1 We interpret (
13)C chemical shift variations in terms of
2 We interpret a full year of high-frequency CO measuremen
3 Here
we interpret a nanosecond transient yellow emission band
4 In the southern part of the 2004 rupture,
we interpret a negative-polarity sedimentary reflector a
5 We interpret above chance classification as evidence for
6 , these discoveries profoundly influence how
we interpret and understand diverse experimental and cli
7 We interpreted and rationalized these results in terms o
8 is defined by a characteristic width, which
we interpret as a "noise width," available to be tuned f
9 l cingulum and corpus callosum fibers, which
we interpret as a consequence of bilateral insults (pote
10 late positive component (900-1500 ms), which
we interpret as a Late Positive Complex, related to the
11 ing organ surrounding a central mouth, which
we interpret as a lophophore, and a U-shaped digestive t
12 plitude and the fluid Verdet constant, which
we interpret as a manifestation of the variable detuning
13 reveal an expansive low-velocity zone, which
we interpret as a possible hot zone, linking ascending m
14 y structure extends to ca. 6 km depth, which
we interpret as a shallow plumbing system comprising a f
15 to a channel at the base of the plate, which
we interpret as a sheared zone of ponded partial melts o
16 longevity of the secondary variations, which
we interpret as a signature of surface inhomogeneities o
17 f homology models for the Na(+),K(+)-ATPase,
we interpret as a transfer reaction of pNBTEA from a per
18 gion of chalcogenide GeSe2 thin films, which
we interpret as being a manifestation of creation and an
19 the maintenance of circadian rhythms, which
we interpret as being due to an effect on the phosphatid
20 us with respect to earlier variations, which
we interpret as being indicative of the natural range.
21 arly visible in > or = 75% of the maps, that
we interpret as boundaries of distinct cortical regions.
22 ventral, and medial-lateral coordinates that
we interpret as cell types.
23 mG-complex; one at least first order in AGT,
we interpret as direct lesion binding.
24 metimes detect a sudden colossal jump, which
we interpret as due to mirror buckling.
25 ty by laser-accelerated particle beams which
we interpret as due to secondary reactions induced by al
26 t and linear in temperature and power, which
we interpret as due to thermoelectricity of the metal el
27 s exhibited a steric occlusion effect, which
we interpret as evidence for restricted access to its gp
28 e zones associated with the new craters that
we interpret as evidence of a surface-bound jetting proc
29 ns that are deeply incised into bedrock that
we interpret as giant plunge pools.
30 eservation of only the pes claw traces, that
we interpret as having been left by walking, not buoyant
31 ake rate (k'R) and vary greatly in kp, which
we interpret as having similar oxygen transport, but mor
32 after all Neoproterozoic glaciations, which
we interpret as incomplete reduction of Se oxyanions.
33 of leg fat mass (r = 0.68, P < 0.05), which
we interpret as increased efficiency of uptake.
34 s running along each of these fibrils, which
we interpret as ladders of metal ions.
35 ics and therapies for CVD, we highlight what
we interpret as major gaps in the medical management of
36 f) rate of heme from IsdC (<10 s(-1)), which
we interpret as necessary so heme loaded IsdC has time t
37 ons off the southern Juan de Fuca ridge that
we interpret as originating from a molten sill at presen
38 ble radio emission from a thermal TDF, which
we interpret as originating from a newly launched jet.
39 ons of dusty clouds in Saturn's rings, which
we interpret as resulting from impacts onto the rings th
40 gp41 domains, i.e. the trimeric state, which
we interpret as small differences in the gp120 structure
41 ed giants with depressed dipole modes, which
we interpret as stars with strongly magnetized cores.
42 e discovery of ASASSN-15lh (SN 2015L), which
we interpret as the most luminous supernova yet found.
43 tion mechanism at [Formula: see text], which
we interpret as the onset of homogeneous etch pit nuclea
44 M82 and a period of 62.0 +/- 2.5 days, which
we interpret as the orbital period of the ULX binary.
