ライフサイエンスコーパス: excite

1 only a minority of sites can be selectively excited.

2 ), the area in space in which visual stimuli excite a neuron(1).

3 h to routine clinical practice represents an exciting advance in respiratory medicine.

4 Exciting advances have been made over the past several y

5 is strategy to open new doors and facilitate exciting advances in angiogenesis-mediated treatment of

6 Exciting advances in the application of nanotechnology a

7 These exciting advances, coupled with increasingly sophisticat

8 emely short optical pulses to non-resonantly excite an electron-hole plasma and show the formation of

9 iments employed piezoelectric transducers to excite and detect longitudinal ultrasound waves of vario

10 the radiotherapy-induced Cherenkov light to excite and image the phosphorescence lifetimes within th

11 rons and indicates that MOC neurons are both excited and inhibited by sound stimuli received at the s

12 vements resembling macroscopic objects is an exciting and challenging endeavor.

13 bled into chiral architectures, represent an exciting and growing class of nanomaterials.

14 aqueous droplets (microdroplets) in oil were excited, and the fluorescence intensity was recorded as

15 e and molecular dynamics calculations of the excited- and ground-state molecules, the results provide

16 s in this fascinating organism, now enabling exciting applications - from speeding up our everyday la

17 We also summarize the broad and exciting applications of SPRM to the analysis of single

18 l properties that lend themselves to new and exciting applications.

19 This observation is particularly exciting as it provides mechanistic insight into OA susc

20 transfer from the PE(4) segment to NDI when excited at 370 nm, but it does not produce a charge-sepa

21 occurring from the PE(4) segment to NDI when excited at 370 nm, followed by delocalization of the hol

22 es not produce a charge-separated state when excited at 420 nm (T(4)).

23 In DM-PSI preparations excited at 740 nm, the excitation remained localized on

24 s the visible and near-infrared spectra when excited at a single wavelength through optical colour co

25 Zenneck waves are excited at interfaces, like surface plasmons and have th

26 lting scaffold promoting uptake of electrons excited at the AgNC.

27 int can support sheet and edge surface modes excited at the free space wavelength hundred times large

28 tailored (6,5) carbon nanotubes which, when excited at their first order excitonic transition (~985

29 ergy released by electronic relaxation of an excited atom or molecule leads to ionization of a neighb

30 importance of electron correlations in these excited atomic states.

31 However, a more exciting avenue is the detection of certain biomarkers a

32 ct that we have so many materials opens many exciting avenues but also create new challenges.

33 ection between these processes also provides exciting avenues for future research.

34 lattice remains elastic and can be thermally excited between lattice configurations reversibly.

35 wed by an alkyne-allene isomerization of the excited branch.

36 d underneath the matching layer, efficiently excites bulk metamaterial modes, which have well-resolve

37 at the intracellular destination site is an exciting but also challenging proposition.

38 thermal expansion when a vibrational mode is excited by a tunable IR laser (QCL: 800-1800 cm(-1) or O

39 indicate 66% (23 of 35) of OVLT neurons were excited by bath application of both hypertonic NaCl and

40 The sample is excited by femtosecond laser pulses with a repetition ra

41 s, among them putative dopamine neurons, are excited by footshocks, and acquire a response to auditor

42 pressing (SOM) inhibitory neurons, which are excited by head movements in dark, but not in light.

43 es of those fluorophores that are indirectly excited by homo-FRET (r(ET)) do not compromise the accur

44 s of the ON type of parasol cells, which are excited by increments in light intensity.

45 st fish, are inhibited by Purkinje cells and excited by parallel fibers.

46 t emit in the near-UV (3.27 eV, 380 nm) when excited by sub-bandgap light.

47 at two-thirds of V2a neurons in lamina X are excited by the Mc4r agonist alpha-MSH, and acute inhibit

48 revealed that these neurons are selectively excited by the unconditioned stimulus (US) during fear c

49 atching could occur between predisposing and exciting causes in individuals who had "special suscepti

50 d that it was easier to prevent exposures to exciting causes than to reverse predispositions.

