ライフサイエンスコーパス: hyperbolic

1 arameters where the steady-state response is hyperbolic.

2 ctric tensor have opposite signs, are called hyperbolic.

3 that the binding/unbinding phase boundary is hyperbolic.

4 turation curve from sigmoidal to essentially hyperbolic.

5 etworks and explore whether this geometry is hyperbolic.

6 rent curve shapes, ranging from sigmoidal to hyperbolic, according to the relative importance of the

7 For hyperbolic agonist concentration-response relationships,

8 We present numerical simulations of hyperbolic analogues of the kagome lattice that show unu

9 with a characteristic intermediate between a hyperbolic and an exponential function was sufficient to

10 and PaO2 can be modelled as a combination of hyperbolic and linear functions.

11 linear spin systems as a transition between hyperbolic and loxodromic classes of Mobius transformati

12 ckground knowledge to quantitatively predict hyperbolic and pragmatic halo effects in number interpre

13 ions in such a way to allow plasticity among hyperbolic and sigmoidal signal-response relationships.

14 atalyzed HsUbc2b/E2(14kb) transthiolation is hyperbolic and yields K(m) values of 102 +/- 13 nm and 1

15 In this study, we designed and synthesized hyperbolic architectured ceramic aerogels with nanolayer

16 DCP-UO22+ species changed from sigmoidal to hyperbolic at high concentrations of protein G.

17 ss infrared-active phonon-polaritons exhibit hyperbolic behaviour for some frequencies, allowing for

18 Both beta-LG and CAS, but not WPI, showed hyperbolic binding isotherms indicating that these prote

19 rrence-bioactivity-effort space produces the hyperbolic black hole of NPs, where IMPs populate the hi

20 wed a specific interaction as indicated by a hyperbolic BRET signal in response to increasing PAR4-GF

21 d In(III) complexes of aminobenzyl-DTPA were hyperbolic, but in each case the apparent affinity of th

22 The hyperbolic circle aims to become a universal space of re

23 t and accurate "coalescent embedding" in the hyperbolic circle even for large networks.

24 hat heparin inhibits HNE by a tight-binding, hyperbolic, competitive mechanism, contrary to previous

25 Native nucleotides show a hyperbolic concentration dependence of the pre-steady-st

26 contrast, binding of MeIm followed a simple hyperbolic concentration dependence.

27 xpected phenomena in both Type I and Type II hyperbolic conditions, with both occurring naturally wit

28 This hyperbolic cooling is particularly efficient, giving pic

29 The hyperbolic cost of this delay not only accounts for kine

30 ive ligand binding, the reference state is a hyperbolic curve for a monomer with a single binding sit

31 Strikingly, EEG results showed an analogous, hyperbolic curve for N1 amplitude, reflecting neural bia

32 au as a function of sample amount, fitting a hyperbolic curve.

33 concentration of free fixed buffers shows a hyperbolic decrease in time at a rate that is not unifor

34 Hirudin-(54-65)(SO(3)(-)) caused a hyperbolic decrease of the inactivation rates, suggestin

35 ary fibrosis do not significantly change the hyperbolic dependence between R(PA) and C(PA), and patie

36 reduction, is established due to an inverse hyperbolic dependence of k(cat)/K(m) on solvent viscosit

37 The hyperbolic dependence of kobs on TDG concentration gives

38 There is a hyperbolic dependence of O(2) yield on catalyst concentr

39 A hyperbolic dependence of the first observable process wi

40 ucleotide incorporation, the analysis of the hyperbolic dependence of the observed first-order rate c

41 ecreases with decreasing [ATP], exhibiting a hyperbolic dependence on [ATP] (K1/2=176(+/-30) microM)

42 The association rates show a hyperbolic dependence on [CO], consistent with Pro-2 dis

43 ve second-order rate constants k1,eff have a hyperbolic dependence on [H+] (k1,eff = a1[H+]/(b1+[H+])

44 me-dependent inactivation of HpGT exhibits a hyperbolic dependence on acivicin concentration with k(m

45 al rate of WRN helicase activity displayed a hyperbolic dependence on ATP-Mg(2+) concentration.

46 quinonoid intermediate formation exhibits a hyperbolic dependence on l-Trp and l-Met concentration.

