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1 parenchyma to increase in attenuation during expiration).
2 n alveolar size from peak inspiration to end expiration).
3 ation-based lung deformation (inspiration vs expiration).
4 ity of spinal respiratory neurons engaged in expiration.
5 is tracheal diameter from inspiration to end-expiration.
6 asured in units of 0.1 cm following a normal expiration.
7 quired data in normal inspiration and normal expiration.
8 urface tension to avoid lung collapse at end-expiration.
9 ith bicuculline and strychnine led to active expiration.
10 ivated, e.g., during exercise, drives active expiration.
11 ral CO2-chemoreception and for gating active expiration.
12 internal and external, are activated during expiration.
13 RG) as the site for the generation of active expiration.
14 lus coincided with late-inspiration or early-expiration.
15 firing is correlated with late-phase active expiration.
16 breathing frequency, inspiration, and active expiration.
17 ated less frequently during inspiration than expiration.
18 lacement was smaller during inspiration than expiration.
19 tary breathing as controlled inspiration and expiration.
20 respiratory neural activity generated during expiration.
21 control the abdominal activity during active expiration.
22 piration followed by a prominent rise during expiration.
23 the conditional pF(L) oscillator for active expiration.
24 h, which is done immediately after a maximum expiration.
25 rred only when stimuli were delivered during expiration.
26 ension and prevents alveolar collapse at end expiration.
27 eement by facilitating identification of end-expiration.
28 at least, a portion of their activity during expiration.
29 ases during inspiration and decreases during expiration.
30 the alveolus, maintaining lung volume at end expiration.
31 l ventilation and completely collapse at end expiration.
32 Measurements were recorded at end-expiration.
33 e alveoli collapse totally (type III) at end expiration.
34 ratory onset (3) mid-inspiration and (4) mid-expiration.
35 entially during post-inspiration and stage 2 expiration.
36 were performed either during inspiration or expiration.
37 alveolar pressure is near zero at the end of expiration.
38 alveolar pressure that exists at the end of expiration.
39 ratory events, with little attention paid to expiration.
40 : inspiration, glottic narrowing, and forced expiration.
41 whereas it did not change significantly with expiration.
42 ume (baseline), deep inspiration, and forced expiration.
43 bursts during both inspiration and the early expiration.
44 abdominal expiratory activity during active expiration.
45 ed hypoxia - conditions that generate active expiration.
46 arafacial region (pFRG), which drives active expiration.
47 and receiving excitatory inputs during late expiration.
48 the highest correlation with coefficient on expiration.
49 ormed with the use of mean density values on expiration.
50 atelet products are frequently wasted due to expiration.
51 lectromechanical coupling during spontaneous expiration.
52 ation by preventing alveolar collapse at end expiration.
53 The diaphragm is an important regulator of expiration.
54 ratory muscle and is assumed to relax during expiration.
55 ing an inhibitory synaptic volley relayed by expiration.
56 ement for an increased shunt fraction during expiration.
57 teral parafacial region (pFL) driving active expiration.
58 e., cessation of both inspiration and active expiration.
59 ith a greater percentage of large alveoli at expiration.
60 anipulated the frequency of inspirations and expirations.
61 E velocity was similar after inspiration and expiration (0.81 +/- 0.24 and 0.84 +/- 0.21 m/s, respect
62 on, 0.8+/-0.3 versus 1.5+/-0.7 [p < 0.0001]; expiration, 1.0+/-0.3 vs. 1.9+/-0.7 [p < 0.0001]) and de
63 ced expiratory volume in the first second of expiration, 2.2 percent predicted [95% CI, 0.1% to 4.3%]
64 The average percentage of stenosis at end expiration (21% +/- 16) was significantly higher than th
65 Estimated PL was 1.5 +/- 6.3 cm H2O at end-expiration, 21.4 +/- 9.3 cm H2O at end-inflation, and 18
66 inspiration, 198+/-53 ms versus 137+/-32 ms; expiration, 225+/-43 ms vs. 161+/-33 ms [p < 0.0001]).
