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1 tes (for example, 30 kelvin with 200 oersted per second).
2 ain rate (-105.9+/-6.1% versus -109.0+/-3.8% per second).
3 rahigh-speed imaging (more than 10(5) frames per second).
4  expanding at high speeds (>10(4) kilometres per second).
5 number of electrons transferred from MV(red) per second).
6 elocities (up to several hundred centimeters per second).
7 ocity of approximately 2.0 to 2.7 kilometers per second).
8 gradient-echo images (approximately 5 frames per second).
9 another near the sound speed (200 kilometers per second).
10  a flow of ocean water of 10(6) cubic meters per second).
11 h them at supersonic velocities (~400 meters per second).
12 ems in rapid streams of pseudofonts (6 items per second).
13 asurement of elongation speed (5 amino acids per second).
14 y ( less, similar10 (12) square centimenters per second).
15 yottaNOPS values (1024 Nucleotide Operations Per Second).
16 to 10 mL/min and frame rates of 4 fps (frame per second).
17  corneal irradiances (7-14 log photons/cm(2) per second).
18 10 kilobases at a velocity of 60 base pairs per second.
19 ange of tempi, but not at tempi below 1 note per second.
20 graphy of moving objects at up to 75 volumes per second.
21 n the impact velocity exceeds 2.5 kilometres per second.
22 abilities with velocities of > 30 nanometers per second.
23  quasar-like luminosity of 1.5 x 10(46) ergs per second.
24 cells, visualizing cell nuclei at 10 volumes per second.
25 copy at the repetition rate of million scans per second.
26 n impact velocity greater than 10 kilometres per second.
27 ptimal cutoff value for HMR was 2.5 mm Hg/cm per second.
28 ypical main belt collisions at ~5 kilometers per second.
29 igh-speed laryngoscopy yielding 4,000 images per second.
30  be 6.5 (+/-0.8) x 10(-12) cubic centimeters per second.
31 g a typical grain velocity of ~18 kilometers per second.
32  kiloelectronvolt range of 4.9 x 10(39) ergs per second.
33 erse waves with amplitudes of ~20 kilometers per second.
34  with velocities of about 100,000 kilometres per second.
35 ling acquisition rates of up to 10(7) frames per second.
36 tosis events in 3D at a rate of seven stacks per second.
37 th an unprecedented frame rate of >25 frames per second.
38 s for macroscopic steel sheets at 600 meters per second.
39  and an absolute rate of 850 chloride anions per second.
40 velocity dispersion of 317 +/- 30 kilometres per second.
41  time-evolving events at up to 10(11) frames per second.
42 ize dendritic membrane potentials many times per second.
43 ial at velocities exceeding 1,000 kilometres per second.
44 gas has a velocity of up to 1,000 kilometres per second.
45 energy band range from 10(39) to 10(41) ergs per second.
46  kiloelectronvolt range of 1.8 x 10(40) ergs per second.
47 pixel dynamic scenes at a speed of 10 frames per second.
48 ndom digital data at a rate of 12.7 gigabits per second.
49 ocessing rate of approximately 170,000 cells per second.
50  gigapascals (GPa) and strain rates of 10(9) per second.
51 s to rates in excess of 1,500 volumes imaged per second.
52 les above an X-ray luminosity of 10(44) ergs per second.
53  at a rate of 46 three-dimensional data sets per second.
54 t their gaze to a new location several times per second.
55 bstrate-borne vibrations at about six pulses per second.
56 er degree and 98% contrast reversing 2 times per second.
57 providing analysis rates greater than 50,000 per second.
58 rm saccadic eye movements two to three times per second.
59  nanospheres at an imaging rate of 10 frames per second.
60 elium, at phase-locked rates up to 96 pulses per second.
61 uency of approximately 10(8) flipping events per second.
62 ient throughput to analyse 500,000 particles per second.
63 ate the solar wind to hundreds of kilometres per second.
64 nted continuously, in real time, at 3 images per second.
65 essels and screen them at rates of thousands per second.
66  to 0.1 moles of CO converted per mole of Au per second.
67 plets at a rate of greater than 350 droplets per second.
68  would yield reading speeds of tens of bases per second.