47 the reduction of NH(2)OH by MV(red), with a hyperbolic dependence on NH(2)OH concentration, and a k(

48 The oxidative process exhibited a hyperbolic dependence on NH(2)OH concentration, with a k

49 n monocation radical (MV(red)), displaying a hyperbolic dependence on NO(2)(-) concentration, with a

50 There was a clear hyperbolic dependence on octanesulfonate binding, indica

51 orescent protein-PLB in AAV-293 cells showed hyperbolic dependence on protein concentration, with a m

52 bserved rate of complex formation exhibits a hyperbolic dependence on sarcosine concentration with a

53 f most other AKRs but displayed the expected hyperbolic dependence on substrate concentration, with n

54 HCS in the cytoplasm, is slow and displays a hyperbolic dependence on substrate concentration.

55 ni), occurs in a second step that exhibits a hyperbolic dependence on substrate concentration.

56 for formation of the 425 nm band exhibits a hyperbolic dependence on succinate concentration, showin

57 The results revealed a hyperbolic dependence on the p-NBA concentration with a

58 ubunits inhibit the activity of spastin in a hyperbolic dependence, characteristic for two interactin

59 anonical intertemporal choice models such as hyperbolic discounting assume that reward amount and tim

60 Further, a quasi-hyperbolic discounting model, a form of hyperbolic disco

61 rmore, we show that, because exponential and hyperbolic discounting models are unable to account for

62 uasi-hyperbolic discounting model, a form of hyperbolic discounting with separate components for shor

63 which fall over time, often referred to as "hyperbolic discounting".

64 rd-which is equivalent to a specific form of hyperbolic discounting.

65 ptions of phenomena such as loss aversion or hyperbolic discounting.

66 One additional mechanism is predictable from hyperbolic discounting: When a person uses willpower to

67 vdW materials, the polaritons can exhibit a hyperbolic dispersion and propagate as nanoscale-confine

68 environments provided by metamaterials with hyperbolic dispersion and simpler metal/dielectric struc

69 ical topological transition from elliptic to hyperbolic dispersion at a wavelength of 4.5 mum.

70 Anisotropic metamaterials with hyperbolic dispersion can be used to design waveguides w

71 vides unique functionalities such as obvious hyperbolic dispersion in the visible and near-infrared r

72 e experimental demonstration of the magnetic hyperbolic dispersion in three-dimensional metamaterials

73 he other hand, similar to photonic crystals, hyperbolic dispersion law of extraordinary photons is mo

74 tural optical materials studied to date, the hyperbolic dispersion originates solely from the electri

75 on periodic metal-dielectric multilayers in hyperbolic dispersion region; however, the influence of

76 Thue-Morse lattice order from elliptical to hyperbolic dispersion regions, compared to the periodic

77 uniaxial optical metamaterial described by a hyperbolic dispersion relation can simultaneously behave

78 he spherical hyperlens is designed with flat hyperbolic dispersion that supports wave propagation wit

79 We verify hyperbolic dispersion with numerical simulations that mo

80 based on Au/TiO2 multilayers and confirm the hyperbolic dispersion, and the presence of high-k modes

81 avelength periodic artificial structure with hyperbolic dispersion, can enhance the spontaneous emiss

82 ptical cavities using indefinite medium with hyperbolic dispersion, which allows propagation of elect

83 has been demonstrated in metamaterials with hyperbolic dispersion--highly anisotropic composite mate

84 al phase transition between the elliptic and hyperbolic dispersion.

85 and Si/Ag nanowire based metamaterials with hyperbolic dispersion.

86 etic modes in anisotropic metamaterials with hyperbolic dispersion.

87 ctions that have a singularity in media with hyperbolic dispersion.

88 The hyperbolic dose response saturated at 20-50 nM with an a

89 It followed a hyperbolic dose response with maximal inhibition of ~50%

90 er planetary orbits, including parabolic and hyperbolic escaping orbits, of the solar system without

91 ivity of unlabeled enzyme varied in a simple hyperbolic fashion, also as seen for human factor X(a).

92 inority A and B components together define a hyperbolic film whose midsurface follows the gyroid mini

93 The hyperbolic fit of the k(obs) vs [DEDAM] plots is interpr

94 e equilibrium and corresponds to an unstable hyperbolic fixed point in the dynamical phase space.

95 minimum uncertainty spin-nematic state to a hyperbolic fixed point of the phase space.

96 ormation versus substrate concentration were hyperbolic for alphaNF epoxidation but highly cooperativ

97 ve shown that the signal-response curves are hyperbolic for the default parameter values.

98 This "hyperbolic" force-velocity relationship has been known s

99 respiring on succinate, ROS generation was a hyperbolic function of [O2].

