ライフサイエンスコーパス: solve

1 ved problems that their account will have to solve.

2 PV6 in the closed state have previously been solved.

3 y (ScaA) and adaptor (ScaB) scaffoldins were solved.

4 ls, but this "inverse problem" is not easily solved.

5 process to address problems that need to be solved.

6 red in the kalihinol class are explained and solved.

7 for Sm2Ru3Ge5 as a representative) have been solved.

8 s were characterized and their structure was solved.

9 C, or genome-wide Hi-C, and FISH is far from solved.

10 soluble and membrane-inserted structures are solved.

11 llenge problem in imperfect-information game solving.

12 ovides nature-inspired solutions for problem solving.

13 nted strategies which were effective in task solving.

14 tested in large-scale benchmark datasets and solved 36% more targets compared to using the best threa

15 prediction both on epitope data derived from solved 3D structures, and on a large collection of linea

16 tocompatibility complexes (pMHCs), they must solve a classic trade-off between speed and sensitivity.

17 ork is programmed using "neural compiler" to solve a differential system emulation task.

18 design and execute scientific experiments to solve a difficult problem in genetics.

19 l maximum or minimum of a given function) to solve a Higgs-signal-versus-background machine learning

20 hetic routes to many important molecules and solve a long-standing challenge in chemistry.

21 he first use of this method in Drosophila to solve a long-standing issue in patterning of the embryon

22 Here we solve a major problem in understanding this dual functio

23 tion procedure (PSAP)] that required rats to solve a new puzzle every day to gain access to cocaine,

24 The system is also used to experimentally solve a second-order nonlinear task, and can successfull

25 We pose and solve a statistical mechanical model of gas adsorption i

26 cts and their mimics to create, explore, and solve a variety of problems in chemistry and biology wil

27 We solved a 3.2 A cryo-electron microscopy structure of the

28 We also solved a 7.4 A structure of the S-layer through electron

29 Additionally, we solved a crystal structure for the apo form of AgmNAT wi

30 It solves a few challenging open statistical questions, clo

31 Rh-hydride catalysis solves a synthetic challenge by affording the enantiosel

32 nd provides a conceptually new algorithm for solving a fundamental computational problem.

33 s quartz glass nanopillars to anchor islets, solving a long-standing problem of keeping tissue-scale

34 te our approach is scalable and effective by solving a set of classification tasks based on a hand-wr

35 r contacts in a random chain, by numerically solving a set of matrix equations.

36 erating functions formalism, we analytically solve all the models in the limit of infinitely large ne

37 f each SubPc-TCBD-aniline conjugate has been solved, allowing to unambiguously assign the atropisomer

38 er to grow into a target shape by posing and solving an elastic energy minimization problem.

39 orresponding system of kinetics equations is solved analytically to obtain concise expressions for is

40 ghlighting new opportunities, problems to be solved and technological advances.

41 hat aims to improve symptoms through problem solving and by changing thoughts and behaviors; noncases

42 improved performance in the creative problem solving and daily routine planning tasks performed after

43 g hind and forecasting, and enabling problem solving and management.

44 hy controls had better reasoning and problem solving and working memory than females, but these gende

45 especially focusing on reasoning and problem solving, and social cognition in schizophrenia patients.

46 RBANS does not include reasoning and problem solving, and social cognition.

47 l ability involved in complex, novel problem solving, and strongly related to working memory and exec

48 e oligonucleotide d[AAATTT]2 with compound 1 solved at 1.25 A (PDB-ID: 5LIT) shows that the drug cove

49 in, geneticin (G418), gentamicin, and TC007, solved at 3.3- to 3.7-A resolution, reveal multiple amin

50 little is known about how these interact to solve basic survival problems.

51 Here we attempt to solve both problems simultaneously, by translating a giv

52 resentative structures that are difficult to solve by conventional MS/MS approaches.

53 re of the S. cerevisiae Pol II-Rad26 complex solved by cryo-electron microscopy.

54 l subunit and the complete Mtb 70S ribosome, solved by cryo-electron microscopy.

55 the deposited RNA structures in the PDB were solved by NMR methods, the usefulness of NMR is still li

56 The structure, solved by solution NMR and EPR spectroscopy in membrane-

57 The A. tumefaciens VirB/VirD4 OMCC, solved by transmission electron microscopy, adopts a cag

58 is a challenge in mass spectrometry which is solved by two-dimensional (2D) Fourier transform ion cyc

59 ases), followed by inherited mutations (6/63 solved cases) and de novo CNVs (4/63 solved cases).