45 inct GAD67-expressing cell population, which
we interpret as the previously unidentified reticular th
46 gions of temporally varying elevation, which
we interpret as the surface expression of subglacial wat
47 r crust of the basins south of Qilian, which
we interpret as the top of a mechanically strong lower c
48 bound cross-bridges on N-cTnC opening (which
we interpret as transmitted through related changes in c
49 d by an intense signal originating from what
we interpreted as both the iBM and the oBM, showing diff
50 ortex are tuned to two parts of space, which
we interpreted as reflecting attention and working memor
51 d by an intense signal originating from what
we interpreted as the inner Bruch's membrane (iBM) layer
52 s from the northwest Australian tropics that
we interpret,
based on an integrated analysis of meteoro
53 increases, the elastic modulus rises, which
we interpret by alluding to ant crowding and subsequent
54 We interpreted C and Cl isotopes using a numerical react
55 METHODS AND
We interpreted cardiac magnetic resonance imaging in 420
56 Based on these observations
we interpret circadian rhythmicity as an emerging proper
57 Also,
we interpret climatic relocation patterns in terms of as
58 Our current model systems, or the way
we interpret data from them, clearly do not have suffici
59 evelopment and provide novel insights on how
we interpret data of psychiatric genetics, indicating th
60 Using this model,
we interpreted data on the fusion of seven different ves
61 We interpret denaturant kinetic m-values and activation
62 urthermore, based on the derived conditions,
we interpret drop movements on both hydrophilic and hydr
63 We interpret each obstacle as an esker ridge formed from
64 We interpret each PCO(2) increase as a direct response t
65 We interpret future and recent historical trends by usin
66 the principle of hydrophobic spine assembly,
we interpret how kinases are capable of performing a dua
67 rom motions of the protein as a whole, which
we interpret in the context of prior theories of catalys
68 In other words,
we interpret its reciprocity with living cells in chemic
69 Here in this work
we interpret LSPs from a Bohr model based geometric pers
70 Using phase field simulations
we interpret magnetization reversal as a synergistic eff
71 We interpret mathematical theories of existence and nonu
72 This has major implications for how
we interpret mechanistic evidence derived from the expre
73 We interpret multiquons and their transformations in a n
74 We interpret our algorithm as deriving a model for the b
75 We interpret our data to mean that the oligomer acts by
76 We interpret our findings as evidence for the convergenc
77 We interpret our findings as evidence that compensatory
78 We interpret our findings in the context of our homology
79 We interpret our record of oxygen isotope ratios from th
80 Specifically,
we interpret our records to indicate repeated, large-sca
81 We interpret our results as evidence that raising FFA in
82 We interpret our results in terms of fish allocating seq
83 We interpret our results in terms of the known structure
84 We interpret our results in terms of the potential for a
85 We interpret our results through a chordate-wide compari
86 We interpret our results through a strongly interacting
87 We interpret our results to mean that C6PS-induced dimer
88 We interpret our results using structural data, which sh
89 We interpret our results with the aid of DFT calculation
90 Instead,
we interpret our rich-country results within a theory of
91 We interpreted our results considering two hypotheses.
92 How can
we interpret p53's disparate activities and the conseque
93 In addition,
we interpret segmented zones of melt supply beneath the
94 We interpret Sll0254 to be a dual-function enzyme with b