100 The midpoint potential was a hyperbolic function of increasing NAD+ concentration, su

101 nd other animals discount future reward as a hyperbolic function of time.

102 The interaction mirrored that of a hyperbolic function, with reversal learning performance

103 O2, showing them to be a combined linear and hyperbolic function.

104 ional O(2) extraction increase as linear and hyperbolic functions, respectively, of (.-)V(O(2).

105 derstood as a continuous extension of trees, hyperbolic geometry enables the embedding of complex hie

106 emerge as discrete samples from a continuous hyperbolic geometry enclosed in a circle: the radius rep

107 are maps, a method that harness the power of hyperbolic geometry into the realm of single-cell data a

108 A hyperbolic gradient-index lens design is fabricated and

109 Yet another important property of hyperbolic graphs is their navigability, and it remains

110 y de Sitter spacetimes are as good as random hyperbolic graphs.

111 ization of graphene plasmon polaritons with (hyperbolic) hBN phonon polaritons, this work might have

112 125I-UbR72L undergoes heterodimer-catalyzed hyperbolic HsUbc12 transthiolation and yields Km = 20 +/

113 niporter function, in which Ca(2+) uptake is hyperbolic in the absence of Mg(2+) and sigmoid in the p

114 succinate and carbamoyl phosphate) caused a hyperbolic increase and decrease, respectively, in the f

115 titrated with unlabeled NS3, resulting in a hyperbolic increase in fluorescence anisotropy and provi

116 lglycerol bilayer, PWR measurements showed a hyperbolic increase in the average refractive index and

117 pressure displayed a consistent R(PA)-C(PA) hyperbolic (inverse) dependence, C(PA)=0.564/(0.047+R(PA

118 o linear, up to 500 mM, without changing the hyperbolic K dependence of single-channel conductance.

119 eltaPDZ) and produce an enzyme that displays hyperbolic kinetics and degrades substrate with a maxima

120 Although 4-OT exhibits hyperbolic kinetics and no structural asymmetry either b

121 d substitution far from the active site gave hyperbolic kinetics and required far lower CheYp for hal

122 litatively different shape from the familiar hyperbolic kinetics curves, instead resembling the long-

123 Human AppBp1-Uba3 follows hyperbolic kinetics for HsUbc12 transthiolation with 125

124 s of polyubiquitin chain formation displayed hyperbolic kinetics with respect to UbcH7 concentration

125 5, three Arabidopsis BAMs that all exhibited hyperbolic kinetics, BAM2 exhibited sigmoidal kinetics w

126 K dependence of macroscopic conductance from hyperbolic (Km = 6 +/- 2 mM) to linear, up to 500 mM, wi

127 It has been shown that the hyperbolic Langmuir isotherm captures the shape of the s

128 Hyperbolic law measurements reveal that the higher coerc

129 of the disposition index (DI), based on the hyperbolic law of glucose tolerance, is a powerful predi

130 strain energy T cycle are related through a hyperbolic law v = L/T, where L is a constant step lengt

131 ctric implementation of a transformed planar hyperbolic lens which retains the same focusing properti

132 s at receptors where agonist binding follows hyperbolic (M(4) muscarinic acetylcholine receptors) or

133 first-order rate constants that varied in a hyperbolic manner as a function of UTP concentration.

134 rvative, upwind, finite volume scheme to the hyperbolic mass balance equations and a finite element s

135 es) (rr-P3ATs), a naturally low-loss organic hyperbolic material (OHM) in the visible frequency range

136 The low-loss, mid-infrared, natural hyperbolic material hexagonal boron nitride is an attrac

137 agonal boron nitride, a natural mid-infrared hyperbolic material, can act as a 'hyper-focusing lens'

138 Hexagonal boron nitride (h-BN) is a natural hyperbolic material, in which the dielectric constants a

139 requency range where hBN behaves as a type-I hyperbolic material, we have found graphene-hBN hyper-cr

140 Hyperbolic materials exhibit sub-diffractional, highly d

141 Natural hyperbolic materials exist at visible frequencies; howev

142 potentially surpassing concurrent artificial hyperbolic materials with lower losses and higher optica

143 hBN, one of the latest natural hyperbolic materials, can be a very strong contender to

144 ntire landscape of atom-atom interactions in hyperbolic media confirming the giant long-range enhance

145 es for realizing efficient impedance-matched hyperbolic media for unpolarized light.

146 Hyperbolic media strengthen numerous attractive applicat

147 osite signs are referred to as indefinite or hyperbolic media.

148 aces and the study of many-body physics with hyperbolic media.