51 Psychological traumas were key exciting causes, but so were somatic diseases, pregnancy

52 , and perverse manner of life," which became exciting causes.

53 Chlamydomonas reinhardtii evolved blue light-excited channelrhodopsins (ChR1, 2) to navigate.

54 Janus crystals represent an exciting class of 2D materials with different atomic spe

55 ing and semiconducting polymers represent an exciting class of materials for bioelectronic devices, t

56 e beauty of the underlying chemistry of this exciting class of materials.

57 ributes of two-dimensional perovskites as an exciting class of optoelectronic materials.

58 at the angular momentum carried by microwave-excited coherent spin waves in a V(TCNE)(x) film can be

59 X-ray diffraction measurements of excited colloidal crystals may then lead towards a bette

60 age immunometabolism in atherosclerosis, new exciting concepts and potential targets for intervention

61 requires characterization of the ground and excited conformation states.

62 ory RNAs have been shown to transiently form excited conformational states (ESs) that remodel local a

63 is highlights the emerging opportunities for exciting "crossover" reactivity offered by these derivat

64 These exciting developments have fueled efforts to develop nov

65 ics, but also enables exploration of new and exciting dimensionality-driven magnetic phenomena.

66 , while VMHvl-projecting PA(Esr1+) cells are excited during intermale aggression and promote attacks.

67 velocities when the chiral Weyl fermions are excited during selective optical transitions between the

68 As a result, many exciting effects of solute-solvent interactions in moder

69 nt arises from the blockage of the optically excited electron transfer from MoSe(2) to WS(2).

70 the compressibility of plutonium's thermally excited electronic configurations, which has thus far no

71 The nature of the excited electronic state is identified with excellent sp

72 nadiabatic dynamics simulations to study the excited electronic states of model amyloid-like peptides

73 e efforts laid the foundation for the recent exciting era of cancer immunotherapy, which includes imm

74 eloping technologies have recently fueled an exciting era of discovery in the field of chromosome str

75 In this Review, we discuss emerging and exciting evidence of intricate and crucial connections b

76 An exciting feature of this synthetic protocol is that the

77 tended ligand CT character of electronically excited FeNHCPZn.

78 ojecting the reader at the forefront of this exciting field of physical chemistry, we believe that th

79 techniques to guide future research in this exciting field.

80 To bridge this gap and illustrate exciting findings emerging from studies of the dark prot

81 These exciting findings have redefined BA signaling in health

82 ed discipline, has recently sparked numerous exciting findings on microglia, the resident macrophages

83 Two-photon excited fluorescence (TPEF) microscopy is a label-free,

84 ough combining particle scattering, sunlight-excited fluorescence, and mid-infrared broadband radiati

85 ue to network interactions, activity in this excited frequency band propagates to nearby regions.

86 h principal cells in the rat (both sexes) OB excite GCs by evoking potent nondepressing EPSPs (termed

87 ency acousto-optic modulation is realized by exciting high-overtone bulk acoustic wave resonances (HB

88 Exciting high-resolution structural details of these cha

89 ulvenes (159 of 225) are described by singly excited HOMO -> LUMO configurations, providing a rationa

90 nces the diffusion of enzymes have generated exciting implications about nanoscale energy flow, molec

91 the directional emission of Huygens dipoles excited in an individual dipolar antenna.

92 is targeting chimeras (PROTACs) represent an exciting inhibitory modality with many advantages, inclu

93 We will briefly outline some of the most exciting, innovative and translational scientific advanc

94 uned circuit, thereby allowing signals to be excited inside the cell, and for them to subsequently be

95 Recent studies have provided exciting insights about the unique characteristics of sk

96 work in nonmodel systems promises to provide exciting insights in the years to come.

97 generation and storage devices, and address exciting instances that profile the multifunctionality o

98 erently weak spontaneous Raman scattering by exciting localized surface plasmon resonance (LSPR) on m

99 ed the scope for wider applications of these exciting materials.

