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1 and calf vascular resistance (determined by plethysmography).
2 nce tomography and six respiratory inductive plethysmography).
3 Breathing was monitored with plethysmography.
4 by monitoring their sniffing with whole-body plethysmography.
5 r permeability was estimated by strain gauge plethysmography.
6 0% O2) with 5 min intervals, was measured by plethysmography.
7 nction was determined by peripheral arterial plethysmography.
8 composition was measured by air-displacement plethysmography.
9 choline challenge was measured by whole-body plethysmography.
10 russide were assessed using venous occlusion plethysmography.
11 ssessed by standard forearm venous occlusion plethysmography.
12 Respiration was examined by plethysmography.
13 sensitivity were assessed during LBNP using plethysmography.
14 ition was measured by using air-displacement plethysmography.
15 omposition was measured via air-displacement plethysmography.
16 week-old unanaesthetized rats via whole-body plethysmography.
17 re, and pulmonary function was determined by plethysmography.
18 oronasal airflow and respiratory inductance plethysmography.
19 ined by the forced oscillation technique and plethysmography.
20 elivery as measured by respiratory inductive plethysmography.
21 onchoconstriction was assessed by whole body plethysmography.
22 easured using venous-occlusion, strain-gauge plethysmography.
23 ted for every subject using venous occlusion plethysmography.
24 nitroprusside were measured by strain-gauge plethysmography.
25 CAD) using a robust, modified form of volume plethysmography.
26 re airway hyperreactivity through whole-body plethysmography.
27 ow responses were measured with strain-gauge plethysmography.
28 as measured using bilateral venous occlusion plethysmography.
29 position was measured using air displacement plethysmography.
30 (0.3 and 1 nmol/min) using venous occlusion plethysmography.
31 il) vasodilators were measured using forearm plethysmography.
32 coronary artery disease by venous occlusion plethysmography.
33 nitroprusside were measured by strain-gauge plethysmography.
34 and during reactive hyperemia by venous air plethysmography.
35 in 10 cirrhotic patients by venous occlusion plethysmography.
36 ults with concentrations of exhaled NO after plethysmography.
37 whites and 18 blacks by use of strain-gauge plethysmography.
38 ng, and body composition by air-displacement plethysmography.
39 lood flow was determined by venous occlusion plethysmography.
40 Forearm blood flow was determined by plethysmography.
41 g non-dominant forearm with venous occlusion plethysmography.
42 ntilation (VE) was measured using whole-body plethysmography.
43 ery and correlated well with measurements at plethysmography.
44 oxide production by forearm venous occlusion plethysmography.
45 d flow (FBF was measured by venous occlusion plethysmography.
46 ion reflex responses to ETS were examined by plethysmography.
47 d at postnatal day 21 using air-displacement plethysmography.
48 rimester was assessed using air displacement plethysmography.
49 diposity was assessed using air displacement plethysmography.
50 tolic BP (DBP) were measured using tail cuff plethysmography.
51 ) mice of C57BL6 background using whole body plethysmography.
52 e time as measuring breathing via whole body plethysmography.
53 sition was determined using air displacement plethysmography.
54 al pulse wave velocity, and venous occlusion plethysmography.
55 n at 2 wk was determined by air-displacement plethysmography.
56 y hyperresponsiveness was evaluated by using plethysmography.
57 ume measurements using respiratory inductive plethysmography.
58 nce in live anesthetized mice using invasive plethysmography.
59 ation, as measured by respiratory inductance plethysmography.
60 m vasodilator responses to isoprenaline with plethysmography.
61 pedance tomography and respiratory inductive plethysmography.
62 zoelectric sensor, and inductive respiratory plethysmography.
63 rements were taken by using air displacement plethysmography.
64 measured lung function using spirometry and plethysmography.
65 Ventilation was measured by whole-body plethysmography.
66 using invasive tracheostomy and unrestrained plethysmography.
67 k EMG recordings and breathing by whole-body plethysmography.
68 l arm blood flow as assessed by strain-gauge plethysmography.
69 h COPD underwent MR imaging, spirometry, and plethysmography.
70 tion was measured in nonanesthetized mice by plethysmography.
71 s, left/right limbs 14/9, using strain gauge plethysmography; 7/16 of these had thrombosis extending
72 sodilation, by both forearm venous occlusion plethysmography (93 +/- 67% vs. 145 +/- 106%, p = 0.006)
73 and FFM were assessed using air displacement plethysmography a median of 6 times between birth and 6
74 re, electrocardiogram, and oxygen saturation plethysmography activity were recorded and reviewed for
75 to determine the ability of air-displacement plethysmography (ADP) and formulas based on triceps skin
76 l age (GA), with the use of air-displacement plethysmography (ADP) and the lambda-mu-sigma method for
78 mposition measurement using air displacement plethysmography (ADP) that was used to calculate a refer
79 , 4.5, and 6 mo of age with air-displacement plethysmography (ADP) validated against a stable isotope
82 tokine profile from reactivated splenocytes, plethysmography after aerosol challenge to pollen, cell,
84 ng forearm blood flow (FBF; venous occlusion plethysmography) after 5 minutes of arterial occlusion.