67 wed that maximum MSNA always occurred at end expiration (25% to 30% of total activity) and minimum ac
68 frame area) at inspiration (39.9%-42.2%) and expiration (35.9%-38.7%) similar to that in the control
69 r occupancy at inspiration (46.7%-47.9%) and expiration (40.2%-46.6%) similar to that in the control
72 iration (25%) and from 6.4 to 3.8 L (41%) at expiration after surgery and correlated well with measur
74 and regional transpulmonary pressures at end-expiration along the ventral-dorsal gradient, as well as
75 tion Pes averaged 17.5 +/- 5.7 cm H2O at end-expiration and 21.2 +/- 7.7 cm H2O at end-inflation and
76 en alveolar area at peak inspiration and end expiration and assessed as a percentage change (I-E Delt
78 t differences (p > 0.05, t-test) between end-expiration and end-inspiration measurements of the cardi
80 The 3D-pressure profile of the EGJ at end-expiration and forced inspiration revealed marked differ
81 S promote the transition from inspiration to expiration and function as part of the 'Inspiratory Off
82 nstability and a tendency to collapse during expiration and increased work of breathing necessitating
83 gular oscillations corresponding to rhythmic expiration and inspiration are modulated by slow periodi
85 from 3D motion tracking, such as the depth, expiration and inspiration distribution, correlated (p <
88 ne group of motoneurones is activated during expiration and only one of the pathways has been detecte
90 hibiting neurons that are most active during expiration and provide a framework for respiratory sinus
91 iratory inhibition during the first stage of expiration and receiving excitatory inputs during late e
94 tical metabolic conditions to provide forced expiration and reduced upper airway resistance simultane
95 tidal ventilation but remained patent at end expiration and those that totally collapsed and reexpand
97 ced expiratory volume in the first second of expiration and/or the peak expiratory flow rate, which c
99 acity plus 1 L), CT (at full inspiration and expiration), and spirometry or plethysmography were perf
100 he expiratory phase (the terminal 10-100% of expiration), and two different TGI catheter flow rates w
102 ti-detector row CT: end inspiration, dynamic expiration, and end expiration (the latter was performed
104 tiple aspects of breathing, including active expiration, and maintain breathing automaticity during n
105 na cava in end inspiration compared with end expiration, and the opposite trend was shown in the supe
106 tilation but did not totally collapse at end expiration; and type III alveoli (n = 12) demonstrated a
107 ntilation but do not totally collapse at end expiration; and type III, alveoli visibly change size du
111 oblique at 45 degrees or 30 degrees angle on expiration as well as 45 degrees and 39 degrees projecti
113 Depolarizing pFL neurons produced active expiration at rest, but not when inspiratory activity wa
114 were analyzed during apnea, inspiration and expiration, at atrial paced heart rates of 60, 80, 100 a
115 ype II in that they totally collapsed at end expiration (atelectasis) and reinflated during inspirati
117 spulmonary pressure in caudal regions at end-expiration (best-positive end-expiratory pressure).
118 n, BMI [r = 0.37], WC [r = 0.43], P < .0001; expiration, BMI [r = 0.24], WC [r = 0.26], P < .0001).
119 on, BMI [r = 0.57], WC [r = 0.62] P < .0001; expiration, BMI [r = 0.58], WC [r = 0.64], P < .0001) an
123 r than 0.794 help airways remain open during expiration by increasing both viscous pressure drop and
126 Images were registered from inspiration to expiration by using an elastic registration algorithm.
127 ntuation of celiac artery compression at end expiration can give rise to a potential pitfall of breat
128 namic lung compliance during inspiration and expiration cannot be modeled accurately with conventiona
131 and approximately 6% in PAH patients during expiration compared to inspiration, while the wave speed
132 , followed by a significant narrowing at end-expiration compared with the peak CSA during that expira
133 only RTN neuron stimulation produces active expiration, consistent with their role as central respir
134 of behaviors and reflex responses, including expiration, coughing, sneezing, vomiting, postural contr
135 ation compared with the peak CSA during that expiration (CSA: breath-3, 79 +/- 3% to 62 +/- 6%; breat
136 ecreased attenuation of the lung parenchyma; expiration CT scans were scored for extent of air trappi
137 getable oils according to conservation state expiration date employing near infrared (NIR) spectrosco
138 sibility to extend the storability after the expiration date, for a possible recovery of bioactive co
139 f bisphenol A in all of these food, based on expiration date, the amount of glucose and sodium chlori
141 d different levels of plasminolysis at their expiration dates, as revealed by alphas2-CN (f1-25) 4P a
144 ous, and 3) the amount of atelectasis at end-expiration decreased from 24% to 16% during spontaneous
146 ntraction of abdominal muscles at the end of expiration during metabolic challenges (such as hypercap
148 a conditional oscillator that drives active expiration during periods of high respiratory demand, an
149 irst time, that the generation of controlled expiration during the post-inspiratory phase engages a d
150 d the diaphragmatic electric activity during expiration, dynamic computed tomographic scans, and resp
151 measured at peak inspiration (I) and at end expiration (E) by image analysis and I minus E was calcu
152 was measured at peak inspiration (I) and end expiration (E) on individual subpleural alveoli by image
153 The ratio of the mean lung density at end expiration (E) to end inspiration (I) was calculated in
154 ns between respiratory phases: (1) from late expiration (E2) to inspiration (I), (2) from I to post-i
157 ia and project to the pFRG region; b) active expiration elicited by hypoxia was blunted after blockad
159 ng the amount of sinus arrhythmia related to expiration (expiration-triggered sinus arrhythmia [ETA])
160 s content at end-inspiration (F(EI)) and end-expiration (F(EE)) using the formula sVol = (F(EI) - F(E
161 ced expiratory volume in the first second of expiration (FEV(1)) of at least 50% predicted, and negat
164 efficiency, declining innovation, key patent expirations, fierce price competition from generics, hig
166 r separation was also acquired at the end of expiration for PET attenuation correction purposes.