60 dividuals was de novo point mutations (53/63 solved cases), followed by inherited mutations (6/63 sol

61 s (6/63 solved cases) and de novo CNVs (4/63 solved cases).

62 likely evolved in our ancestors to simplify solving certain challenges-including social ones.

63 We solved co-crystal structures of both VRK1 and VRK2 bound

64 de rationalization of the mode of binding by solving co-crystal structures of selected inhibitors in

65 enes is an important biological strategy for solving cocktail-party-like problems in nonhuman animal

66 o from differences in how animals and humans solve cognitive problems.

67 Solving combinatorial optimization problems is challengi

68 Humans have clear limits in their ability to solve complex reasoning problems.

69 inked to task complexity, and the process of solving complex problems in a sequence of simpler, more

70 ions and chemical components is essential to solving contemporary problems in modern biology, especia

71 Moreover, the recently solved crystal structure of AMPK has shed light both int

72 to remember most things, think clearly, and solve day-to-day problems (ie, normal cognition).

73 crystal structure of full-length PSMalpha3, solved de novo at 1.45 angstrom resolution, revealed a d

74 The subcomponents of social problem-solving did not influence depression.

75 ver, experimental methods have difficulty in solving disordered PPIs and existing protein-protein and

76 Participants were randomized to a problem-solving education (PSE) intervention (n = 111) or usual

77 ures of shorter constructs of NEMO have been solved, efforts to elucidate the full-length structure o

78 -Sham scheme of density functional theory to solve electronic structure problems in a wide variety of

79 ype and protecting the genetic material, are solved elegantly in biological systems by the encapsulat

80 of classical computational methods have made solving even few-atom electronic-structure problems inte

81 ed by a change in motivation towards problem-solving, expressed in reduced neophobia and increased ex

82 The algorithm presented here rapidly solves fairly large problems of this type, and provides

83 ite-difference method on a staggered grid to solve for the acoustic eigenmodes (field and frequency)

84 We solve for the halo-free sample transmission function by

85 dynamics with a swarm-based string method to solve for the minimum free-energy gating pathways of the

86 into cells has remained the major problem to solve for widespread development of RNA therapeutics, bu

87 High-resolution structures have been solved for an allosterically inhibited and agonist-bound

88 )2-(s1tbe)4-(tBu)2-COOtBu, the longest to be solved for any linear peptoid, revealed a PPI helix of g

89 Unanticipated conformations solved for complexes with competitive antagonists and a

90 hy, the structure of these domains was first solved for the human Filamin B.

91 A numerical method of solving for the elastic wave eigenmodes in acoustic wave

92 or, and many types of animals appear to have solved foraging problems using a shared set of mechanism

93 li in complex with RNAP and from T. maritima solved free in solution.

94 being a universal quantum computer that can solve general classes of hard problems.

95 est spatial scales and has potential to help solve globally important social and ecological challenge

96 position of the toxin domain onto previously solved GTP.EF-Tu.aa-tRNA structures reveals potential st

97 e, and appraisal support) and social problem-solving (i.e., positive and negative problem orientation

98 e of the important issues and problems to be solved if these efforts are to be successful.

99 plying all subsequent tasks are more rapidly solved in 2D.

100 rge-scale collection of related ligand pairs solved in complex with the same protein partner: we find

101 structures for glutamate receptors have been solved in complexes with agonists, antagonists, alloster

102 iscusses current limitations that need to be solved in future developments.

103 conserved residues, using crystal structures solved in the absence of tRNA as a guide.

104 t problem has not been formulated, much less solved, in a consistent and reliable way.

105 ponents of social support and social problem-solving increase the likelihood of depression in outpati

106 nt Social Network Survey, the Social Problem-Solving Inventory Revised-Short, and the Center for Epid

107 ignificance of their contribution to problem solving is debated within the field of biology.

108 ystem uses approximate Bayesian inference to solve it.

109 re domain of RVFV NSs (residues 83-248), and solved its crystal structure, a novel all-helical fold o

110 We have solved its structure in complex with the C-terminal pept

111 ch manipulation is simulated and analysed by solving Laplace's equation, and the deformation of the m

112 yCom can be rapidly converged by iteratively solving linear programming (LP) problem and the number o

113 engineers, physicists, and mathematicians to solve long-standing questions about the way in which rep

114 onstruct three-dimensional (3D) lattices for solving macromolecular structures.

115 ns confirmed our hypothesis, indicating that solving magnetic field inhomogeneity may become a powerf

116 pproaches offer exceptional opportunities to solve major outstanding problems in the study of how soc

117 ight specific examples where these materials solve multiple issues related to complex sensing environ

118 for local network alignment, specifically to solve network querying problems.

