ライフサイエンスコーパス: dot

1 ion of IOH was preretinal (57%), blot (57%), dot (38%), flame-shaped (16%), and vitreous (8%); most I

2 erans with PTSD and 28 control Veterans on a dot probe task with negative-neutral word pairs.

3 ncoprotein expression using western blot and dot blot.

4 Moreover, immunostainings and dot blots of optic nerve and myelin showed that expressi

5 n reaction (PCR), real time PCR (RT-PCR) and dot blot hybridization have also been proposed for patho

6 images also showed fewer line fragments and dots in nonvascular areas and more continuous vessel ima

7 , blue-white veil (72 [53.7%]), globules and dots (68 [50.7%]), pseudopods or streaks (47 [35.1%]), a

8 indings suggest that the developed MAb based dot blot ELISA is a simple, rapid performed in less than

9 ere included for the evaluation of MAb-based dot blot ELISA.

10 atial biases by leveraging a novel bilateral dot motion detection paradigm.

11 having a width corresponding to the braille dot size.

12 We demonstrate application of the C-dot-hydrogel for evaluating the efficacy of a chemothera

13 The C-dot-hydrogel platform exhibits high sensitivity and dete

14 attention at the synthesis of carbon dots (C-dots) with the ability to interact with DNA to suggest a

15 ating luminescent amphiphilic carbon-dots (C-dots).

16 Primarily, C-dots modified with amine moieties were synthesized using

17 In addition, the C-dots (2.8+/-0.8nm) possessed a good colloidal stability

18 sonance energy transfer (FRET) between the C-dots and EtBr was studied, in which the C-dots serve as

19 collapses resulting in aggregation of the C-dots and quenching of their luminescence.

20 An interaction study of the C-dots and the DNA fragment of lambda bacteriophage was pe

21 C-dots and EtBr was studied, in which the C-dots serve as an excitation energy donor and the EtBr se

22 The C-dots showed strong photoluminescence with a quantum yiel

23 A binding of the C-dots to DNA was also observed as a change to DNA electro

24 minescent and absorption properties of the C-dots.

25 In this probe, a carbon dot-doped silica core serves as a reference and provides

26 A novel functionalized carbon dot has been synthesized by covalently linking beta-cycl

27 ess, fluorescence imaging of a single carbon dot and CD aggregate was simply achieved using filter-fr

28 On the basis of this carbon dot and (ferrocenylmethyl) trimethylammonium iodide (Fc(

29 sonance energy transfer(FRET) between carbon dots(CDs) and AuNPs as nanoquenchers.

30 extrin to the surface of N, S codoped carbon dots (beta-CD-CDs).

31 Moreover, we found tea-derived carbon dots can interact with ARF in nucleus that may further l

32 Fabrication of nitrogen-doped carbon dots (N-CDs) electrode for the screening of purine metab

33 Multiple-color-emissive carbon dots (CDots) have potential applications in various fiel

34 Herein, we report the fluorescent carbon dots as an effective and recyclable carbocatalyst for th

35 in the form of multilayer graphene ("carbon dots") have been under highly active study for applicati

36 ion of structurally similar graphitic carbon dots (CDs), with (g-N-CD) and without (g-CD) core nitrog

37 tubes, graphene variants, luminescent carbon dots, nanocrystals as quantum dots, and photon up-conver

38 om-up assembly route for monodisperse carbon dots (CDs) into different sizes of CD aggregates through

39 hotoluminescent carbon nanoparticles, carbon dots (CDs), are promising emerging light-harvesters for

40 med our attention at the synthesis of carbon dots (C-dots) with the ability to interact with DNA to s

41 The mild surface acidity of carbon dots imparted by -COOH functionality could effectively c

42 vel signal amplification strategy the carbon dots (CDs) functionalized with aptamer (CD-aptamer) used

43 encapsulating luminescent amphiphilic carbon-dots (C-dots).

44 of covert attention induced by a flashed cue dot, and a concurrent reduction, but not elimination, of

45 hat TRIM25 is redistributed into cytoplasmic dots associated with stress granules, while RIG-I associ

46 Ex vivo dermoscopy (EVD) with derm dotting (DD) improves clinicopathologic correlation and

47 multilayers patterned into 1 microm diameter dots, using scanning transmission x-ray microscopy.