69 pe effects predict a value in excess of 1400 per second.
70  with an average blue shift of 23 kilometers per second.
71  an effective processing rate >160,000 cells per second.
72  is achieved at greater than 1 mass spectrum per second.
73 period derivative of 3.614 x 10(-13) seconds per second.
74 nd turnover numbers on the order of hundreds per second.
75  of the solar wind to hundreds of kilometers per second.
76  with lower average speeds of 200 kilometers per second.
77 ts of information per spike rather than bits per second.
78 ng modulated data at rates up to 10 gigabits per second.
79 esicle membrane at a rate >10,000 per trimer per second.
80 , with an aggregate data rate of 50 gigabits per second.
81 decision making pathways up to several times per second.
82 roduces some thousands of antibody molecules per second.
83  parametric resonance and images at 5 frames per second.
84  and an elongation rate of 13-18 amino acids per second.
85 d; the other flared five times to 10(40) erg per second.
86  of carrying spores at speeds of centimeters per second.
87 s of the flares were greater than 10(39) erg per second.
88 p to 60 kelvin at a sweep rate of 22 oersted per second.
89 re two to four words are typically processed per second.
90 ay luminosities in excess of 3 x 10(39) ergs per second.
91 e detection thresholds at 160 and 640 pulses per second.
92 to a throughput of approximately 1,000 cells per second.
93 attern (200 Hz in 100 ms trains, five trains per second, 100 micros, 7 mA) and was compared with sham
94 pact velocities ranging from 26 to 97 meters per second (2-13.5 J).
95 ented in alternation at a rate of six images per second (6 Hz; 3 Hz identity repetition rate) for a 2
96 of objects at a rapid fixed rate (six images per second: 6 Hz), with faces interleaved as every fifth
97 eves a detection throughput of 2000 droplets per second, a detection limit of 20 nM, and an excellent
98 agnetic field sweep rate of about 20 oersted per second, although higher temperatures have been achie
99 ron liquid is found to be ~0.1 square meters per second, an order of magnitude higher than that of ho
100 y as high as 1.3 square centimetres per volt per second and a high on/off current ratio exceeding a m
101 AB can translocate along DNA at up to 250 bp per second and can unwind an average of 14,000 bp, with
102 ith an average speed of 0.3 to 0.6 kilometer per second and caused high peaks in the photospheric mag
103  IOP, ECG, and body temperature measurements per second and compensates for barometric pressure in re
104 velocity offsets of less than 600 kilometres per second and linear offsets of less than 100 kiloparse
105 ity dispersion peak exceeding 100 kilometres per second and modest rotation.
106 with a turnover of 2 phospholipid molecules per second and per OmpLA dimer until most of the membran
107 .3 mum, speeds up to nearly 200 image planes per second and the ability to noninvasively acquire hund
108  of solid nanowires at a scale of attolitres per second and the process can be directly imaged with i
109 seen, with phase speeds of 1 to 4 megameters per second and trajectories consistent with the directio
110 e pore at median rates of 2.5-40 nucleotides per second and were examined at one nucleotide spatial p
111  Alfven speed ( approximately 800 kilometers per second) and another near the sound speed (200 kilome
112 40 sverdrups (Sv) (1 Sv = 10(6) cubic meters per second), and it occurs mainly in subtropical regions
113 maximum contraction velocity (MCV; in pixels per second), and latency of MCV (LMCV; in seconds).
114 (NLS), macroscopic transport rates (hundreds per second), and single cargo transit times (millisecond
115 m per second) or severe (able to walk <0.4 m per second)--and randomly assigned them to one of three
116 .2 motifs, at a rate of about 15 nucleotides per second, and "dwells" at a motif site for 2.7 s while
117 esponding to a light velocity of 1600 meters per second, and a transparency of 40% that increases to
118 ased image acquisition at 175 million voxels per second, and computational modules for high-throughpu
119 nts from 5% to 50%, a ramp-strain rate of 2% per second, and relaxation periods of 2.5 min.
120 n air under the cloud base at ~11,000 images per second, and the differences in characteristics of op
121  vena cava (temporal resolution, five images per second; and spatial resolution, 150-mm field of view
122 ith |v(LSR)| greater, similar 170 kilometers per second are at larger distances.