119 ion for the proton operators are derived and solved numerically in combination with the phenomenologi

120 The equations were solved numerically, and the solutions are similar to tho

121 Five cryogenic X-ray structures were solved of the monomeric protease with allosteric inhibit

122 However, problem-solving often involves considering a hierarchy of sub-de

123 erian-Lagrangian model where hemodynamics is solved on a fixed Eulerian grid, while platelets are tra

124 nt success, there are still many problems to solve, on the way to the manufacturing of biomedical dev

125 s, such as social support and social problem-solving, on depression.

126 hich works in two phases: The first phase is solved optimally, and for the second we propose several

127 Besides solving optimization problems, polariton graphs can simu

128 rcuit motifs and generalize the framework to solve other categorization tasks.

129 Although exciting progress has been made to solve parts of the above issues, a versatile solution is

130 nation and understanding, rather than merely solving pattern recognition problems; (2) ground learnin

131 is often trivial and may even be viewed as a solved problem.

132 We solve problems by applying previously learned rules.

133 hted contributions can be chosen to not only solve problems of optimization and inference but also to

134 wer of spectroelectrochemistry techniques to solve problems of the current world, this device is used

135 nd support the use of physical aggression to solve problems.

136 echanisms for innovation and optimization to solving problems in chemistry and engineering.

137 lel between biology and human engineering in solving problems in fundamentally similar ways.

138 e imagination, scientists get their kicks by solving puzzles that advance biomedical research.

139 based on entangled photons are essential for solving questions in fundamental physics and are at the

140 near program, and demonstrate that it can be solved quickly in practice.

141 rts where 7.1-11% of the molecular diagnosis solved rate was attributed to CNVs.

142 nto free- and bound-associated equations and solving resulted inverse problem by using evolutionary s

143 new multidimensional chemical approaches to solve RNA structures.

144 MBV (Match BAM to VCF); a method to quickly solve sample mislabeling and detect cross-sample contami

145 DURA-Z coating effectively solves several key challenges preventing the current ant

146 nowire transistors are being investigated to solve short channel effects in future CMOS technology.

147 llow-up data found no differences in problem-solving skills across groups.

148 irment than females on reasoning and problem solving, social cognition, processing speed, working mem

149 r strengths can be reconfigured as needed to solve specific problems and to anneal the system at room

150 rnating least-squares algorithm (NMF-ALS) to solve spectral overlaps.

151 an alpha-helix as observed in the previously solved structure of the GCGR transmembrane domain.

152 ination, we used cryo-electron microscopy to solve structures of Drosophila Dicer-2 alone and in comp

153 n internal loops, and compare the results to solved structures and to RAGTOP results without special

154 Here, we have solved structures of human DNA polymerase beta (hPolbeta

155 ng novel electron cryomicroscopy methods, we solved structures of microtubule-attached, dimeric kines

156 The solved structures of Neisseria BamD and BamE share overa

157 Na(+) as the most likely ion present in the solved structures, and pulsed electron nuclear double re

158 mportant source of structural restraints for solving structures of oligomeric transmembrane domains (

159 siveness/carelessness, and avoidance problem-solving styles).

160 best predicted both exploration and problem-solving success.

161 To solve such a problem, we developed a new method called O

162 With our initial goal to solve synthetic problems toward 5-phenyl-2,2'-bipyridine

163 ation and cognitive performance on a problem-solving task in a large sample of captive orang-utans (P

164 ty and understanding of the physical problem-solving task.

165 HIT'nDRIVE aims to solve the "random walk facility location" (RWFL) problem

166 John was first to use X-ray diffraction to solve the 3-dimensional structure of a protein, sperm-wh

167 The different approaches used to solve the asymmetric task may reflect distinct cognitive

168 the tissue-scale behaviour challenges us to solve the corresponding mechanical problem at the scale

169 We solve the crystal structure of the LZ:CM2 complex, revea

170 Here we solve the crystal structures of the N-terminal domains o

171 telomerase, which adds telomeric repeats to solve the end replication problem, and RTEL1, which dism

172 that people use two different strategies to solve the explore-exploit dilemma: directed exploration,

173 xt] The resulting algorithms can efficiently solve the Fokker-Planck equation with strongly non-Gauss

174 Yet mechanisms that solve the free-rider problem-critical for sustaining coo

175 report free-flight mosquito wing kinematics, solve the full Navier-Stokes equations using computation

176 digital holography and spatial filtering can solve the inverse problem for free-flowing aerosol parti

177 nctional via examples, bypassing the need to solve the Kohn-Sham equations.