95 We interpreted such fluctuations as topographic Rossby w
96 ibitory (GH298) and excitatory (krasavietz),
we interpret that the normal phenomena of sensory percep
97 We interpret that the westbound flowing current flow acr
98 We interpreted that roots of E. pithyusa significantly p
99 )H COSY and (19)F-(19)F QF-COSY NMR spectra,
we interpret the (1)H and (19)F NMR spectra of the porph
100 We interpret the appearance of the hydroxyl groups in th
101 We interpret the appearance of these structures as indic
102 We interpret the association with later BMI as being pro
103 We interpret the available evidence as suggesting that C
104 Furthermore,
we interpret the band of seismicity above the magma cham
105 rst-principle lattice dynamics calculations,
we interpret the changes in the phonon dispersion as the
106 We interpret the CO2 release, the formation of nanograin
107 table at these depths in a warm damp mantle,
we interpret the conductor to be a partially molten laye
108 We interpret the data using a theoretical framework devi
109 We interpret the data with an alternating access model t
110 We interpret the DBS effects as compensating for a loss
111 ous dopamine for binding to D2/D3 receptors,
we interpret the decreases in binding to reflect dopamin
112 Hence
we interpret the differential elevation of the southern
113 ld model defined on regular random networks,
we interpret the dynamics of the system in this region a
114 We interpret the effect of K532 mutation as indicating t
115 We interpret the effects of DMSO as being derived from i
116 We interpret the ensemble of data to indicate that (i) t
117 We interpret the findings in terms of emerging network m
118 eatures based on their joint statistics, and
we interpret the firing rates of V1 neurons as performin
119 We interpret the fluctuating asymmetry in fras1 mutant s
120 We interpret the found deviation in favor of sons to be
121 We interpret the geochemical and temporal differences be
122 We interpret the high level of nestedness observed in th
123 es of phase transitions in mantle silicates,
we interpret the images and estimate in situ temperature
124 We interpret the immobile fraction as arising from RNAP
125 The results have implications for how
we interpret the impact of global warming on the hydrolo
126 We interpret the initial elastic regime by an increase o
127 We interpret the isotopic fractionation to be related to
128 We interpret the juxtaposition of the null results of DH
129 We interpret the large (13)C coupling as resulting from
130 We interpret the large extension as a transition to the
131 ity that grows with the duration of CCS, and
we interpret the lifetime of CCS as the time for which t
132 We interpret the mantle electrical structure as evidence
133 We interpret the mechanism of growth enhancement to be a
134 We interpret the multiple conformations of NS5 observed
135 We interpret the new results to mean that pause sites ca
136 meta-community and River Continuum Concept,
we interpret the observed taxonomic patterns and accompa
137 enarios, climate, and carbon cycle feedback,
we interpret the Paris Agreement in terms of three clima
138 Using theoretical analyses,
we interpret the phase behaviour of archetypal IDP seque
139 We interpret the phenotype gradient as arising from anal
140 We interpret the presence of CO2 ice as the result of th
141 We interpret the raindrop fossils using experiments in w
142 thems from Paraiso Cave in eastern Amazonia;
we interpret the record as being broadly related to prec
143 We interpret the reduced FEF activity and slower saccadi
144 We interpret the relationship of these findings and our
145 We interpret the relationships between (3)He/(4)He value
146 Overall,
we interpret the remodeling of disordered state ensemble
147 ations than our specific area of interest as
we interpret the results and outcomes.