123 ger terminal arbors but only where more bits per second are needed for a specific purpose.
124 t outflow speeds of a few hundred kilometres per second are observed; these are below the escape spee
125                Thus approximately 10(6) ions per second are required for a minimal detection.
126 ving particles (V approximately a few meters per second) are aligned along the symmetry axes of the l
127           Median SWS measurements (in meters per second), as well as change in median SWS (median SWS
128  as high as 1.12 square centimetres per volt per second at 100 per cent strain along the direction pe
129 e constant of k(app) = 1.1 x 10(7) per molar per second at 4 degrees C.
130  and CO formation turnover frequency of 0.28 per second at a low overpotential of 54 millivolts.
131 usion reactions at rates of only a few atoms per second at most and must be studied immediately follo
132  as high as 4050 square centimeters per volt per second at room temperature.
133 hoton count rates exceeding 7 x 10(6) counts per second at saturation, after correcting for uncorrela
134 ce rotation rate, approximately 2 kilometers per second at the equator, predicts an oblateness (equat
135 upernovae that radiate more than 10(44) ergs per second at their peak luminosity have recently been d
136            We imaged samples at one 2D image per second, at resolutions as low as 145 nm laterally an
137 imulus presentation rates of 5 and 10 bursts per second, at which human listeners report robust SSS,
138  burst rates of approximately 100 supercoils per second (average burst size was 6.2 supercoils).
139                   Average number of saccades per second, average saccade amplitude and average search
140 ith velocities higher than 10,000 kilometres per second, believed to originate in relativistic (that
141 formation rate of cognitive control (in bits per second, bps) in the model fitting to estimate the ca
142  from relative speeds of less than 10 meters per second by comparing two optical atomic clocks connec
143  ventricle with MR tracking (13 to 15 frames per second) by both transseptal and retrograde aortic ap
144 uminosities of up to a few times 10(40) ergs per second can be explained by supercritical accretion o
145 t a megaflood (greater than 220 cubic meters per second) carved the canyon about 45,000 years ago.
146 ith an acquisition rate of 333 Raman spectra per second, chemical information was obtained separately
147 ty is in the range of hundreds of nanometers per second, comparable to the transport velocities of bi
148 s >0.5% at flow rates of several microlitres per second, compatible with typical microfluidic applica
149 activity at the tumor injection site [counts per second (cps) averaged over 10 seconds] ranged from 3
150 izes mode coupling, we achieved 400-gigabits-per-second data transmission using four angular momentum
151 ve detection sensitivity (i.e., Delta(counts per second)/Delta(particle concentration)).
152 d with a Doppler velocity of ~700 kilometers per second, direct evidence of large-scale asymmetry in
153          The eyes move rapidly several times per second, displacing the retinal image each time.
154 the enzyme hydrolyzes 35 +/- 4 ATP molecules per second during ssDNA translocation.
155     We present an all-plasmonic 116-gigabits per second electro-optical modulator in which all the el
156 eroids at velocities exceeding 10 kilometers per second, enough to heat and degas target rock.
157  rate of the polymers is several micrometers per second, ensuring that a polymer fiber reaches the wa
158 neously, generating 10-100 action potentials per second even without synaptic input.
159 ance (more than 1 square centimetre per volt per second) even after a hundred cycles at 100 per cent
160 y flow midexpiratory phase (FEF25-75; liters per second), FEF25-75 (% predicted), and a categorical o
161 ide (ITO) substrate can generate >micrometre per second fluid convection.
162 d theoretical studies predict only nanometre per second fluid velocities that are inadequate for micr
163 to achieve sensitivities up to 80,000 counts per second for a 1 ng/L (133)Cs solution, providing a de
164       This translates to 35 processed frames per second for a 640 pxx352 px video of 4 whiskers.
165 egrees C) of 157 electrons (78 molecules H2) per second for CpI and 25 electrons (12 molecules H2) pe
166 d for CpI and 25 electrons (12 molecules H2) per second for CrHydA1.