178 ly model the transition probabilities and to solve the label-imbalance problem, we novelly incorporat

179 gh natural selection, can serve as guides to solve the limitations of materials and engineering techn

180 the structure and function of A6 in order to solve the long-standing mystery of poxvirus membrane bio

181 scirpaceus) can use magnetic declination to solve the longitude problem at least under some circumst

182 -3 predicted the number of moves required to solve the most difficult planning problems in children a

183 arning was necessary for the participants to solve the new social version of the task, and that infor

184 othing optimization technique is proposed to solve the non-smooth problem.

185 icient optimization algorithm is designed to solve the objective function.

186 while the I-TASSER-MR server is designed to solve the phase problem for proteins that lack close hom

187 k structure study provides a great chance to solve the problem.

188 We exactly solve the properties of this asymmetric percolation on r

189 ophic growth as an autocatalytic process and solve the resulting time-dependent resource allocation p

190 Here, we use NMR experimental constraints to solve the structure of a type-2 diabetes related human i

191 We solve the structure of one of these conformers by cryo e

192 We also solve the structure of this complex by negative stain el

193 Instead, we derive and solve the systems of ordinary differential equations for

194 ge-Kutta and Newmark methods, is proposed to solve the temporal auxiliary differential equations (ADE

195 with quantum mechanical (QM) calculations to solve the transition state structure of human MAT2A.

196 stable 5-LOX protein, which had been used to solve the X-ray crystallographic structure of 5-LOX, and

197 We solved the 2.7 A crystal structure of the CYP3A4-MDZ com

198 Using cryo-electron microscopy, we solved the atomic structure of an apex bnAb, PGT145, in

199 n insight into inhibition of MPO by SPIN, we solved the cocrystal structure of SPIN bound to a recomb

200 We also solved the crystal structure of full-length KGA and pres

201 o understand the physical basis for this, we solved the crystal structure of JFH-1 NS3, revealing a n

202 To define that interaction, we solved the crystal structure of RBBP4 in complex with an

203 We solved the crystal structure of the 6-HB formed by MT-WQ

204 We solved the crystal structure of the complex between an o

205 Recently, we have solved the crystal structure of the phosphatase domain o

206 We solved the crystal structure of UbV.7.2 and rationalized

207 We solved the crystal structures of the AIPL1-FKBP domain a

208 We then solved the crystal structures of the wild-type mIDH2 and

209 We show that evolution solved the enzyme's key kinetic obstacle-how to maintain

210 sured residue-residue distances, we recently solved the first atomic model for Bax oligomeric pores a

211 Recently, we solved the functional structure of AID and demonstrated

212 Here we solved the high-resolution structure of DISC1 C-terminal

213 By enantioselective HPLC, we solved the racemic mixture and ascertained that the two

214 To overcome heterogeneity, we solved the structure of P405M-HlyIIC, a mutant that excl

215 We solved the structure of the MPE8 antibody bound to RSV F

216 f electron cryo-microscopy (cryoEM), we have solved the structure of the Pyrococcus furiosus archaell

217 moving balls over long distances, observers solved the task more efficiently, using the ball positio

218 Control tests showed that they solved the task using learned information and not olfact

219 Here, we have solved the X-ray crystal structure of an EBNA1 DNA-bindi

220 We solved the X-ray crystal structure of one site VIII mAb,

221 We solved the X-ray structure of a cyclic immunogen in comp

222 Additionally, we have solved the X-ray structure of the drug-resistant catalyt

223 efficient graph-based method that casts and solves the constant-column biclustering problem as a max

224 e formation of an insoluble Cu(II) gel which solves the critical challenge of applying Glaser couplin

225 rence of two major types of human aggression solves the execution paradox, concerned with the hypothe

226 Here, we describe an algorithm that solves the high error rate problem by combining long, hi

227 This mechanism solves the inherent cross-diffusion issue of redox ECs a

228 Easi-CRISPR solves the major problem of animal genome engineering, n

229 o all members of an otherwise diverse family solves the problem of how a master regulator can control

230 nductor electrode in a PEC is created, which solves the Schrodinger, Poisson and drift-diffusion equa

231 ng features in the two retinal images (i.e., solving the "stereoscopic correspondence problem") so th

232 ctivation provides an alternate approach for solving the age-old challenge of introducing an alpha-me

233 Here by solving the analytical steady-state distribution of the

234 thermal phonon transport in superlattices by solving the Boltzmann transport equation and using the B

235 Unexpectedly, solving the crystal structure of Tda2 revealed it belong

236 Solving the crystal structure of the DEKK Fc region at a

237 By solving the crystal structure of the IL-1alpha/aptamer,

238 By solving the crystal structures of Btk inhibitors bound t

239 s a functional pair due to their utility for solving the difficult protein folding problem.