100 ion of experiment and modeling to provide an exciting mechanistic insight into the relationship betwe

101 s, the Drosophila spermathecal lineage is an exciting model for probing the molecular mechanisms that

102 ur orders of magnitude for FFR of spin-orbit excited molecular ions with merged beam and electrostati

103 ed with a 110 fs time constant by 40% of the excited molecules while the rest relax to a (3)MLCT exci

104 Cue-excited neurons showed greater increases in firing and c

105 Review surveys the current progress of this exciting new area.

106 o develop synthetic counterparts, leading to exciting new behaviors in man-made structures.

107 movement ecology can be extended to use this exciting new data type.

108 s review moves through pioneering studies to exciting new findings.

109 y of practical applications and is providing exciting new insight into the biology of CRISPR-Cas syst

110 Here, we focus on exciting new insights into effectors that target abiotic

111 le, we discuss recent work that has revealed exciting new insights into the molecular mechanisms that

112 With exciting new NASA plans for a sustainable return to the

113 ular intervention for AF management presents exciting new opportunities, along with substantial chall

114 This finding offers an exciting new opportunity for small-molecule targeted cov

115 CHAT presents an exciting new peptide for the delivery of nucleic acid th

116 (electro)materials science and will open up exciting new possibilities through the use of aprotic so

117 action in biological environments to produce exciting new prospects for biomedicine.

118 signalling in immune cells and conclude with exciting new research demonstrating an immutable role fo

119 The EGFR-sfGFP fly is an exciting new resource for studying cellular localization

120 orted proline-based STAT3 inhibitors into an exciting new series of (R)-azetidine-2-carboxamide analo

121 As we enter an exciting new stage in maize genomics, this retrospective

122 )d-d state features a weak Ni-aryl bond, the excited Ni(II) complexes can undergo Ni homolysis to gen

123 associated secretory phenotype, favoring the exciting notion that thus far unknown mechanisms must be

124 While single dramatic events often excited onset, daily repetition of lesser shocks could a

125 data at a rapidly increasing rate, providing exciting opportunities and formidable challenges to exis

126 alization, the family of gel materials opens exciting opportunities for advanced energy technologies.

127 Micro- and nanoscale metallic glasses offer exciting opportunities for both fundamental research and

128 Phase-transition materials provide exciting opportunities for controlling optical propertie

129 electric nanostructures have recently opened exciting opportunities for functional nanophotonics, owi

130 the level of myeloid progenitors, which adds exciting opportunities for novel treatment strategies.

131 of sub-nanometer bimetallic clusters offers exciting opportunities for tailoring their catalytic per

132 of major challenges in the field along with exciting opportunities for the future of macrophage-base

133 ) H(9) )(60) ions (33.7 kDa), which opens up exciting opportunities for the structural characterizati

134 n of these older drugs might in turn provide exciting opportunities for the understanding of disease

135 rate the ways in which photoswitches present exciting opportunities for their use in optofluidics app

136 rent interest in account of the many new and exciting opportunities it offers for, for example, quant

137 vations in offline and online MRI-guided RT, exciting opportunities they offer for advancing research

138 multisensory processing, while also opening exciting opportunities to facilitate early learning thro

139 These advances provide exciting opportunities to profoundly transform synthetic

140 /CT in other areas such as orthopedics offer exciting opportunities.

141 very large sample sizes, biobanks provide an exciting opportunity to identify genetic components of c

142 or a large number of participants provide an exciting opportunity to perform genome-wide association

143 method of cell therapy delivery provides an exciting opportunity to recondition organs prior to tran

144 ht-sensitive opsins and then optogenetically excited or inhibited the neurons while evaluating cardio

145 s produced through quenching of an optically excited organic sensitizer.

146 erature, a fraction of the quantum liquid is excited out of the condensate into higher momentum state

147 he lowest resonance to consist of coherently excited pairs only.

148 search, which led to the observation of many exciting phenomena such as quantized vortices, second so

149 This study reveals an exciting phenomenon that light is an ideal external stim

150 how distinctly different one- and two-photon excited photoluminescence energies: from free-excitons (

151 ural phase space, which has led to novel and exciting physical properties.