167 ed efficiency, stagnant success rate, patent expirations for key drugs, fierce price competition from
169 elds were subsequently applied to the end-of-expiration frame of the acquired 4D MRI volume and the A
170 ional Vts were calculated by subtracting end-expiration from end-inspiration volumes in total lung, n
171 n infants the rate of emptying during forced expiration from near total lung capacity to residual vol
172 rst-order surrogates for infected human lung expirations from patients with pulmonary tuberculosis.
173 correlated in fractional atelectatic mass in expiration greater than or equal to 40% and 20-40% group
174 ruitment with fractional atelectatic mass in expiration greater than or equal to 40% was less than 7%
175 uring expiration, and especially during late expiration, HFPOs prolonged expiratory time (TE) and ton
176 constant airflow during both inspiration and expiration, highlighting a design optimized for efficien
177 Increase in tonic scalene activity at end-expiration, however, was equivalent during crescendo and
178 hted 4D MR images were registered to the end-expiration image using a nonrigid B-spline registration
180 ns were obtained at full inspiration and end expiration in 21 pediatric lung transplant recipients wi
182 harges were present for both inspiration and expiration in both external and internal intercostal ner
183 ppler ultrasonography during inspiration and expiration in both the supine and upright positions.
184 and closing during chewing, and inspiration-expiration in breathing, which must be labile in frequen
186 riable and inconsistent phasic activation in expiration in one or more of the PCs was present in seve
187 rease during inspiration and decrease during expiration in the presence of a variable shunt fraction,
189 ight lung volumes at end inspiration and end expiration increased substantially after operation in pe
190 %], P<.001 versus end-tidal volume), whereas expiration increased the cardiac volume included (median
192 ricular systolic area during inspiration and expiration is a reliable catheterization criterion for d
194 clude that in anesthetized adult rats active expiration is driven by the pFL but requires an addition
196 ro-posterior oblique projection performed on expiration is recommended for diagnostics and interpreta
197 e such that for a 45 degrees oblique view on expiration is recommended for radiographic imaging of pa
198 in both patient and animal studies in which expiration is terminated before derecruitment of lung un
199 n of the transitions between inspiration and expiration is the timing of the inspiratory off-switch (
200 tion (%LAA-950insp) and less than -910 HU at expiration (%LAA-910exp) obtained with single univariate
201 to produce a technically satisfactory forced expiration lasting 0.5 second, only 46 (58%) could produ
202 g 0.5 second, only 46 (58%) could produce an expiration lasting 1 second, with the youngest children
205 rrow range of breathing amplitude around end-expiration level with 35% of the counts in a 7-min acqui
207 ate rhythm generators, one generating active expiration located close to the facial nucleus in the re
209 d to the transitions between inspiration and expiration may vary, and abnormal respiratory mechanics
210 ated that the rate of emptying during forced expiration measured by both parameters was greatest in t
211 obtained during suspended respiration at end expiration (n = 50) or at end inspiration (n = 50), and
213 nt region and fractional atelectatic mass in expiration negatively correlated with PaO2/FIO2 ratio (r
214 with the normal chest wall condition, at end-expiration non aerated lung tissue weight was increased
215 l expiratory pattern formation during active expiration observed during hypercapnia or after the expo
216 alveolar homogeneity between inspiration and expiration occurred with higher PEEP (16-24 cm H2O) (P >
217 ced expiratory volume in the first second of expiration of 0.6 L [0.2 L], and mean [SD] Paco2 while b
218 raphy (CT) scans acquired at inspiration and expiration of 194 individuals with COPD from the COPDGen
220 ly estimated at peak inspiration and at peak expiration of each gasp by transesophageal methods.