167              Reference ranges in centimeters per second for mean angle-corrected V(MCA) on the left a
168 ack laser scanning ( approximately 40 frames per second) for targeting two lasers (a 473-nm blue lase
169 tion proved to be most beneficial (60 pulses per second, for 20 s every minute), whereas continuous s
170 current speed of imaging is up to 100 frames per second (fps) over a volume about 0.8 x 1 x 0.5 mm(3)
171 d reduced exposure times at a fast 50 frames-per-second (FPS) capable of resolving mouse cardiac cycl
172 a record high-speed entry of 28.6 kilometers per second from an orbit close to that of Jupiter-family
173 ale jets with speeds of 80 to 250 kilometers per second from the narrow bright network lanes of this
174  rate of sporozoites (approximately 1 to 2.5 per second) from the mosquito proboscis.
175 sequence a speed of 136 billion cell updates per second (GCUPS) was achieved on a dual Intel Xeon E5-
176  ICC neurons with limiting rates >500 pulses per second had CFs <1.5 kHz, whereas neurons with lower
177 ximal framing rates of 250 to 100,000 images per second has allowed new views of musculoskeletal func
178 bance readout at rates of up to 300 droplets per second (i.e., >1 million droplets per hour).
179  are swapped between the eyes multiple times per second; (iii) the dominance duration as a function o
180 ic diffusivity of 2.4 x 10(-2) square meters per second implies a major role for water circulation in
181           These oscillations, 2.6 kilometers per second in amplitude, are coupled with chromospheric
182  values of >1000 square centimeters per volt per second in field-effect transistors with microwave-re
183 ng at rates of up to 32 reconstructed images per second in fixed and living cells.
184 bout where to look approximately three times per second in normal viewing.
185 system capable of imaging at up to 25 frames per second in real-time display mode.
186 away from each origin at approximately 88 bp per second in synchronous culture.
187  which correspond to ca. 4600 Brownian jumps per second in the solid state at 300 K.
188  propelled at speeds of 50 to 150 kilometers per second into the corona.
189 flow's kinetic power larger than 10(46) ergs per second is enough to provide the feedback required by
190  and optic nerve head at 249,000 axial scans per second is possible.
191  a 1% increase in aortic arch PWV (in meters per second) is related to a 0.3% increase in subsequent
192 raveling with a velocity of ~1200 kilometers per second, it is the fastest unbound star in our Galaxy
193 ork, were of the order of hundreds of meters per second, less than what has been observed in our expe
194 PED enables scanning of thousands of volumes-per-second, limited only by camera acquisition rate, thr
195 of absolute river discharge (in cubic meters per second) may be derived solely from satellite images,
196 etabolic demand but higher-frequency PDs (>2 per second) may be inadequately compensated without an a
197  frequency domain (measured in Hz, or cycles per second) may capture different cardiac phenomena at d
198 to demonstrate passive and active (30 frames per second) modulation of a 64-view backlight, producing
199 rve highly dilatant and slow [~4 micrometers per second (mum/s)] aseismic slip associated with a 20-f
200 eir fast transport rates of up to 1,500 ions per second, Na(+)/H(+) antiporters operate by a two-doma
201 is-Menten constant (Km) of PR (10(3) photons per second/nm2), and show that light-driven pumping by P
202       The Fermi velocity of 4 x 10(5) meters per second obtained from these transport experiments agr
203  upstream, and approximately 10 cubic meters per second of seepage emanates from its vertical headwal
204 synthesis by the rotation at about 100 times per second of the central stalk and an attached ring of
205 ompressive image reconstruction at 10 frames per second of two-dimensional (range and angle) sparse s
206 ions are collected at a rate of one fraction per second on a high-density microarray to retain the se
207 tes, and carry out 6.4 x 10(18) instructions per second on general-purpose computers.
208  measurements put a lower limit of k >/= 210 per second on the rate constant for bound substrate oxid
209 irment--moderate (able to walk 0.4 to <0.8 m per second) or severe (able to walk <0.4 m per second)--
210 nes, which are broader than 1,000 kilometres per second, originate in dense shock waves powered by ho
211 ith at least 10(26) molecules being produced per second, originating from localized sources that seem
212  we measure a decoherence rate of 8 x 10(-5) per second over 100 milliseconds, which is the time requ
213 oward the Kathmandu basin at ~3.3 kilometers per second over ~140 kilometers.