48 of ordered arrays of graphene nano-domains (dots), epitaxially embedded in a two-dimensional boron-c

49 ption (biases towards smaller, denser, etc., dots) are evidence for the number's dependence on these

50 decreased to negative faces during the faces dot-probe task in the experimental versus control group

51 y of large arrays of highly-uniform graphene dots imbedded in a BCN matrix, enabling novel devices.

52 radient centrifugation, immunoprecipitation, dot and Western blotting, and confocal imaging were perf

53 ophysical assays including amyloid kinetics, dot blot, ELISA, and TEM show that 5 effectively inhibit

54 rticipants were then administered a modified dot probe task in which the cues were neutral and angry

55 nt data (a complex pattern of colored moving dots of different sizes).

56 The new dot blot detection system resolved individual IgE sensit

57 A novel dot blot-based assay system for the detection of IgE aga

58 gh recruitment of the cargo receptor nuclear dot protein 52 (NDP52).

59 erns was found to be a monotonic function of dot spacing, a result interpreted as evidence that rough

60 r study, the roughness of a different set of dot patterns was found to be a monotonic function of dot

61 as positively related to the motion speed of dot patterns.

62 sis showed that more than 92.593% (25/27) of dots fell within the limits of agreement.

63 Andreev bound states induced on each of dots hybridize to define Andreev molecular states.

64 both large (5-80) and small (1-4) numbers of dots, is facilitated in the monocular, subcortical porti

65 hich they could choose to categorize sets of dots on the basis of number alone, surface area alone or

66 Animals viewed grating or dot-field stimuli drifting in different directions.

67 by injecting approximately one electron per dot on average, we achieve a more than twofold reduction

68 Filling the nanowire with 4 electrons per dot creates a synthetic spin-one chain, with four-fold d

69 We perform dot-product operations with the 2D and 3D memristive cro

70 In addition, strongly positive perinuclear dots were observed in 30 of 36 specimens (83%).

71 anthanide-coordinated semiconducting polymer dots (Pdots), which possess fluorescence and mass signal

72 ASOs and LBPA were co-localized in punctate, dot-like structures, likely intraluminal vesicles (ILVs)

73 ion sequencing technology), and quantitative dot blot assays.

74 Quantum dot qubits, in contrast, are highly adjustable using ele

75 Strong coupling of a quantum dot electron to a cavity photon would allow for long-ran

76 Here we present a quantum dot signalling-based cell assay carried out in a segment

77 Specifically, we couple a quantum dot to a high-quality-factor microwave cavity to measure

78 yer molybdenum disulfide (MoS2), and quantum dot arrays with nanometer-scale spatial density by focus

79 We used lattice light-sheet and quantum dot-enabled synaptic contact mapping microscopy to show

80 top-down method to create large-area quantum dot arrays with nanometer-scale spatial density that all

81 he possibility of polarisation-based quantum dot applications in on-chip conditions.

82 via oriented attachment directed by quantum dot (QD) surface chemistry.

83 A single-sized CdSe quantum dot (3.0 +/- 0.2 nm) can replace several different dye c

84 aptopropionic acid (MPA)-capped CdSe quantum dot (MPA-CdSe QD) and visible light.

85 tudy reports the fabrication of CdSe quantum dot (QD)-sensitized photocathodes on NiO-coated indium t

86 The physical properties of a doped quantum dot (QD) are strongly influenced by the dopant site insi

87 charge configurations of the double quantum dot device.

88 ing of electronic states in a double quantum dot to form Andreev molecule states; a potential buildin

89 single electron in a silicon double quantum dot to the photonic field of a microwave cavity, as show

90 A boron-doped graphene quantum dot (B-GQD) as a metal-free multimodal contrast agent (C

91 This includes quantum dot radiative rate enhancement in microcavities, and a p

92 fer (NRET) from adjacent nanocrystal quantum dot (NQD) films.

93 Controlling the thickness of quantum dot (QD) films is difficult using existing film formatio

94 and k.p theory with consideration of quantum dot anisotropy allows us to elucidate the origin of the

95 The emerging generation of quantum dot optoelectronic devices offers an appealing prospect

96 solar energy applications in dye or quantum dot-sensitized solar cells, polymer-fullerene polymer so

97 Our quantum dot device architecture enables multi-qubit algorithms i

98 In particular, quantum dot circuits represent model systems for the study of st

99 exanoate (MHA) ligand shell of a PbS quantum dot (QD) and water.