240 Solving the Fokker-Planck equation for high-dimensional

241 icient statistically accurate algorithms for solving the Fokker-Planck equations associated with high

242 dopsins with altered spectral properties, by solving the high-resolution channelrhodopsin crystal str

243 By solving the IMP over different numbers of source nodes,

244 By solving the inverse problem, we can obtain the required

245 odynamics are then quantified by numerically solving the Navier-Stokes equations in the moving wall d

246 s one of the most common techniques used for solving the phase problem in X-ray crystal diffraction.

247 ed coarse graining to RNA-ligand systems and solving the process in a pseudo-first order approximatio

248 ccurred for stimuli that were irrelevant for solving the task.

249 e applied to any other focusing optics, thus solving the X-ray optical problem at synchrotron radiati

250 Here, ITC experiments performed to solve these discrepancies now show that the region conta

251 To solve these problems, efforts have been made to combine

252 Efforts to solve this challenge have generated a range of innovativ

253 To solve this conundrum, we used Forster resonance energy t

254 search for new strategies and approaches to solve this emergent problem?

255 sms that subtend the manner in which animals solve this exploitation-exploration dilemma are still po

256 We solve this geometric inverse problem of determining the

257 We solve this inverse problem by providing a numerical meth

258 present SpartaABC, a web server that aims to solve this issue.

259 ours of metals are reported that effectively solve this long-time dilemma.

260 To solve this problem and also to increase circulation time

261 Here we solve this problem by considering the scaling exponent o

262 We solve this problem by proposing an evolving caveman netw

263 stments based on measuring confidence do not solve this problem reliably.

264 One way to solve this problem would be to expand the donor pool to

265 To solve this problem, for the first time, we produced gene

266 To solve this problem, numerous methods of countermeasure h

267 To help solve this problem, researchers are investigating novel

268 To solve this problem, we designed and fabricated titanium

269 To solve this problem, we propose a method based on matrix-

270 y network topology information attempting to solve this problem.

271 We solved this challenge with 1,4-bicyclo[2.2.2]octane dica

272 t the Time Point Selection (TPS) method that solves this combinatorial problem in a principled and pr

273 the hypothesis that the human visual system solves this problem by automatically identifying the nav

274 photon targeted patch-clamp recording, which solves this problem by making use of a closed loop visua

275 covered that the fruit fly olfactory circuit solves this problem with a variant of a computer science

276 ent a reaction kinetics-based technique that solves this problem, significantly increasing the dynami

277 el and easy-to-use computational method that solves this problem.

278 ed on cell-penetrating poly(disulfide)s that solves this problem: we deliver about 70 QDs per cell, a

279 the role that marine reserves might play in solving this challenging and ubiquitous problem in ecosy

280 l)-l-tyrosine ((18)F-FET) may be helpful for solving this diagnostic problem.

281 colleagues describe a promising step toward solving this problem by identifying and describing a rad

282 An urgent, critical first step in solving this problem is replacing the Journal Impact Fac

283 c and theoretical problems can eventually be solved through newly designed synthesis strategies (e.g.

284 unately, EM, in its base form, requires long solve times to complete and often leads to unstable kine

285 tuberculosis Rv3802 X-ray crystal structure, solved to 1.7 A resolution.

286 The structure of BiFae1A was solved to 1.98A resolution, and two tetramers were obser

287 The crystal structure of the EBD dimer was solved to 2.2 A resolution.

288 The X-ray crystal structure of NosK, solved to 2.3 A resolution, reveals that the protein is

289 in the catalytic domain of plant CesAs, was solved to 2.4 A resolution.

290 on protein only if the protein structure is solved to atomic resolution.

291 y problems, each of which can be effectively solved to enhance the assembly of structurally altered r

292 cently, dozens of virus structures have been solved to resolutions between 2.5 and 5.0 A by means of

293 upled micromagnetic simulation framework and solved TSPs of size 26-city and 15-city with an accuracy

294 dal classification of human aggression helps solve two important puzzles.

295 ion in Vanadium Dioxide (VO2) to efficiently solve vertex coloring of graphs.

296 Components of social problem-solving were not related to depression.

297 especially when groups are large, but may be solved when individuals who have more to gain from the c

298 he results and calculate the statistics, are solved with a double-linked tree.

299 ering problem, which can then be efficiently solved with linear time and space complexity.

300 These problems were anticipated to be solved with the advent of fully biodegradable devices.