152 Quantum spin liquids are an exciting playground for exotic physical phenomena and em

153 These results generate exciting possibilities for treatment of RP patients with

154 This finding presents an exciting possibility of designing other 14-3-3 compounds

155 This suggests the exciting possibility that undesirable opioid side effect

156 these studies, the CANTOS trial, raises the exciting possibility that, in the foreseeable future, we

157 Our goal is to convey the exciting potential of analytical chemistry to contribute

158 ons and localized plasmons and summarize the exciting progress it has opened by the ultrafast imaging

159 Recently, the exciting progress of materials design has promoted the d

160 the periodic table have already demonstrated exciting properties such as near-room-temperature topolo

161 Finally, the challenges with, and exciting prospects of, CRISPR based biosensing developme

162 e systems under study, and take advantage of exciting recent advances in modeling the relations betwe

163 Exciting recent data have provided novel insights into h

164 molecular photon upconversion (TTA-UC) is an exciting research area for a broad range of photonic app

165 mation has been lacking, and it will open an exciting research direction on how drug distribution aff

166 ial intelligence can be used to advance this exciting research field in all its aspects.

167 This concept not only opens exciting research possibilities but also encourages clin

168 esting where the dissipated heat in a sample excites resonant magnons in a thin ferromagnetic metal l

169 Here, we study helium nanodroplets excited resonantly by femtosecond extreme-ultraviolet (X

170 Early experiments have yielded exciting results; however, there are limited options to

171 raining becomes effective during sleep, with excited reward processing sending inhibitory signals to

172 The CT neurons in S1 synaptically excited S1-projecting thalamocortical (TC) neurons in su

173 that a similar mechanism is responsible for exciting Saturn's hexagonal flow pattern.

174 By applying a short ultrasound pulse to excite single microbubbles tethered to cell membranes, a

175 optically create and investigate low-energy excited spin states in the Mott insulator.

176 ric Cyt c is entirely due to a cascade among excited spin states of the iron ion, causing the ferric

177 Some of these probes represent exciting starting points with the potential to illuminat

178 otoexcitation of the anthracene to a locally excited state (LES) is followed by concerted electron tr

179 aticity upon excitation to the first triplet excited state (T(1)).

180 This complex was found to have a long-lived excited state (tau = 4 ns), which was computationally as

181 being more anisotropic in AB stacking, where excited state absorption related to Exc.

182 heir photoreaction due to an increase in the excited state barrier for photorelease.

183 Fs-TA studies were performed to monitor excited state CT events.

184 let fission (iSF) process is responsible for excited state deactivation in isoindigo derivatives.

185 ient photoreactions by thwarting competitive excited state decay channels.

186 that the spin of the initially populated FC excited state differs from that of the ground state, eve

187 en located for simple BODIPY structures from excited state dynamic simulations.

188 ckness-dependent modulation of the ultrafast excited state dynamics in the 2DP/MoS(2) heterostructure

189 the photoinduced processes that govern their excited state dynamics.

190 The excited state electron density distributions are thus am

191 -metal charge transfer ((2)LMCT) photoactive excited state exhibits donor-dependent charge separation

192 The nature of the lowest excited state in these complexes changes character from

193 asymmetric torsional potential, and a 'free' excited state in which FliJ undergoes rotational diffusi

194 (C(60/70)), with the noncovalent ground and excited state interactions that occur upon fullerene gue

195 The "Franck-Condon" (FC) excited state is the first state created when a molecule

196 tum-chemical calculations to demonstrate the excited state leading to the formation of the thietane i

197 Challenges, in particular the extension of excited state lifetimes, and recent conceptual breakthro

198 fer involving the lowest-energy ligand-field excited state of the Fe(II)-based photosensitizer, defin

199 olecular process occurring on the long-lived excited state of the Ni(II) complex.