223 ts had at least mild artery narrowing at end expiration, of whom 40 (73%) had less narrowing at end i
226 ith dynamic expiration versus 30.9% with end expiration (P < .0001); and bronchus intermedius, 57.5%
227 ynamic heterogeneity between inspiration and expiration (P < .01 for both) with a greater percentage
229 with 22.9% and 26.3% volume increase at end expiration (P = .001) and end inspiration (P = .002), re
231 ith dynamic expiration versus 35.7% with end expiration (P = .0046); carina, 53.6% with dynamic expir
232 partial pressure of oxygen during end-tidal expiration (P(ET)o(2)) was kept between 50 and 60 mmHg,
233 lapse; (3) airway dilatation occurred during expiration, particularly early in the phase; and (4) mag
234 ced expiratory volume in the first second of expiration (percent of predicted) over time differed bet
237 ssure exerts its effects keeping open at end-expiration previously collapsed areas of the lung; conse
242 : tidal volume 250 mL; FIO2 0.5; inspiration/expiration ratio 1:3; respiratory rate 25 breaths/min; p
243 raphe nuclei, and nucleus retroambiguus (the expiration region of the caudal ventral respiratory grou
244 the concept that it is not only involved in expiration-related activities but also in species specif
245 In contrast, individual MUs typically showed expiration-related decreases in firing as exercise inten
247 ced expiratory volume in the first second of expiration (RR, 1.90; 95% CI, 1.26-2.85; P = .002; I(2)
250 reathing (e.g., frequency, amplitude, active expiration, sighing) and differ in their ability to prod
251 ught that inhibition between inspiration and expiration simply prevents activity in the antagonistic
252 cross-sectional area during inspiration and expiration, smaller increases in airway area during insp
253 number of lung units that close during each expiration so that they are not forced to rerecruit duri
254 way performance often record some measure of expiration, such as FEV1 (Forced Expiratory Volume in 1s
255 pressure-time area during inspiration versus expiration (systolic area index) was used as a measureme
256 .2 +/- 4.7 cm H2O) and the time constant for expiration (tau = CL/Gu) decreased (2.67 +/- 0.62 to 2.3
257 iaphragms at their zone of apposition at end-expiration (Tdi,ee) and peak-inspiration (Tdi,ei) with u
258 athetic bursts occurred more commonly during expiration than inspiration at low tilt angles, but occu
260 thod to facilitate the identification of end-expiration that can significantly improve interobserver
261 end inspiration, dynamic expiration, and end expiration (the latter was performed only at the levels
263 ince flow progressively decreases throughout expiration, the reduction in dynamic hyperinflation resu
264 ly one direction during both inspiration and expiration through most of the tubular gas-exchanging br
265 should be considered for samplers with short expiration times and labile analytes; (5) two study-spec
266 how how selective control of inspiration and expiration times can be achieved in a new representation
268 he difference in the respiratory change from expiration to inspiration (%E) between pulsed Doppler mi
271 ocity and D-VTI significantly decreased from expiration to inspiration; 2) the %E in PV-D velocity (2
272 e that some motor tasks are performed during expiration to take advantage of changes in intrathoracic
273 s of 30, 40, and 55 Gy were delivered during expiration to the atrioventricular junction (n=5) and le
275 t of sinus arrhythmia related to expiration (expiration-triggered sinus arrhythmia [ETA]) from short-
276 ed inspiratory activity and initiated active expiration, ultimately progressing to apnea, i.e., cessa
279 in frequency resulted from a prolongation of expiration (up to 276%), which gradually returned to bas
280 rs were measured at peak inspiration and end expiration using digital image analysis, and strain was
281 and bronchus intermedius, 57.5% with dynamic expiration versus 28.6% with end expiration (P = .0022).
282 tion (P = .0046); carina, 53.6% with dynamic expiration versus 30.9% with end expiration (P < .0001);
283 as follows: aortic arch, 53.9% with dynamic expiration versus 35.7% with end expiration (P = .0046);
284 parenchyma density values on inspiration and expiration, visual HRCT scores, and pulmonary function t
286 revealed that scalene muscle activity at end-expiration was 50.7 +/- 14.0% higher at highest increase
288 inuation of mechanical inflation into neural expiration was associated with failure of the subsequent
292 in which mid-expiratory inflation lengthens expiration was used to study afferent modulation of resp
293 NO (estimated from bronchiolar gases at end-expiration) was near zero, suggesting NO in exhaled gase
294 yperpolarizing pFL neurons attenuated active expiration when it was induced by hypercapnia, hypoxia,
295 ibly obvious collapse of the alveolus during expiration, whether this collapse is total or partial.
297 l end of the facial nucleus abolished active expirations, while rhythmic inspirations continued.