100 Toward a truly photostable PbSe quantum dot (QD), we apply the thick-shell or "giant" QD structu

101 Here, we present quantum dot light emitting diodes (QDLEDs) with a metasurface-in

102 r tunnel coupling in a semiconductor quantum dot array so as to simulate a Fermi-Hubbard system.

103 ctron of a metal-oxide-semiconductor quantum dot.

104 of an electron confined in a silicon quantum dot.

105 ominally perfectly-fabricated single quantum dot device failing to behave in accordance with design.

106 ssary to improve the yield of single quantum dot nanophotonic devices.

107 the authors develop a tumor-specific quantum dot system that permits in vivo cation exchange to achie

108 s designed to resonantly enhance the quantum dot emission, thereby resulting in a nominally perfectly

109 ht illumination while preserving the quantum dot in the desirable cubic crystal phase.

110 tably tuned through variation of the quantum dot-molecule energy gap, temperature and the triplet-exc

111 a route for further progress towards quantum dot electron spin qubits where deep cooling of the mesos

112 Here transparent quantum dot light-emitting diodes (Tr-QLEDs) are reported with h

113 pole charge qubit formed in a triple quantum dot.

114 abeling of the apoptotic cells using quantum dot reporters.

115 strate an ultrathin freestanding ZnO quantum dot (QD) active layer with nanocellulose structuring, an

116 Quantum dots (QDs) are extremely bright, photostable, nanometer

117 Quantum dots-Gold nanoparticle (QDs-GNP) based FRET probes invol

118 probes including mechanophores(10), quantum dots(11), fluorescent pairs(12,13) and molecular rotors(

119 nuclear polarization in GaAs/AlGaAs quantum dots with high accuracy using a new approach enabled by

120 lly, the combination of graphene and quantum dots was also included to explore the fluorescence prope

121 ing from classical dyes to drugs and quantum dots, allowing changes in the photochemical behavior of

122 sed probes, including Alexa dyes and quantum dots.

123 es over traditional organic dyes and quantum dots.

124 ngle or colloidal) dye molecules and quantum dots.

125 Fluorescent nanoparticles such as quantum dots (QD) offer superior optical characteristics compare

126 nescent carbon dots, nanocrystals as quantum dots, and photon up-converting particles.

127 other biotinylated molecules such as quantum dots.

128 efects in diamond and self-assembled quantum dots, albeit often with compromised coherence and optica

129 y on electron-transfer rates between quantum dots (QDs) in chiral QD assemblies.

130 QDs) combined with two biofunctional quantum dots (QDs) were used for simultaneously detecting two pr

131 Carbon quantum dots (CQDs) obtained from natural organics attract signi

132 as Ti-Si molecular sieves and carbon quantum dots (CQDs), are also briefly appraised in view of their

133 Carbon quantum dots (CQDs), with an average size around 3.2 nm, are fab

134 ly fluorescent nitrogen doped carbon quantum dots (NCQDs) were synthesized using microwave assisted g

135 Magnetically N-doped Carbon quantum dots has been synthesized via a simple chemical method a

136 e, novel nanocarriers such as carbon quantum dots with their recent applications in drug delivery wil

137 of N-acetyl-L-cysteine capped CdAgTe quantum dots (NAC-CdAgTe QDs) and dodecahedral gold nanoparticle

138 CdTe/CdS quantum dots (QDs) are encapsulated in the pores of the mesoporo

139 ndex material and colloidal CdSe/CdS quantum dots (QDs) for applications in the visible region.

140 isible-light-absorbing colloidal CdS quantum dots (QDs), without a sacrificial oxidant or reductant,

141 onse in the fluorescence of CdTe@CdS quantum dots (QDs).

142 Immobilization on CdS quantum dots allows these catalysts to be active in purely aqueo

143 oncept, we use downshifting CdSe/CdS quantum dots to improve the performance of a silicon solar cell.

144 e reactions with as-synthesized CdSe quantum dots (QDs) are chosen as two model reactions.

145 ze 2.8, 4.6, 7.2, or 9.0 nm and CdSe quantum dots (QDs) of size approximately 3.3 nm.

146 ecarboxylic acid-functionalized CdSe quantum dots undergo thermally activated delayed photoluminescen

147 onent ligand shells passivating CdSe quantum dots.

148 oxylates on the (100) facets of CdSe quantum dots.

149 TGA)-capped cadmium-telluride (CdTe) quantum dots (QDs) exposing green emission were directly synthes

150 g not neutral but negatively charged quantum dots.