200 dies allude to a catalytic cycle whereby the excited state of the organophotocatalyst is reductively

201 mprove the quantum yields of photorelease by excited state participation and blocking ion pair recomb

202 rophores, photoswitching agents, and triplet excited state quenchers for single-molecule and super-re

203 he SLR calculations provide estimates of the excited state radiative line width, which we relate to t

204 that the newly formed isomer appears in the excited state rather than in the ground state.

205 vepacket on a triplet metal-centered ((3)MC) excited state surface.

206 sting an intersystem crossing to the triplet excited state with subsequent phosphorescent decay.

207 y the electronic coupling between the lowest excited state, which has charge-transfer (CT) character,

208 ng benzene's physicochemical behavior in its excited state, while molecular motion, predicted for sev

209 e photodissociation of ICN in the (1) Pai(1) excited state, with emphasis on the transient response i

210 harge transfer (ICT) also contributes in the excited state.

211 d photoluminescence (PL) from a spin-singlet excited state.

212 at could be coupled to the bright (1)paipai* excited state.

213 molecules while the rest relax to a (3)MLCT excited state.

214 ant cumulenic character of the bridge in the excited state.

215 series of complexes allows for tuning of the excited-state "turn-on" of aurophilicity, where ligand t

216 that QDs impart stereoselectivity to triplet excited-state [2 + 2] cycloaddition reactions of alkenes

217 An in-depth study of the excited-state also revealed the preferential relaxation

218 T(2)) of benzene and cyclobutadiene (CBD) as excited-state antiaromatic and aromatic archetypes, resp

219 strategies on how to use Baird's 4n rule on excited-state aromaticity, combined with Huckel's 4n + 2

220 penheimer molecular dynamics, ab initio, and excited-state calculations led to unambiguous assignment

221 nes does not contribute significantly to the excited-state chemistry of these molecules.

222 These results demonstrate that using excited-state coherence data may be used to tailor ultra

223 near-IR sensitizer, azaBODIPY, for promoting excited-state CS.

224 more regular beta strand configuration in an excited-state dimer, as well as exchange of both monomer

225 These dark excitons dominated the excited-state distribution, a surprising finding that hi

226 ctions involving neutral organic radicals as excited-state donors or acceptors.

227 consistent with electronic spectroscopic and excited-state dynamical data, further underscoring the d

228 machine learning for excited states include excited-state dynamics simulations, static calculations

229 herence data may be used to tailor ultrafast excited-state dynamics through targeted synthetic design

230 ption techniques were performed to probe the excited-state dynamics, revealing ultrafast charge separ

231 reorganization energy of 0.7 +/- 0.1 eV for excited-state electron transfer.

232 s, we also provide a short introduction into excited-state electronic structure methods and approache

233 lifetime extension utilizing triplet-triplet excited-state equilibria is detailed.

234 Whereas excited-state events on the ps timescale have been struc

235 ctroscopic techniques were used to track the excited-state evolution of the employed iridium photocat

236 nitrogen tunneling and the first example of excited-state heavy-atom tunneling.

237 Excited-state injection often occurs on ultrafast time s

238 ed with radical formation beyond the initial excited-state Ir(ppy)(3) oxidation.

239 The initial establishment of excited-state lifetime extension utilizing triplet-tripl

240 onfirming the importance of the newly formed excited-state manifold in TBPCExBox(4+) for the populati

241 s work provides a substantial advance in the excited-state physical chemistry of luminescent nanoclus

242 to attenuate solvent-dependent mechanisms of excited-state quenching through addition of a beta-carbo

243 thway would encourage the development of new excited-state reactivities in the field of metallaphotoc

244 psilon = 9800 M(-1) cm(-1), at 450 nm and an excited-state reduction potential, E(Ir(+*/0)) = 1.76 V

245 resolution techniques capable of identifying excited-state signatures and molecular identities of the

246 achine learning is employed to speed up such excited-state simulations but also how this branch of ar

247 Together with a previous excited-state study, our data allow establishing a detai

248 Such unexpected slow process of excited-state transformation results in near-infrared du

249 and make possible the fluorescence from S(2) excited states (phosphorescence from T(2) excited states

250 gand field splitting allows direct access of excited states aligned along and perpendicular to the IC

251 The multiplicity of the productive excited states and the role of oxygen (O(2)) in the CO p

252 st be maintained by stabilizing these highly excited states and, at the same time, the system has to

253 Besides the SOC induced ISC pathway, triplet excited states are also realised in organic chromophores

254 eraged single ensemble and not from a set of excited states emitting with distinct luminescence decay

255 into the diverse pathways to access triplet excited states in organic chromophores.