85 analysed in unanaesthetised animals by body plethysmography along with rate of O2 consumption (VO2))
89 udy, we established dwarf hamster whole-body plethysmography and assessed disease severity and propen
90 3 months corrected age with air displacement plethysmography and at 1-year-corrected age with skin-fo
91 factors were assessed with venous occlusion plethysmography and blood sampling during intra-arterial
92 , lung function was determined by whole-body plethysmography and bronchoalveolar lavage fluid was ana
93 ouble-blind, randomized case-control forearm plethysmography and crossover systemic interventional st
95 espiratory circuits, we performed whole-body plethysmography and electrophysiological recordings from
96 ood pressure (SBP) was measured by tail-cuff plethysmography and fecal microbiota analyzed by16S rRNA
100 n as 3-compartment model by air displacement plethysmography and isotope dilution in early (13-16 wee
103 tion was assessed through the use of forearm plethysmography and related to clinical disease activity
106 ed forearm blood flow (FBF; venous occlusion plethysmography) and calculated the vascular conductance
107 easured forearm blood flow (venous occlusion plethysmography) and calculated vascular conductance (FV
108 vascular conductance (FVC, venous occlusion plethysmography) and cutaneous vascular conductance (CVC
109 rm blood flow (measured via venous occlusion plethysmography) and intra-arterial blood pressure to qu
110 ulmonary function studies (spirometry and/or plethysmography), and a cardiology evaluation which incl
112 observed through antinociception, whole-body plethysmography, and blood-brain biodistribution studies
114 lood flow was determined by venous occlusion plethysmography, and dose-response curves were generated
116 methacholine was assessed by barometric body plethysmography, and numbers of lung eosinophils and lev
117 methacholine was assessed by barometric body plethysmography, and numbers of lung eosinophils and pro
119 of the lung for carbon monoxide (TLco), body plethysmography, and spirometry were assessed post-bronc
121 graphy, graded treadmill exercise, tail cuff plethysmography, and telemetry (heart rate, activity, te
122 Blood flow was measured by venous occlusion plethysmography, and the percentage of HbO(2) perfusing
123 illary lactate (the primary endpoint), thumb plethysmography, and ulnar frame count to investigate th
124 ibrated and validated a new air-displacement plethysmography (AP) method for measuring body compositi
126 , which was observed with the semi-automated plethysmography apparatus, but not a buried pellet test.
127 ycemia, we studied forearm blood flow (FBF) (plethysmography), arteriovenous glucose difference (AV-d
129 ed as enhanced pause (Penh) with noninvasive plethysmography at Day 16 of age), and did not cause inf
132 od flow, was measured noninvasively by using plethysmography at rest, after breathing supplemental ox
134 ial occlusion was determined by strain gauge plethysmography before and 4 h and six weeks after combi
135 ial acetylcholine) was assessed with forearm plethysmography before and after (1) 15-minute reperfusi
136 earm blood flow (FBF) using venous occlusion plethysmography before and after intra-arterial infusion
137 .2 microg/min) were assessed by strain-gauge plethysmography before and after nonselective blockade o
138 al voluntary contraction by venous occlusion plethysmography before and after regional inhibition of
139 rip and cold pressor test were determined by plethysmography before and during adrenergic receptor bl
140 latation were assessed with venous occlusion plethysmography before and during intra-arterial infusio
141 te-macrophage colony-stimulating factor) and plethysmography, before and after methacholine, to asses
142 blood flow was measured by venous occlusion plethysmography, before, and 8 min after, completing inf
143 y, nasal cannulas and respiratory inductance plethysmography belts connected to Nox-T 3 allows record
145 re measured using bilateral venous occlusion plethysmography, bioimpedance cardiography, transthoraci
146 to 10 minutes of forearm arterial occlusion (plethysmography), blood pressure, and muscle sympathetic
147 ing) constant bias, and the air displacement plethysmography body density and SFT methods showed posi
148 -compartment, Db(VRJ), BIA, air displacement plethysmography body density, and SFT ranging from a mea
149 ood pressure and heart rate were measured by plethysmography; body composition was estimated by DEXA;
150 e-macrophage colony-stimulating factor), and plethysmography, both before and after methacholine trea
151 sed at birth and at 3 mo by air-displacement plethysmography by using the Pea Pod system (Cosmed) and
152 of 10 healthy volunteers enclosed in a body plethysmography chamber mimicking the entrapment environ
153 pliant protocol and underwent spirometry and plethysmography, completed the St George's Respiratory Q
155 ume (both at airway opening and by inductive plethysmography) could be identified on the deflation li
157 with the reduction in respiratory inductive plethysmography-derived lung volume, high continuous dis
158 tive pulmonary disease underwent spirometry, plethysmography, diffusing capacity of carbon monoxide,
160 cardiac output were made by venous occlusion plethysmography, Doppler flow wire and quantitative coro
161 pedance tomography and respiratory inductive plethysmography during a stepwise recruitment procedure.