151 erials, for example, NaBr, collagen, quantum dots, silver and polystyrene colloids.

152 Colloidal quantum dots (CQDs) feature a low degeneracy of electronic state

153 Recently, doped colloidal quantum dots (CQDs) have been demonstrated to be promising mater

154 Emission control of colloidal quantum dots (QDs) is a cornerstone of modern high-quality light

155 es are usually quenched in colloidal quantum dots by Auger and other nonradiative decay channels.

156 Aptamer-conjugated Quantum dots (QDs) are adsorbed to Au nanoparticles (AuNPs) due

157 LGA) with bright, spectrally defined quantum dots (QDs) to enable direct, fluorescent detection of na

158 Electron spins in gate-defined quantum dots provide a promising platform for quantum computatio

159 Here we show that for gate-defined quantum dots this disorder can be suppressed in a controlled man

160 rted to date in Si/SiGe gate-defined quantum dots.

161 125) using polyamidoamine dendrimer-quantum dots (PAMAM-QDs) and PAMAM-sulfanilic acid-Ru(bpy)3(2+)

162 Double quantum dots (DQDs) are a versatile platform for solid-state phy

163 Here, double quantum dots are defined by gate voltages in indium antimonide n

164 ted with proteins, fluorescent dyes, quantum dots, and magnetic nanoparticles can be further produced

165 secondary antibody labeled with dyes/quantum dots (QDs) was used to visualize the presence of the tar

166 ansport layers (ETLs) and engineered quantum dots (QDs).

167 photodoping to specially engineered quantum dots with impeded Auger decay, we demonstrate a consider

168 Subsequent etching quenches excess quantum dots, leaving a highly tumor-specific signal provided by

169 old narrower, respectively, than for quantum dots.

170 C-synthesized materials ranging from quantum dots to submicrometer spheres and recent upscaling advan

171 f arrays of self-assembled InAs-GaAs quantum dots (QDs) has been quantified as a function of growth r

172 containing self-assembled InAs/GaAs quantum dots-a mature class of solid-state quantum emitter-with

173 als cover gold nanoparticles (GNPs), quantum dots (QDs), carbon nanotubes (CNTs), and graphene oxide

174 of a new magnetic chitosan-graphene quantum dots (Fe3O4@Chi-GQDs) nanocomposite as an adsorbent for

175 oparticle (AgNPs) and thiol graphene quantum dots (GQD-SH) as the nanomaterial for ultrasensitive and

176 Biofunctional magnetic graphene quantum dots (GQDs) combined with two biofunctional quantum dots

177 presence and the absence of graphene quantum dots (un-functionalized), respectively.

178 ng signal at functionalized graphene quantum dots based imprinted sensor was realized to be about 3-

179 Graphene quantum dots embedded silica molecular imprinted polymer (GQDs-e

180 Herein, graphene quantum dots in nanocomposite practically induced the electrocat

181 vely charged functionalized graphene quantum dots in the film and the target analyte toward the enhan

182 uniform-size semiconducting graphene quantum dots laterally integrated within a larger-bandgap matrix

183 the covalent attachment of graphene quantum dots with N-acryloyl-4-aminobenzamide molecules might ex

184 ed through self-assembly of graphene quantum dots.

185 limited to 50-65% for the nuclei in quantum dots.

186 ported so far for optical cooling in quantum dots.

187 ods as model plasmonic systems, InAs quantum dots (QDs) embedded in an InGaAs quantum well as an emit

188 emiconductor device: a chain of InAs quantum dots embedded in an InP nanowire.

189 As nanophotonic geometries with InAs quantum dots.

190 single, isolated self-assembled InAs quantum dots.

191 controlled positioning of individual quantum dots in the near field of gold nanocone antennas, we enh

192 The system uses near-infrared quantum dots and a membrane-impermeable etchant, which serves as

193 ecific signal provided by the intact quantum dots remaining in the extravascular tumor cells and fibr

194 in agreement with a numerical model.Quantum dots in a nanowire are one possible approach to creating

195 Zero-dimensional MoS2 quantum dots (QDs) possess distinct physical and chemical proper

196 e we show that colloidal nanocrystal quantum dots (QDs) can serve as efficient and robust, precious-m

197 colloidal semiconductor nanocrystal quantum dots (QDs) have been central to the field for over 30 ye

198 The use of semiconductor nanocrystal quantum dots (QDs) in optoelectronic devices typically requires

199 scale systems, including nanocrystal quantum dots, carbon nanotubes and graphene.