149 ty tensors have opposite signs are termed as hyperbolic media.

150 the way for the control of cold atoms above hyperbolic meta-surfaces and the study of many-body phys

151 boron nitride, plasmonic super-lattices and hyperbolic meta-surfaces as well.

152 Unlike conventional ion traps, in which hyperbolic metal electrodes establish equipotential boun

153 f an organic dye placed in a grating coupled hyperbolic metamaterial (GCHMM).

154 Hyperbolic metamaterial (HMM), a sub-wavelength periodic

155 proof of concept experiment with a uniaxial hyperbolic metamaterial at radio-frequencies revealing t

156 Initially, we propose an optical hyperbolic metamaterial based on Au/TiO2 multilayers and

157 noparticles inside the ferrofluid form small hyperbolic metamaterial domains, which from the electrom

158 mmetric subwavelength gratings and a passive hyperbolic metamaterial engineered to display a transmis

159 Here, we demonstrate that an Al/Al2O3 hyperbolic metamaterial geometry is capable of a similar

160 olarized emitter placed at the boundary of a hyperbolic metamaterial is shown to excite extraordinary

161 ss of particle absorbers called transferable hyperbolic metamaterial particles (THMMP) that display s

162 pt results confirm that the proposed virtual hyperbolic metamaterial structure can be used for effici

163 Here we propose a hyperbolic metamaterial structure to realize a highly ef

164 ized plasmonic biosensor platform based on a hyperbolic metamaterial that can support highly confined

165 -down nanostructuring are combined, creating hyperbolic metamaterial-based photonic crystals termed h

166 pologically distinct bulk states in a chiral hyperbolic metamaterial.

167 near-field scanning the surface of a chiral hyperbolic metamaterial.

168 In this paper, we present grating coupled-hyperbolic metamaterials (GC-HMM) as multiband perfect a

169 Hyperbolic metamaterials (HMMs) represent a novel class

170 plasmonic and metamaterial devices including hyperbolic metamaterials (HMMs).

171 thermal emission properties of semiconductor hyperbolic metamaterials (SHMs).

172 Here we introduce and design virtual hyperbolic metamaterials (VHMMs) formed by an array of p

173 ch combines the most interesting features of hyperbolic metamaterials and photonic crystals.

174 Hyperbolic Metamaterials are artificially engineered mat

175 At this time, we show that hyperbolic metamaterials can control spontaneous emissio

176 Second, hyperbolic metamaterials consisting of ultrathin Al-dope

177 Here we propose employing hyperbolic metamaterials for a broadband impedance match

178 While artificial hyperbolic metamaterials have been demonstrated, they su

179 Hyperbolic metamaterials were initially proposed in opti

180 dband photonic density of states provided by hyperbolic metamaterials with the light-scattering effic

181 Similar to hyperbolic metamaterials, photonic hyper-crystals exhibi

182 Hyperbolic metamaterials, which can be realized by alter

183 commonly used in creating visible wavelength hyperbolic metamaterials.

184 characteristics of the strong anisotropy of hyperbolic metamaterials.

185 focusing via dispersion engineering based on hyperbolic metamaterials.

186 erimental realization of a visible-frequency hyperbolic metasurface using single-crystal silver nanos

187 Moreover, hyperbolic metasurfaces exhibit strong, dispersion-depen

188 nsional metamaterials (metasurfaces) such as hyperbolic metasurfaces for propagating surface plasmon

189 passing through metallic components), these hyperbolic metasurfaces have been predicted to suffer mu

190 yer architecture, we demonstrate luminescent hyperbolic metasurfaces, wherein distributed semiconduct

191 xperimental basis, we present evidence for a hyperbolic [MgATP]-velocity relationship of heavy-meromy

192 As the hyperbolic [MgATP]-velocity relationship was not consist

193 free (125)I-polyubiquitin chain assembly by hyperbolic Michaelis-Menten kinetics with respect to Ubc

194 oidal (cooperative) behavior without DNA but hyperbolic (Michaelis-Menten) kinetics in its presence,

195 The compound acts as a hyperbolic mixed modifier in the presence of a synthetic

196 lex, resulting in a change of mechanism from hyperbolic mixed predominately catalytic activation (HMx

197 al differential equations including elliptic-hyperbolic mixed type, free-boundary problems, and corne

198 r IX (Ki 224 +/- 32 nM) was characterized by hyperbolic mixed-type inhibition, indicating that factor

199 leavage product containing the exosite was a hyperbolic mixed-type inhibitor of ADAMTS13 proteolysis

200 epelling manifolds, this allows us to detect hyperbolic mixing zones.

