correlation spectroscopy, as tools to recor

48 ified by the novel fluorescent techniques of raster image scanning spectroscopy and number and bright

49 Using this cross correlation raster image spectroscopy method, specific locations in

50 enerate publication-quality vector graphics, rastered images and in-line streamed graphics for webpag

51 e (RPE/BM) layer imaged on the SD-OCT 5-line raster in normal subjects and in patients with papillede

52 trations from 100 nM down to <30 pM with PIE-raster lifetime image correlation spectroscopy (RLICS).

53 custom scan acquisition protocol of up to 13 raster lines of 9-mm scan length with automatic real-tim

54 s the acquisition of a Raman spectrum over a rastered macro spot.

55 A raster map of total tree basal area (TBA) for the conter

56 s) and full-thickness MH (82 scans), 25-line raster missed focal traction (<1500 mum) and MH in 5 sca

57 ing of proteins from thin tissue sections in raster mode and discuss advantages (a 10-fold reduction

58 tability and analytical results, whereas the raster mode was preferred over spot mode for greater acc

59 e composite image by collecting a predefined raster of matrix-assisted laser desorption/ionization ti

60 obtain spatially resolved spectra, by sample rastering or by 2D imaging, are introduced.

61 es, one can consistently identify the proper raster orientation within 2 degrees -4 degrees in each o

62 lled manner, and along a specific predefined raster path, covering a limited area.

63 d along an ad-hoc arbitrarily free-form, non-rastered path.

64 Furthermore, it is superior to the 25-line raster pattern at detecting early MH formation, while de

65 imaged 5 times, and each scan consisted of a raster pattern comprising 40 000 uniformly spaced A-scan

66 tion OCT instrument using a 200 x 200 A-scan raster pattern covering a 6 mm x 6 mm area centered on t

67 rm data, images are extracted to observe the raster pattern in a layer-by-layer manner, with the resu

68 investigates the viability of discerning the raster pattern of additively manufactured components usi

69 n spectra via a Raman microspectrometer in a raster pattern on a 0.5-microm grid and assembling pseud

70 of the labeled tissue by the laser beam in a raster pattern, the mass tags are liberated and recorded

71 ualization method that displays neurons as a raster plot after sorting them along a one-dimensional a

72 Raster plots revealed a striking difference in the respo

73 connectivity matrices, voltage traces, spike raster plots, local field potentials, and information th

74 how increasing both the number of pulses per raster point and the total acoustic power yielded corres

75 wo exposure parameters: number of pulses per raster point and total acoustic power.

76 Cirrus HD-OCT using the 512 x 128 horizontal raster protocol.

77 on each eye, centered at the fovea, using a raster protocol.

78 image analysis algorithms that are based on raster representation.

79 he structural complexity of rubble at a high raster resolution of 1 cm and that of tabulate coral at

80 gh-throughput LIAD probe and an assembly for raster sampling of a LIAD foil were designed, constructe

81 Each raster scan covered a retinal area of 6 x 6 mm encompass

82 rence tomography (OCT) data were obtained as raster scan data (512 x 180 axial scans in a 6 x 6-mm re

83 hibit less scan distortion than conventional raster scan images.

84 isely controlling the sample position during raster scan in a focused, confined X-ray beam, we are sc

85 Conventionally, raster scan methods are used to interrogate such librari

86 PAM system can achieve a 3D PAM image via a raster scan of 256 x 256 pixels within a time duration o

87 al scanner that performs a transillumination raster scan of the female breast in approximately 3 min.

88 epeated 3 times: 3-dimensional (3D) 6 x 6-mm raster scan of the optic disc and macula, radial, and li

89 A raster scan of the optic nerve and analysis of the retin

90 domain OCT technology enables higher density raster scan protocols and improved performance of en fac

91 Raster scan protocols enabled three-dimensional volumetr

92 ibrometry, and flow cytometry at a record 2D raster scan rate of more than 100 kHz with 27,000 resolv

93 e microscopy (to +/-4 nm), a two-dimensional raster scan to calibrate position detector response, and

94 position of the excitation focus during the raster scan.

95 T and fluorescence imaging by using only one raster scan.

96 ing fluctuation correlation spectroscopy and raster-scan image correlation spectroscopy analysis of l

97 This is different from the original raster-scan image correlation spectroscopy approach, whe

98 the idea of using Number and Brightness and Raster-scan Image Correlation Spectroscopy as methods to

99 Cross-correlation raster-scan image correlation spectroscopy revealed that

100 uorescence correlation spectroscopy (FCS) or raster-scan image correlation spectroscopy) or particle

101 tified by Number and Brightness analysis and Raster-scan Image Correlation Spectroscopy.

102 standard laser confocal imaging techniques (raster-scan mode) not only can we reach the temporal sca

103 Because in a raster scanned image successive pixels are measured at d

104 his article we describe a protocol to obtain raster scanned images with an Olympus FluoView FV1000 co

105 dimensional imaging systems frequently use a raster scanned laser to measure the range of each pixel

106 The tissue sample was raster scanned with TRS to yield a spatial map of the wa

107 The electrode/light source was raster-scanned a finite distance above the sample surfac

108 Two-photon photolysis with raster-scanned femtosecond IR pulses gives the first thr

109 Our method surpasses limits on the speed of raster-scanned imaging imposed by fluorescence lifetime.

110 es a miniaturized resonant/nonresonant fiber raster scanner and a multielement gradient-index lens as

111 The miniaturized raster scanner is fabricated by mounting a commercial do

112 r both radial scan patterns when compared to raster scanning (P < .001 for both comparisons).