148 We interpret the results as a manifestation of the great
149 We interpret the results from these experiments in terms
150 We interpret the results in terms of the structural prop
151 Accordingly,
we interpret the ribless neck vertebrae of three-toed sl
152 In this article,
we interpret the same data by a mechanism where CD4(+) T
153 We interpret the series of intermediates preceding hemif
154 We interpret the similarity of tropical SST changes, in
155 We interpret the surface energy from liquid metal measur
156 We interpret the theoretical results in relation to thei
157 We interpreted the binding data within the theoretical f
158 We interpreted the data in relation to transgenerational
159 We interpreted the IR spectra by comparison with density
160 We interpreted the PCs as a mere signal-rich coordinate
161 We interpreted the results with a modified biofilm-condu
162 We interpreted the Thy1 force fields as representations
163 We interpreted their expression time differences by stat
164 d what drove observed evolutionary patterns,
we interpreted them in the context of its population dyn
165 We interpret these anomalies--previously undocumented in
166 We interpret these data as a reflection of tissue-specif
167 We interpret these data as functional evidence for TCR-i
168 We interpret these data as showing that participants fai
169 We interpret these data as strong evidence, consistent w
170 We interpret these data to indicate that neonatal infect
171 We interpret these data to propose that increasing the d
172 We interpret these differences to reflect the abundance
173 We interpret these different effects of barley genotype
174 We interpret these findings as evidence that p38 mitogen
175 We interpret these findings as reflecting the grouping o
176 combination, and in light of previous work,
we interpret these findings as showing that eye movement
177 We interpret these findings in light of "predictive-codi
178 We interpret these findings in terms of two different ki
179 We interpret these findings in the context of the effect
180 We interpret these findings in the context that the dyna
181 We interpret these findings in the framework of biased c
182 We interpret these findings to indicate either that auto
183 We interpret these findings to indicate that both alpha(
184 We interpret these findings to mean that a dynamic relat
185 We interpret these findings using simple scaling argumen
186 We interpret these findings within a novel framework in
187 We interpret these finds as evidence that drugs of abuse
188 We interpret these functional neuroimaging findings to r
189 We interpret these grains as nanometre-sized SiO2 (silic
190 We interpret these inclusions as primary due to their en
191 We interpret these inputs as dendrite-targeting excitati
192 We interpret these isotopic patterns as recording the pr
193 We interpret these lags as indicating that Great Basin c
194 We interpret these latter findings to show the importanc
195 We interpret these materials to have formed under hydrot
196 We interpret these observations as reflecting the freedo
197 d on images obtained by the Curiosity rover,
we interpret these outcrops as evidence for past fluvial
198 data from high-resolution mass spectrometry,
we interpret these products to result from the generatio
199 We interpret these radiocarbon-enriched signals to repre
200 We interpret these records using a model that simulates
201 We interpret these regions as reflecting the formation r
202 Moreover,
we interpret these results and favour the hypothesis tha
203 We interpret these results as an indication that liquid,
204 We interpret these results as evidence supporting the no
205 We interpret these results as indicating a significant g
206 We interpret these results as indicating that the oligou
207 We interpret these results as showing that paralysis ind
208 We interpret these results as signatures of embryonic se
209 We interpret these results as signatures of the Kondo ef
210 (NE) released from the locus coeruleus (LC),
we interpret these results as suggestive that the LC-NE
211 We interpret these results as that visual stimulation re
212 We interpret these results in terms of an evolutionary t
213 We interpret these results in terms of noncanonical orie
214 We interpret these results in terms of response-effect d
215 We interpret these results in the context of previous st
216 We interpret these results in the context of Record and
217 We interpret these results to demonstrate an intrinsic r
218 We interpret these results to explain how BLM is well eq
219 We interpret these results to indicate a role for the OB
220 We interpret these results to indicate that a strong, pe
221 Taken together,
we interpret these results to mean that Gag membrane int
222 Taken together,
we interpret these results to mean that RSV Gag membrane
223 We interpret these results to mean that the amino acids
224 We interpret these results to suggest that whether or no
225 We interpret these results with the aid of a model for t
226 We interpret these seismic structures as a continuing re
227 We interpret these seismic velocity anomalies as indicat
228 We interpret these suspended sediments to have been trap
229 of isolated elements of the overall network,
we interpreted these data using in silico model-based in
230 We interpreted these findings as compatible with a malad
231 Using a phylogenetic approach,
we interpreted these fossil specimens as members of an e
232 ted intracellularly but not in the membrane,
we interpreted these results to suggest that G-1 could a
233 We interpret this absence of pattern in the adult coral
234 We interpret this additional second phase to represent t
235 We interpret this as a global dependency of the rate of
236 We interpret this as a potential cost of arriving early
237 We interpret this as being related to an increase in moi
238 We interpret this as due to enhanced interactions with m
239 We interpret this as evidence for the existence of distr
240 We interpret this as evidence of the reciprocal relation
241 nd affinity differences were not correlated,
we interpret this as evidence that supercoiling occludes
242 iates in the photocycle of both PYP and Bph,
we interpret this as formation of a metastable complex b
243 of analgesic-exposed F1 fathers or mothers,
we interpret this as potentially indicating an analgesic
244 We interpret this as suggestive that charges are free fr
245 We interpret this as the phase variation of the dayside
246 We interpret this behaviour as direct evidence for scree
247 We interpret this behaviour in terms of the properties o
248 We interpret this cold spell to reflect, to our knowledg
249 We interpret this difference in terms of the hydration p
250 We interpret this difference in terms of the protic or a
251 We interpret this dispersion to reflect cooling of the m
252 Based on its distribution,
we interpret this dust to be interplanetary in origin.