201 infer the network angular coordinates of the hyperbolic model according to a geometrical organization

202 Kinetic analysis showed a first-order hyperbolic model fit for the change in the L( *) value,

203 A one-site binding hyperbolic model indicated that the maximal percent of i

204 A hyperbolic model quantified rates of extinction.

205 and the k coefficient estimated by fitting a hyperbolic model to individual data.

206 that delay-choices were best predicted by a hyperbolic model, with the largest reward devaluations o

207 marine vertebrates are well described by our hyperbolic model.

208 were not well fitted by linear or classical hyperbolic models (respectively), due to the high sensit

209 h searches conformational space via parallel hyperbolic Monte Carlo.

210 This is demonstrated with vertically aligned hyperbolic nanotube (HNT) arrays composed of alternating

211 Specifically we show that an hyperbolic network geometry emerges spontaneously from m

212 lear if de Sitter graphs are as navigable as hyperbolic ones.

213 e along anisotropic metasurfaces with either hyperbolic or elliptical dispersion.

214 aried by microarray platform with some being hyperbolic or linear, and others following a power-law;

215 Hyperbolic, or indefinite, metamaterials are photonic st

216 ttern is uniform, it is known as the pleated hyperbolic paraboloid (hypar) origami.

217 ly graded, random) offsets, is invariantly a hyperbolic paraboloid.

218 ptimal model of exploration in fact produces hyperbolic path lengths, which are well approximated by

219 an example of hierarchical ordering within a hyperbolic pattern, a unique mode of soft-matter self-as

220 where charge carriers in graphene couple to hyperbolic phonon polaritons (17-19) in the encapsulatin

221 Here we report that hyperbolic phonon polaritons allow for a flat slab of he

222 infrared nanoimaging and nanospectroscopy of hyperbolic phonon polaritons are demonstrated in a novel

223 es for hexagonal BN, where the high-momentum hyperbolic phonon polaritons enable efficient near-field

224 surface plasmon polaritons in graphene with hyperbolic phonon polaritons in h-BN, so that the eigenm

225 f surface plasmon polaritons in graphene and hyperbolic phonon polaritons in h-BN.

226 on length 1.5-2.0 times greater than that of hyperbolic phonon polaritons in h-BN.

227 Here we demonstrate that hyperbolic phonon polaritons in hexagonal boron nitride

228 picture for the understanding of the role of hyperbolic phonon polaritons in near-field optical imagi

229 However, control of these hyperbolic phonon polaritons modes has remained challeng

230 Here, a detailed study of hyperbolic phonon polaritons propagating in hexagonal bo

231 multimode waveguides for the propagation of hyperbolic phonon polaritons--collective modes that orig

232 surface scattering in the damping process of hyperbolic phonon polaritons.

233 d, wavelength dependent propagation angle of hyperbolic phonon polaritons.

234 efficient coupling of a plasmonic antenna to hyperbolic phonon-polaritons in hexagonal-BN to highly c

235 lutions of the Navier-Stokes equation on the hyperbolic plane (2) observed by Chan and Czubak is a co

236 cribed by a family of patterns that tile the hyperbolic plane by regular degree-three trees mapped on

237 The hyperbolic plasmon-phonon polaritons in graphene/h-BN su

238 The hyperbolic plasmon-phonon polaritons possess the combine

239 des of the graphene/h-BN heterostructure are hyperbolic plasmon-phonon polaritons.

240 The overall reaction yields hyperbolic plots of rate versus AGT concentration for O6

241 metamaterial-based photonic crystals termed hyperbolic polaritonic crystals, allowing free-space acc

242 In effect, the real-space propagation of hyperbolic polaritons and their spectroscopic resonances

243 ries, we observe edge-oriented and steerable hyperbolic polaritons as well as forbidden zones where t

244 by direct nano-infrared imaging, that these hyperbolic polaritons can be effectively modulated in a

245 The lifetime and figure of merit of the hyperbolic polaritons can be regulated by the edge aspec

246 blish a solid basis for the understanding of hyperbolic polaritons in linear waveguides, which is of

247 in-plane anisotropy, we report edge-tailored hyperbolic polaritons in patterned alpha-MoO(3) nanocavi

248 e we report on three-dimensionally confined 'hyperbolic polaritons' in boron nitride nanocones that s

249 power-asymptote (critical power; CP) of the hyperbolic power-time relationship for high-intensity ex

250 These hyperbolic properties arise from a highly ordered struct

251 quantity of biotin-labeled nucleic acids is hyperbolic rather than linear.