162 blood flow was measured by venous occlusion plethysmography during an intrabrachial infusion of brad
163 , freely behaving rat pups, using whole-body plethysmography during breathing of room air (RA), durin
164 blood flow was measured by venous occlusion plethysmography during intrabrachial infusions of apelin
165 of FM, and FFM measured by air-displacement plethysmography during the first 5 mo of life.Applying p
167 asurements were performed using strain-gauge plethysmography during transfusion, followed by testing
168 sing deuterium dilution and air-displacement plethysmography), eating behavior (measured by using a 3
170 a selection from raw recordings derived from plethysmography experiments and the analysis of these da
171 ion was assessed by forearm venous occlusion plethysmography, flow-mediated dilation, and pulse wave
172 All three visits utilized ECG and finger plethysmography for haemodynamic measures, and the high
173 e (HR), forearm blood flow (venous occlusion plethysmography), FVR, and MSNA (obtained through direct
174 ne resorption in rat AIA were assessed using plethysmography, histopathologic analysis, and immunohis
175 r results show that in whole-body barometric plethysmography, hM3Dq-mediated, global Foxb1(+) neuron
176 y frequency (RF) was monitored by whole-body plethysmography immediately after the 4th challenge (ear
177 hma were characterized with spirometry, body plethysmography, impulse oscillometry, alveolar and bron
178 hysiological tests, such as spirometry, body plethysmography, impulse oscillometry, and multiple brea
179 essed all participants with spirometry, body plethysmography, impulse oscillometry, multiple breath n
180 BQ-123 were assessed using venous occlusion plethysmography in 10 patients with syndrome X and 10 ma
181 Lung volumes were measured by spirometry and plethysmography in 109 healthy subjects aged 7-21 years.
182 lood flow was measured with venous occlusion plethysmography in 12 cigarette smokers and 12 age- and
183 blood flow was measured by venous occlusion plethysmography in 16 volunteers during infusion of SFLL
184 enous tone using radionuclide forearm venous plethysmography in 24 healthy subjects with no cardiovas
185 ) receptor blocker (BQ-123) were analyzed by plethysmography in 37 normotensive patients and 27 hyper
188 blood flow was measured by venous occlusion plethysmography in response to serial intra-arterial inf
189 viously determined by respiratory inductance plethysmography in that subject (i.e., particles inhaled
190 responses were assessed by venous occlusion plethysmography in the brachial circulation before and a
192 lf blood flow was measured with strain gauge plethysmography in the two higher dose treatment groups
193 (brachial catheter) and forearm blood flow (plethysmography) in 19 healthy subjects at baseline and
194 l improved peak blood flow (venous occlusion plethysmography) in arms (+24%, P=0.027) and legs (+23%,
196 ed by a combination of whole-body barometric plethysmography, invasive measurement of airway resistan
198 nhaled methacholine by barometric whole-body plethysmography is a valid indicator of airway hyperresp
199 ve surrogates for cystometry, such as penile plethysmography, lack sufficient evidence to allow recom
203 ficantly correlated to respiratory inductive plethysmography measurements in 12 patients (mean r = 0.
205 Parameters studied included strain-gauge plethysmography measures of peripheral circulatory funct
206 electroencephalography, electrocardiography, plethysmography, mechanical ventilation or pharmacologic
207 lood pressure data by the indirect tail-cuff plethysmography method consistently shows increased pres
208 lood flow were evaluated by venous occlusion plethysmography, MSNA by microneurography, and blood pre
209 control subjects underwent spirometry, body plethysmography, multiple-breath inert gas washout (with
210 otocols mimicking those imposed by tail-cuff plethysmography (novel environment, heat, restraint, inf
211 abdominal wall motion using opto-electronic plethysmography (OEP), (ii) intra-thoracic and intra-abd
215 linical Severity Scoring (VCSS) systems, air-plethysmography (outflow fraction [OF], venous filling i
216 es (deltaV(L)[t]) via respiratory inductance plethysmography over a range of P(aw) settings in five p
218 ung volume measured by respiratory inductive plethysmography, oxygen saturation, perfusion index, reg
220 A-602 or vehicle and conscious, unrestrained plethysmography performed on days 0, 3, and 5 (n = 7 to
222 l pressure (MAP), electrocardiography (ECG), plethysmography (Pleth), and the test systems utilized e
224 monitoring was limited to blood pressure and plethysmography preoperatively and intraoperatively.