253 We interpret this effect within an extended kinetic mode
254 We interpret this emission as cooperative spontaneous re
255 We interpret this evidence to indicate that Compagopisci
256 We interpret this feature as a torsional Alfven wave pro
257 We interpret this fiber motion to be the result of oscil
258 We interpret this finding as the effect of embedding, se
259 We interpret this finding in light of hierarchical predi
260 We interpret this finding to suggest that the CysM activ
261 We interpret this hysteresis phenomenon as support (alth
262 We interpret this in terms of quantum suppression of the
263 We interpret this in-solution chemical information using
264 We interpret this increased time scale as a multiphonon
265 We interpret this motion as conformational dynamics of t
266 Using micromagnetic modelling,
we interpret this nominally full magnetization reversal
267 We interpret this object as a binary system of two black
268 How do
we interpret this observation in light of the well-known
269 We interpret this occurrence as a gravid female and unbo
270 rhood SES as a proxy for health care access,
we interpret this pattern to indicate continued, true in
271 We interpret this reduced risk as a stabilization of the
272 We interpret this result as a decrease in the relative u
273 We interpret this result as arising due to spatial fluct
274 We interpret this result as primarily a remnant of the c
275 ly stable under moderate shear stresses, and
we interpret this result in terms of stress-free shape a
276 We interpret this result to indicate that there remains
277 We interpret this result to mean that both microdialysis
278 We interpret this result to reflect the presence of a pr
279 We interpret this significant improvement with a theory
280 We interpret this to indicate that lakes are present in
281 We interpret this to indicate that stabilization of the
282 We interpret this to mean that the Compound I (peroxidas
283 We interpret this to reflect episodic flow from lower-ma
284 We interpret this to reflect interval-dependent recovery
285 We interpret this to reflect the role of saliency and ex
286 We interpret this trend as signalling our approach to a
287 hat TRAMP facilitates pre-mRNA splicing, and
we interpreted this as a fail-safe mechanism to ensure t
288 We interpreted this difference as the expected differenc
289 We interpreted this effect as adaptation to the emotiona
290 n experiments without a catheter (P < 0.05);
we interpreted this result to be mild cholestasis caused
291 ling of these independent clinical CNV data,
we interpreted three SVs to be of potential clinical sig
292 channel and demonstrate the kinetics of what
we interpret to be intrinsic hERG voltage sensor movemen
293 at a mass per charge (m/q) = 32 to 35, which
we interpret to be S+ and H2S+, with (S+ + H2S+)/(Na+ +
294 ange than the polypeptide in pa-HO-CN, which
we interpret to indicate that pa-HO-N3 is conformational
295 a few hundred thousand years or less, which
we interpret to reflect a change in the global delta(44/
296 ade precise cross-links at Rap1 sites, which
we interpret to reflect native Rap1-TFIID interactions.
297 e L-P complex lacks full processivity, which
we interpret to reflect the lack of the viral nucleocaps
298 tion changes in central East Antarctica that
we interpret to represent rapid discharge from a subglac
299 organization of subcellular structures that
we interpret using fractal dimension (FD).
300 n 572 ClinSeq participants, and in 37 genes,
we interpreted variants that cause high-penetrance cance