200 (MNPs), carbon based nanomaterials, quantum dots (QDs), magnetic nanoparticles and polymeric NPs hav

201 orescent dyes ( approximately 4 nm), quantum dots, either small ( approximately 10 nm diameter; sQDs)

202 is structured by stacking a layer of quantum dots (QDs) and a layer of piezoelectric material.

203 Chains of quantum dots coupled to superconductors are promising for the re

204 e and size controlled fabrication of quantum dots in monolayer molybdenum disulfide (MoS2), and quant

205 Ordered arrays of quantum dots in two-dimensional (2D) materials would make promis

206 A sub-monolayer CdS shell on PbS quantum dots (QDs) enhances triplet energy transfer (TET) by sup

207 ic impurity doping of colloidal PbSe quantum dots (QDs) using a postsynthetic cation exchange reactio

208 t that cesium lead iodide perovskite quantum dots (CsPbI3 QDs) can be used as catalysts to promote th

209 ipate that the approach of screening quantum dots not only based on their optical properties, but als

210 anomaterials, such as semiconducting quantum dots (QDs), metal nanoparticles, semiconductor-metal het

211 emission by colloidal semiconductor quantum dots (qdots).

212 Luminescent semiconductor quantum dots (QDs) are one of the more popular nanomaterials cur

213 Chemically synthesized semiconductor quantum dots (QDs) can potentially enable solution-processable l

214 nd, more specifically, semiconductor quantum dots (QDs) have emerged as crucial materials for the dev

215 Colloidal semiconductor quantum dots are attractive materials for the realization of sol

216 device fabrication of semiconductor quantum dots continue to improve, the ideas presented here will

217 attractive feature of semiconductor quantum dots for optoelectronics applications.

218 nal confinement allows semiconductor quantum dots to exhibit size-tunable electronic and optical prop

219 In 2000, semiconductor quantum dots were shown to emit single photons, opening a path t

220 lable organic dyes and semiconductor quantum dots, the CD aggregates provided a 10-7000-fold improvem

221 lement of electrons in semiconductor quantum dots.

222 tive materials such as semiconductor quantum dots.

223 e oils, based on CdSe/ZnS core-shell quantum dots sensitized with lithium tetracyanoethylenide (LiTCN

224 Qubits based on silicon quantum dots are emerging as leading candidates for the solid-st

225 be with conventional methods.Silicon quantum dots provide a promising platform for quantum computing

226 demonstrate the patterning of single quantum dots (QDs) at predefined locations on silicon and transp

227 report optical positioning of single quantum dots (QDs) in planar distributed Bragg reflector (DBR) c

228 ment to applications in which single quantum dots are embedded within nanofabricated photonic devices

229 pproach that allows to assess single quantum dots as candidates for quantum nanophotonic devices.

230 tion techniques, we find that single quantum dots often appear in the vicinity of comparatively large

231 between Si3N4 waveguides and single-quantum dots in GaAs geometries, with performance approaching th

232 n parametric downconversion sources, quantum dots, colour centres or atoms are fundamentally differen

233 conductor nanocrystals, specifically quantum dots (QDs), can be tuned over 2.0 eV through surface che

234 ntrol can be achieved in solid-state quantum dots at thermoelectrically cooled temperatures, thereby

235 on control by growth, in solid-state quantum dots in the thermoelectrically cooled temperature regime

236 nic acid (3-MPA) capped lead sulfide quantum dots were prepared in a variety of organic solvents stab

237 h of CSH-stabilized cadmium sulphide quantum dots (CdS QDs).

238 While individual superconducting quantum dots have been explored, control of longer chains requir

239 We synthesized cadmium telluride quantum dots (CdTe QDs) capped with thioglycolic acid (TGA) as a

240 mine the impact of cadmium telluride quantum dots (CdTe QDs).

241 The quantum dots are intravenously delivered into orthotopic breast

242 Despite this, the quantum dots generally do not exhibit significant differences in

243 By designing the quantum dots in a 2D superlattice, we show that new energy bands

244 trolled by the size and pitch of the quantum dots in the superlattice.

245 The etchant rapidly quenches the quantum dots through cation exchange (ionic etching), and facili

246 scale spatial density that allow the quantum dots to interfere with each other and create artificial

247 ance of metal ions released from the quantum dots.

248 ed emission spectra in comparison to quantum dots appearing in defect-free regions, and this behavior

249 o deterministically couple donors to quantum dots in arrays of qubits.