225 ) data available from respiratory inductance plethysmography provided important insight to changes in
226 t a constant level to acquire a pulse volume plethysmography (PVP) waveform and calibrate it to brach
228 l artery to measure forearm blood flow (FBF, plethysmography) responses to administration of isoprena
229 n, forearm blood flow (FBF; venous occlusion plethysmography) responses to brachial artery administra
230 Forearm blood flow (FBF, by strain-gauge plethysmography) responses to local intra-arterial infus
233 contribute to eventual neonatal death, since plethysmography revealed that E18.5 Spi1(-/-) embryos ar
236 utility of calibrated respiratory inductance plethysmography (RIP) and esophageal manometry to identi
237 nd, to address whether respiratory inductive plethysmography (RIP) could be used to monitor changes i
239 ed home monitor using respiratory inductance plethysmography (RIP) with simultaneously recorded polys
242 ermination of cardiac function (by impedance plethysmography), serial pulmonary function tests (spiro
245 lsatile and the nonpulsatile portions of the plethysmography signal and is, in part, determined by st
246 ultiple breath inert gas washout (MBW), body plethysmography, single-breath determination of carbon m
248 s measured by spirometry (FEV1; n = 521) and plethysmography (sRaw; n = 567), and AHR by methacholine
250 vity was measured by non-invasive whole-body plethysmography, Th2 response and airway inflammation by
251 y pattern of the rat pups using flow-through plethysmography, then formed in situ preparations from t
252 kg (airway opening tidal volume), and 13.7% (plethysmography tidal volume) compared with total lung c
253 llary density (GCD); and 3) venous occlusion plethysmography to assess endothelium-dependent (% Hyper
254 and K(+)) analyses; and 2) venous occlusion plethysmography to assess peripheral microvascular filtr
255 to use the technique of abdominal inductance plethysmography to compare diurnal variation in girth in
256 ratory monitors using respiratory inductance plethysmography to detect apnea and obstructed breathing
257 nt, and ventilatory parameters by whole body plethysmography to determine the responses elicited by b
258 Subjects were studied using strain gauge plethysmography to measure blood flow, P(v), and the ven
261 aired in the mutant mice, we used whole-body plethysmography to quantitatively measure odor-evoked sn
262 arm blood flow (FBF) responses (strain-gauge plethysmography) to intra-arterial infusion of a selecti
263 arm blood flow (FBF) responses (strain gauge plethysmography) to intraarterial infusion of a selectiv
264 We measured forearm blood flow responses (plethysmography) to isocapnic hypoxia (arterial saturati
266 The following measurements were taken: FM by plethysmography, total and specific immunoglobulin E (Ig
267 , we introduce the concept of terahertz-wave-plethysmography (TPG), which detects blood volume change
268 ecorded in newborn rat pups using whole-body plethysmography under normoxic and hypoxic conditions.
269 healthy control subjects, with strain-gauge plethysmography used to measure venous pressure (Pv), fo
270 sessed by bilateral forearm venous occlusion plethysmography using acetylcholine and N-monomethyl-L-a
271 d methacholine were determined by whole body plethysmography using changes in enhanced pause (Penh) a
272 including compression ultrasound, impedance plethysmography, ventilation-perfusion scanning, compute
274 ism of death in cases of viral encephalitis, plethysmography was evaluated in mice infected with 3 fl
279 sponse), and in 6 subjects, venous occlusion plethysmography was used to measure forearm blood flow d
280 To address this question, venous occlusion plethysmography was used to measure forearm blood flow r
284 Pulmonary airflow resistance, as measured by plethysmography, was detected 1 day postinoculation and
285 pathology is the need to combine whole-body plethysmography (WBP) to measure respiration with electr
286 ) or noninvasive techniques, like whole body plethysmography (WBP), assesses the severity of pulmonar
290 h the dorsal hand vein technique and forearm plethysmography, we studied the effects of PAR-2 activat
291 phageal manometry and respiratory inductance plethysmography were made preextubation during airway oc
292 spiration and expiration), and spirometry or plethysmography were performed during a 2-hour visit to
293 py, ultrasonic vocalizations, and whole-body plethysmography were used to assess VF motion, swallow f
294 h recorded CPF (28% air and 72% strain gauge plethysmography) were included; 591 (38.5%) had normal C
295 ial artery catheter) and forearm blood flow (plethysmography) were measured and vascular conductance
296 ram) and beat-to-beat blood pressure (finger plethysmography) were recorded from all participants, wh
297 Subjects (n=157) underwent venous occlusion plethysmography with acetylcholine, bradykinin, glyceryl
298 ssessed by standard forearm venous occlusion plethysmography with acetylcholine, nitroprusside, and v
299 ultaneously in both arms by venous occlusion plethysmography with mercury-in-Silastic strain gauges w