214 and a reduced number of pinch/release cycles per second (P < 0.05).
215 wton-meters quadricep strength at 90 degrees per second; P = .04 and .01, respectively) and among CNS
216 train rate (153.8+/-8.9% versus 191.4+/-8.9% per second; P<0.05) and peak rate of left ventricular un
217 4+/-8.0 degrees versus -129.4+/-12.8 degrees per second; P<0.05).
218 r second versus no MVI, 2.41+/-1.26 mm Hg/cm per second; P=0.03).
219 rfusion reserve >/=2.0, 2.24+/-1.19 mm Hg/cm per second; P=0.04).
220 sts show sensitivities of up to 18000 counts per second/parts per billion and volume (cps/ppbv) at a
221 aled luminance using just 1 synaptic vesicle per second per distinguishable gray level.
222         Rates were determined in nucleotides per second per molecule of polymerase (nt/s) and were li
223 ate a flux of about 10 norfloxacin molecules per second per OmpF trimer in the presence of a 1 mM con
224 relative photon signal (0.56 x 10(7) photons per second per square millimeter +/- 0.11 P < .001) of r
225 relative photon signal (0.56 x 10(7) photons per second per square millimeter +/- 0.11.
226  imaging photon signal (0.57 x 10(7) photons per second per square millimeter +/- 0.15, P < .001) of
227  imaging photon signal (0.57 x 10(7) photons per second per square millimeter +/- 0.15, P < .001) of
228 dimeglumine administered at a rate of 2.0 mL per second) performed with a 3.0-T imager with a dedicat
229  was best for pulse rates near 80-160 pulses per second (pps) and degraded for both lower and higher
230 be driven to hundreds of thousands of cycles per second promising applications in magneto-electro-opt
231 acked using low TFs of one to four reversals per second (r/s) and a spatial frequency (SF) of 0.24 cy
232 ic DBS delivering the same number of stimuli per second (rate-control 6.2 or 1.8 Hz, respectively) an
233 t high velocities-up to about 600 kilometres per second-relative to the galaxy disk.
234 9 meter, average velocity 0.20 to 0.75 meter per second) required to transport the pebbles.
235  elongation rates of 220% and (3.7 x 10(4))% per second, respectively, at operating temperatures from
236 re approximately 0.1, 1, and 3.5 nucleotides per second, respectively.
237 plete yeast cell cycle at one 3D image stack per second reveals an unexpected degree of photosensitiv
238  source, with turnover frequencies of 33,000 per second (s(-1)) in dry acetonitrile and 106,000 s(-1)
239 cular ultrasound (IVUS) imaging at 72 frames per second safely in vivo, i.e., visualizing a 72 mm-lon
240 ted rapid (>10,000 phospholipids per protein per second) scrambling of phospholipid probes.
241 roxide were decomposed by a single bacterium per second, signifying the presence of a highly active c
242  steady-state creep rate of less than 10(-6) per second-six to eight orders of magnitude lower than m
243 apped particles by only about 1-2 kilometres per second, so rotation has been thought inconsequential
244 ger fixation durations at 5 than at 3 frames per second (specialists: beta = .01; 95% CI: .004, .026;
245 oint mass is GM = 666.2 +/- 0.2 cubic metres per second squared, giving a mass M = (9,982 +/- 3) x 10
246 lt plane at an average speed of 8 kilometers per second, suggesting efficient seismic energy generati
247  star at projected speeds of 4-10 kilometres per second, suggesting highly eccentric or unbound traje
248 ID therefore offers more tandem mass spectra per second than conventional methods of collisional acti
249 alanced synaptic currents evoke fewer spikes per second than excitatory inputs alone or equal excitat
250 ume almost an order of magnitude less energy per second than spike trains.
251 flow of millions of ions across the membrane per second that is readily measured as a change in curre
252 zed by unexpectedly fast flow (up to 1 metre per second) that we attribute to high capillary pressure
253 -pixel-by-240-pixel video input at 30 frames per second, the chip consumes 63 milliwatts.
254   With frame rates exceeding a million scans per second, the firehose of data generated by the time s
255  once to a peak luminosity of 9 x 10(40) erg per second; the other flared five times to 10(40) erg pe
256 man blood cell lineages at millions of cells per second throughout life.