250 lective etching of excess untargeted quantum dots.

251 more complex many-body states using quantum dots.

252 pling (100x) from PHCs embedded with quantum dots is observed.

253 From this, it is determined that ZnO quantum dots on bulk n-InGaN with low In content x is the most d

254 ed on l-cysteine capped Mn doped ZnS quantum dots (l-cys ZnS:Mn QDs).

255 The dye rhodamine and two InP/ZnS quantum dots (QDs) emitting in the green and in the red regions

256 lloidal, heavy metal-free CuInS2/ZnS quantum dots (QDs) to reduce CO2 to CO using 450 nm light.

257 pair, including the donor, CdSe/ZnS quantum dots (QDs), and the acceptor, dextran-binding malachite

258 water soluble l-cysteine capped ZnS quantum dots (QDs).

259 ttices (HNC-SLs) self-assembled from quantum-dot-Au (QD-Au) satellite-type HNCs.

260 Here, we use quantum-dot-coated nanopipette electrodes (tip diameters approxi

261 mall as 50 nm in diameter and single quantum-dots.

262 re asked to classify the speed of 2-D raised dot patterns passing under their right middle finger.

263 ns about the net direction of dynamic random dot motion.

264 and even better sensitivity to higher random dot stimulus velocities.

265 ision loss on motion perception using random dot kinematograms to test the capacity for form from mot

266 range of reading abilities were shown random-dot displays spatially divided into horizontal segments.

267 cence and Raman signals to detect the F-SERS dots.

268 ter spraying with a dose of 50 microg F-SERS dots.

269 d surface-enhanced Raman scattering (F-SERS) dots.

270 ical total masses greater, similar160Mmiddle dot in circle, greater, similar60Mmiddle dot in circle a

271 dle dot in circle, greater, similar60Mmiddle dot in circle and greater, similar90Mmiddle dot in circl

272 dot in circle and greater, similar90Mmiddle dot in circle, for GW150914, GW151226 and LVT151012, res

273 electron spin qubits requiring only a single dot and no additional magnetic field gradients, as well

274 decrease the band-edge degeneracy and single-dot photoluminescence linewidth in CQDs by means of unif

275 dividual CQDs exhibit an ultra-narrow single-dot linewidth, and we successfully propagate this into t

276 res deep inside silicon using 1 microm-sized dots and rod-like structures of adjustable length as bas

277 rious normal tissues and particularly strong dot-like perinuclear staining in the lining epithelial c

278 cal interaction (PPI) analysis revealed that dot periodicity modulated functional connectivity betwee

279 ted chirality of the acceptor QDs affect the dot-to-dot electron-transfer kinetics.

280 to measure with exceptional sensitivity the dot's electronic compressibility, that is, its ability t

281 gap, we simulated afferent responses to the dot patterns used in these roughness coding experiments

282 The dots were hyperautofluorescent on fundus autofluorescenc

283 to the point where we can truly connect the dots at the molecular level.

284 ium nitride contacts are made to each of the dots in order to induce superconductivity, as well as pr

285 er, indicating that chiral imprinting of the dots may lie at the origin of this phenomenon.

286 tudied as a function of charge parity on the dots, and in magnetic field.

287 As these connect-the-dots become brighter and expand into more and more remot

288 These dots exhibit a strikingly uniform size of 1.6 +/- 0.2 nm

289 p-benzoquinonemonoimine C6 H2 (-cdots, three dots, centered NH2 )2 (-cdots, three dots, centered O)2

290 , three dots, centered NH2 )2 (-cdots, three dots, centered O)2 .

291 ncovalently packed via two Au(I)cdots, three dots, centeredCu(I) metallophilic interactions, whereas

292 tely planar, likely via S(alkyl)cdots, three dots, centeredS(thiophene) intramolecular locks.

293 lization: Landolt-C gap resolution and three-dot bisection.

294 to speed) and postcentral gyrus (related to dot periodicity).

295 nd superior parietal lobule was sensitive to dot periodicity.

296 rality of the acceptor QDs affect the dot-to-dot electron-transfer kinetics.

297 eye movements and perception of translating dot patterns.

298 prominent moth (Symmerista albifrons), White-dotted prominent moth (Nadata gibosa), Monarch butterfly

299 ects had bilateral symmetric multiple yellow dots at the macula.

300 zed by bilateral multiple early-onset yellow dots at the macula.