113 urrent pore and specific molecule imaging by raster scanning an alphaHL-based probe over a glass memb

114 ich require either long acquisition times or raster scanning and have a requirement for sufficient si

115 It relies on raster scanning for localized data acquisition, which ca

116 a computational framework that integrates a raster scanning forward model with a deep learning prior

117 methods (scanning number and brightness and raster scanning imaging correlation spectroscopy) the ef

118 The prevailing approaches include raster scanning of a rectangular grid on a vertical wall

119 l, temporal control is easily attainable via raster scanning or random addressing, allowing for the s

120 s of healthy patients who had undergone a 31-raster scanning protocol on a commercial SD-OCT device w

121 t-of-plane growth rates can be controlled by raster scanning the coated tip across the substrate.

122 s of inhomogeneous polycrystalline solids by raster scanning them under a micro/nano focused polychro

123 pical of those used for crystal centering by raster scanning through an X-ray beam were sufficient to

124 PS-OCT raster scanning was performed before (baseline [BSL]) an

125 age of 49 (22-79) years who underwent 1-line raster scanning with SD OCT were identified.

126 cal tissues can be formed by two-dimensional raster scanning, and functional parameters can be furthe

127 In this believed new method of modified raster scanning, as it acquires the image, the laser sca

128 nce with minimal (<3%) flux variation during raster scanning, whereas the other gels had a substantia

129 ion to a small spot and probes the sample by raster scanning.

130 chemical image of the surface as compared to raster scanning.

131 ) captures images without array detectors or raster scanning.

132 Individual microcrystals are located by raster-scanning a several-micrometer X-ray beam across t

133 Here, we performed sequential serial raster-scanning crystallography using a microfocused syn

134 hoton efficiency have been with conventional raster-scanning data collection using single-pixel photo

135 ical properties of haemoglobin, we show that raster-scanning optoacoustic mesoscopy (RSOM) provides h

136 optical and ultrasound imaging, specifically raster-scanning optoacoustic mesoscopy (RSOM), offers a

137 ther, high-efficiency and programmable laser raster-scanning patterns can be locally controlled by ad

138 Raster-scanning the radiation force over the object and

139 or an Er:YAG laser (350 mJ/pulse at 6 Hz) by raster-scanning the samples under a fixed handpiece or l

140 generation (iAMD) underwent 6- x 6-mm SS-OCT raster scans at baseline and during their follow-up peri

141 ow that fluorescence-fluctuation analysis of raster scans at variable timescales can provide this inf

142 For neovascular AMD (133 scans), 7 25-line raster scans confirmed subretinal/intraretinal fluid not

143 Optical coherence tomography (OCT) RNFL raster scans from 98 healthy and 50 glaucomatous eyes we

144 e of the choroid in healthy eyes from 1-line raster scans obtained using SD OCT.

145 3D raster scans of the beam profiles were acquired using a

146 of the technique have been compared with the raster scans showing that the algorithm provides reliabl

147 Sequential 6-line radial and 25-line raster scans were evaluated for intraretinal/subretinal

148 OCT raster scans were further analyzed regarding the central

149 Three-dimensional 6x6 mm macular cube raster scans were obtained with SS-OCT operating at 1050

150 , 6 x 6-mm macular structural OCT horizontal raster scans, and 6 x 6-mm macular OCT angiography volum

151 T examination comprising a macular map, line raster scans, and en face images of the inner retinal su

152 avelength using repeated en face Doppler OCT raster scans, comprising 600 x 80 axial scans and coveri

153 fly-back distortion) present in conventional raster scans, it is not distortion-free.

154 ea was measured on structural OCT horizontal raster scans.

155 SD OCT raster scans/fluorescein angiograms were obtained from 2

156 Specifically, given an environmental raster, SERAPHIM computes environmental "weights" for ea

157 A raster series of 100 B-scans separated by 60 microm was

158 primary beam intensity of 100 pA, and (iii) raster sizes in the range of 8-15 mum.

159 We furthermore apply raster spectral image correlation spectroscopy for the s

160 e imaged on the fovea using Cirrus HD 1-line raster, Spectralis enhanced depth imaging (EDI), and RTV

161 is parameters like laser intensity and laser raster step size (spatial resolution in resulting image)

162 olecular mapping of the single cells under a rastering step size of 5 mum, even revealing lipid distr

163 tional adaptations, we have used optogenetic raster stimulation to map the laminar distribution of GA

164 Removing the need to raster the optics in two directions significantly reduce

165 Continuous ceramic coatings are produced by rastering the laser beam over a sample specimen.

166 the ion abundances in spectra obtained while rastering the laser over the tissue.

167 on of adjoining tiles, which are acquired by rastering the primary ion beam.

168 Here, we adapt this raster/vector concept to a 2D colloidal system and reali

169 bstantially higher rates using both standard raster volume (20.0%, 90% confidence interval [CI] 8.2%-

170 concurrent imaging with a standard (61-line) raster volume and a 24-line radial pattern.

171 mall full-thickness MHs compared to standard raster volume scanning.

172 The effects of surface scanning mode (raster vs unidirectional scanning) and the constancy of

173 omplex, patterned stimuli into the projected raster, whose exact locations on the retina were recorde