257 at a metallic glass at rates of 10(6) kelvin per second to temperatures spanning the undercooled liqu
258 , which can give kicks up to 4000 kilometers per second to the merged black hole.
259 IOCT) capable of imaging at up to 10 volumes per second to visualize human microsurgery.
260 ates at high speed ( approximately 50 frames per second) to provide high spatial resolution ( approxi
261  as they move inward at about 300 kilometres per second towards the active supermassive black hole, w
262 ve luminosities of more than 3 x 10(39) ergs per second, unusually soft X-ray components (with a typi
263 des at a single wavelength, and 1.6 terabits per second using two OAM modes over 10 wavelengths.
264 ity of translocation on ssDNA in nucleotides per second (V(trans)).
265  the velocity of DNA unwinding in base pairs per second (V(un)) by the velocity of translocation on s
266 obe delivery ( approximately 1,000,000 cells per second), versatile across cell types and can be read
267 perfusion reserve <2.0, 3.18+/-1.42 mm Hg/cm per second versus myocardial perfusion reserve >/=2.0, 2
268 ients without MVI (MVI, 3.33+/-1.50 mm Hg/cm per second versus no MVI, 2.41+/-1.26 mm Hg/cm per secon
269 nchronized high-speed (124 or 210 kiloframes per second) video images and wideband electromagnetic fi
270                An imaging speed of 16 frames per second was determined to be adequate to suppress mot
271  operating at a speed of 249,000 axial scans per second was developed.
272       The median firing rate of 4.1 impulses per second was slightly higher than predicted from consi
273 e estimated source strength (>/=0.6 kilogram per second) was comparable to that of the massive hydroc
274                           SSP SWV (in meters per second) was prospectively assessed twice in 22 asymp
275 l droplets at rates of up to 10,000 droplets per second, we demonstrate that flow cytometry permits p
276 l acquisition rates of more than two spectra per second were demonstrated.
277                   Nuclear images (two frames per second) were acquired simultaneously with fluoroscop
278 es C is about 2.78 molecules per Pd1 O4 site per second when 2.0 wt % CuO is used as a co-catalyst wi
279 90 </= |v(LSR)| less, similar 170 kilometers per second (where v(LSR) is the velocity in the local st
280  times the speed of light (71,000 kilometres per second), where the absorption is strongly anti-corre
281 nous end of the range (more than 10(40) ergs per second), which require black hole masses of 50-100 t
282 hesize and secrete thousands of Ig molecules per second, which are folded and assembled in the endopl
283 lly greater than several tens of centimetres per second, which corresponds to the gravitational escap
284 rate in the range of about 10(8)-10(9) grams per second, which is far too small to deplete the atmosp
285 es of nanoliters to approximately picoliters per second, which is ideal for nanopipettors.
286 d with a peak sliding velocity of 1.1 meters per second, which propagated toward the Kathmandu basin
287 sclerotic human coronary artery at 16 frames per second, which showed strong correlation to gold-stan
288 a sequence of images at either 3 or 5 frames per second while EMs were recorded.
289 g mode still provides up to five ECD spectra per second while operating in an information-dependent a
290 king of blood samples at 15-20 million cells per second while yielding an output of highly purified C
291 -tags at flow rates of hundreds of particles per second, while maintaining the spectral resolution re
292 ecovery of up to 91.3% at over 300,000 cells per second with >3% cell loss.
293 ormance gains by annotating ~85,000 variants per second with 50 attributes from 17 commonly used geno
294    In vivo images were acquired at 12 frames per second with 50-microm working distance and 2.5-micro
295 bsorptometry, up to a scan rate of few volts per second with a satisfactory single-scan signal-to-noi
296 that produces transverse images at 10 frames per second with an in-plane resolution of approximately
297 le-molecule data collected at 200,000 frames per second with unprecedented signal-to-noise.
298  using 40-MHz ultrasonography at 8000 frames per second (with electrocardiographic gating).
299  corresponding to almost a billion electrons per second, with an experimentally demonstrated current
300 eveals an elongation rate of ~10 amino acids per second, with initiation occurring stochastically eve

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