252 potential response are best described by the hyperbolic ratio function when compared with linear, pow

253 er inactivation rate constants (k(app)) were hyperbolic, reflecting saturation of T.GAG complex and f

254 limit set is that of a geometrically finite hyperbolic reflection group in one higher dimension.

255 In the hyperbolic regime, we demonstrate the strong enhancement

256 Speed and time to exhaustion conformed to a hyperbolic relationship (r(2) = 0.92 +/- 0.03) which cor

257 Moreover, the hyperbolic relationship between insulin secretion and be

258 To determine whether the hyperbolic relationship between insulin sensitivity and

259 The hyperbolic relationship between S(i) and AIRg was presen

260 Although a hyperbolic relationship existed between insulin secretio

261 cardiolipin-lacking mitochondria displayed a hyperbolic relationship indicating cytochrome c pool beh

262 e H+ dependence of Cd2+ transport, showing a hyperbolic relationship with a Km of 19.9 nm for H+.

263 ecretion, particularly in the context of the hyperbolic relationship with insulin action, in elderly

264 yper clamp)) demonstrated the characteristic hyperbolic relationship.

265 d mechanism: They are generalizations of the hyperbolic response of Michaelis-Menten kinetics x/(K+x)

266 e native enzyme (Hill coefficient > 2), to a hyperbolic response.

267 owth, thereby confirming previous results on hyperbolic reward discounting, yet without making any pr

268 t their kinematics is also consistent with a hyperbolic, reward-dependent cost of time.

269 radation on reductant concentration followed hyperbolic saturation kinetics, and differences between

270 ete Riemannian manifolds, which includes the hyperbolic setting.

271 that is moderately decreased and a partially hyperbolic shape for the O2 binding curve.

272 rom all samples of a data set by the inverse hyperbolic sine (asinh) transformation.

273 ial locations within a compact subwavelength hyperbolic slab.

274 netically resolvable, as evidenced by single hyperbolic SOS concentration dependences of the inactiva

275 We define conjugate hyperbolic space and entropic momentum co-ordinates to d

276 als that constitute lattices in an effective hyperbolic space with constant negative curvature.

277 ntries acting on the two-dimensional complex hyperbolic space.

278 Random geometric graphs in hyperbolic spaces explain many common structural and dyn

279 nning above critical speed (asymptote of the hyperbolic speed versus time-to-exhaustion relationship

280 h a synthetic fluorogenic substrate produced hyperbolic substrate versus velocity curves, rather than

281 logical theory suggests an important role of hyperbolic surface scattering in the damping process of

282 18 hidden neurons and 5 output neurons using hyperbolic tangent and softmax activation functions in h

283 ry are investigated by applying an empirical hyperbolic tangent function to both observed and downsca

284 First, the hyperbolic tangent function, tanh (x), can be used to de

285 e law is a result of a strong, approximately hyperbolic temperature variation of the reorganization e

286 nd Eu1(Mg), of the same Eu-Mg defect, with a hyperbolic time dependence on 'switchdown' from Eu0 to E

287 icantly altered polymerization kinetics from hyperbolic to a decidedly more sigmoidal behavior.

288 At the transition from hyperbolic to elliptical dispersion (corresponding to a

289 band, yielding a topological transition from hyperbolic to elliptical dispersion.

290 of the mechanical response transitions from hyperbolic to sigmoidal for more rod-like glycocalyx ele

291 rome c and shifts the reaction kinetics from hyperbolic to sigmoidal such that COX is fully or strong

292 binding curves obtained with DCP-UO22+ from hyperbolic to sigmoidal, the latter characterized by Hil

293 e tunable topological transitions from open (hyperbolic) to closed (elliptical) dispersion contours i

294 ng the two major types of vdW materials, the hyperbolic vdW crystals are inherently inadequate for op

295 r effect quenching, resulting in prematurely hyperbolic velocity versus substrate profiles and undere

296 Filament adsorption onto grids was hyperbolic when analyzed as a function of time or bulk p

297 SK concentration for [Glu]Pg and [Lys]Pg was hyperbolic with dissociation constants corresponding to

298 ease in a gradual manner, which becomes more hyperbolic with increasing n.

299 nactivation (K(I)) of hGST P1-1 on [BITC] is hyperbolic, with K(I) = 66 +/- 7 microM.

300 concentration and observed exchange rate is hyperbolic, with the limiting rate being that for global