256 s suppress internal conversions of the upper excited states in the solids and make possible the fluor

257 scussed applications of machine learning for excited states include excited-state dynamics simulation

258 lems when using them in machine learning for excited states of molecules.

259 with computational modeling of the emissive excited states of representative examples.

260 The metal-to-ligand charge transfer (MLCT) excited states of Ru polypyridyl compounds serve as the

261 he molecular orbitals that contribute to the excited states that are precursors to CS.

262 of the nature and energy level of low-lying excited states that could be coupled to the bright (1)pa

263 ) on electronic relaxation, transitions from excited states to ground states, is well studied, but th

264 signatures of spatial delocalization of the excited states which are characteristics of dynamics in

265 ly advantageous, a detailed understanding of excited states with ligand-to-metal charge transfer (LMC

266 opment featuring early transition metals and excited states with significant LMCT contributions.

267 2) excited states (phosphorescence from T(2) excited states).

268 re aromatically stable configurations in the excited states, an emerging area that needs attention.

269 e energies of the lowest singlet and triplet excited states, enhancing the yield of triplet-triplet a

270 bles the population of higher-energy doublet excited states, leading to the observed potent photoredu

271 ter chromophores to describe reaction center excited states.

272 te, it is antiaromatic in its lowest paipai* excited states.

273 s keto and enol tautomers, in the ground and excited states.

274 e energies of the lowest singlet and triplet excited states.

275 -blue photoluminescence from charge-transfer excited states.

276 onon relaxation and molecule-like long-lived excited states.

277 eg, cardiac hypertrophy or failure) forms an exciting target for further research.

278 Consequently, mPTPB represents an exciting target for tuberculosis treatment.

279 This Perspective highlights exciting targets within synthetic lethality, (PARP, ATR,

280 A waveguide port is used to excite the array via slot-lines that couple the electrom

281 We employ single-cycle THz pulses to excite the low-frequency rotational motion of water and

282 nd the waveguide evanescent wave was used to excite the Raman signals of the test analytes.

283 Additionally, X-ray-induced luminescence excited the conjugated photosensitizers, resulting in a

284 continuously regulate interface adhesion by exciting the mechanical micro-vibration in the adhesive

285 om the output of the lantern by individually exciting the single-mode MCF cores, and that these patte

286 current lines of research and questions that excite them.

287 ry of DNA and RNA base editors are revealing exciting therapeutic opportunities for these technologie

288 We believe it is an extremely exciting time to be a neuroscientist, as we have an oppo

289 Structural biology is entering an exciting time where many new high-resolution structures

290 As microbiologists we live in exciting times.

291 Therefore, T(4)PE(4)NDI can be selectively excited to form a charge-separated state via ultrafast p

292 microdialysis (MD) thus providing a new and exciting tool in neuroscience and drug discovery.

293 ts disease with up to 90% accuracy and is an exciting tool in our research armory that could allow se

294 These tools provide an exciting translational avenue to merge omics-based drug

295 efficient intersystem crossing to the lowest excited triplet state upon halogenation was a key mechan

296 In bulk polar solution, DMABN forms an excited twisted intramolecular charge-transfer (TICT) st

297 process where a single photon simultaneously excites two or more two-level systems (qubits) in a sing

298 Exciting under tight focusing at the low frequency side

299 tigate the HCN, HNC photofragments in highly excited vibrational states using both frequency and inte

300 two images simultaneously that allows us to excite water with stimulated Raman scattering and hemogl