ライフサイエンスコーパス: respiratory system

1 s was inversely related to compliance of the respiratory system.

2 Pinf,c) to the measured values of the total respiratory system.

3 y infections that have a predilection to the respiratory system.

4 ansport and on bacterial colonization of the respiratory system.

5 or pathologic liquid plug flows found in the respiratory system.

6 is one of the major lines of defense of the respiratory system.

7 ith CF have normal elastic properties of the respiratory system.

8 f neuronal activity patterns controlling the respiratory system.

9 kely secondary to increased impedance of the respiratory system.

10 rticles (SiO2 NPs) cause oxidative stress in respiratory system.

11 ation, branching, and differentiation of the respiratory system.

12 utable to the mechanical load imposed on the respiratory system.

13 rmal values for oxygen and compliance of the respiratory system.

14 ory pressure-volume (P-V) curve of the total respiratory system.

15 of epithelial branches that constitutes the respiratory system.

16 index of an early developmental stage of the respiratory system.

17 outy gene function enhances branching of the respiratory system.

18 that Shh is essential for development of the respiratory system.

19 he toxic effects of cigarette smoking in the respiratory system.

20 r commands and afferent information from the respiratory system.

21 he lungs, the chest wall, and the integrated respiratory system.

22 makes unique and multifaceted demands on the respiratory system.

23 ns, represents a first contact site with the respiratory system.

24 ASC in lymphoid tissues associated with the respiratory system.

25 poreal carbon dioxide removal to support the respiratory system.

26 helial cell types including those lining the respiratory system.

27 their capability to penetrate deep into the respiratory system.

28 sights into the regenerative capacity of the respiratory system.

29 ubsets of these cells functioning within the respiratory system.

30 ll unknown basic information about the human respiratory system.

31 result in diseases in brain, heart, and the respiratory system.

32 e of the major lines of defense of the human respiratory system.

33 ystem, including in the gastrointestinal and respiratory systems.

34 monitors the digestive, cardiovascular, and respiratory systems.

35 e mimicry, as well as the cardiovascular and respiratory systems.

36 ic to organs of the developing digestive and respiratory systems.

37 ring development of the gastrointestinal and respiratory systems.

38 es as an important electron junction in many respiratory systems.

39 on of the terminal branches of the tracheal (respiratory) system.

40 sure resulted in the lowest elastance of the respiratory system (18.6 +/- 6.1 cm H2O/L) after a recru

41 iratory distress syndrome (compliance of the respiratory system, 22 +/- 3 mL/cm H2O).

42 nce interval (CI): 0.55, 0.95; P = 0.02) and respiratory system (6 studies; pooled relative risk = 0.

43 n of tidal volume, dynamic compliance of the respiratory system, a/A ratio, and PaCO2 by measuring be

44 To probe how the cardiac and the respiratory system adjust their rhythms, despite continu

45 ac (adjusted OR = 1.37, 95% CI: 1.00, 1.89), respiratory system (adjusted OR = 1.89, 95% CI: 1.00, 3.

46 The respiratory system, although readily accessible, remains

47 flurane transiently enhanced activity of the respiratory system, an effect that was most prominent at

48 oteins elicit NOS-dependent signaling in the respiratory system and (2) studies that link SNO signali

49 nesthesia and surgery produce changes in the respiratory system and are responsible, along with under

50 The resistances of the respiratory system and chest wall were not altered by su

51 nts or in terms of dynamic elastances of the respiratory system and chest wall.

52 he physiological basis for complexity in the respiratory system and its implications for disease.

53 Thus, mechanics of the respiratory system and its lung and chest wall component

54 s to human beta-defensin 1 is present in the respiratory system and other mucosal surfaces in mice.

55 murine homologue of hBD-2 is present in the respiratory system and other mucosal surfaces.

56 e lung are critical to maintaining a healthy respiratory system and preventing pulmonary disease.

57 disease, sleep apnea, and infections of the respiratory system and some nonrespiratory sites, which

58 lay critical roles in fluid clearance in the respiratory system and the brain, and flagella are requi

59 itive end-expiratory pressure (PEEPi) of the respiratory system and the respective lung and chest wal

60 logical processes, such as signalling in the respiratory system and vasodilation in the cardiovascula

61 interplay between the autonomic nervous and respiratory systems and the ventricular rate.

62 een implicated in branching of the tracheal (respiratory) system and formation of wing interveins.

63 In both the developing Drosophila tracheal (respiratory) system and mammalian lung, a fibroblast gro

64 crosis, massive bacterial replication in the respiratory system, and blood-borne dissemination to oth

65 We labelled the factors mood, respiratory system, and peripheral nervous system, accor

66 hology on arthropod mobility, osmoregulatory/respiratory systems, and defensive strategies.

67 Regarding symptoms not connected with the respiratory system, anemia occurred most frequently.

68 e organs (APC = -6.01%), and diseases of the respiratory system (APC = -6.29%) decreased significantl

69 map showing where the organs of the gut and respiratory system are derived from in the early Xenopus

70 of respiratory timing so that the motor and respiratory systems are coupled.

71 vote a greater fraction of their body to the respiratory system, as tracheal volume scaled with mass1

72 ance (difference of R5 and resistance of the respiratory system at 20 Hz [R5-20]; 2.0 vs 0.7 cm H2O .

73 th the decrease in FEV1 and reactance of the respiratory system at 5 Hertz.

74 ine IOS results, including resistance of the respiratory system at 5 Hz (R5; 6.4 vs 4.3 cm H2O . L(-1

75 Spirometric and IOS (resistance of the respiratory system at 5 Hz [R5] and 20 Hz [R20], reactan

76 5 Hz [R5] and 20 Hz [R20], reactance of the respiratory system at 5 Hz [X5], resonant frequency of r

77 relationship (pressure-volume curve) of the respiratory system before and 6 hrs after bacterial inst

78 ion limb of the pressure-volume curve of the respiratory system beyond the inflection point.

79 t ramifications not only in the evolution of respiratory systems but also in the origin of life itsel

80 character are complicated by control of the respiratory system by the oscillator and its feedback me

81 bles for severe ARDS: radiographic severity, respiratory system compliance (</=40 mL/cm H2O), positiv

82 y distress syndrome, p = 0.014), had reduced respiratory system compliance (34 vs 29 vs 30 vs 23 L/cm

83 )), the quotient of tidal volume (V(T)), and respiratory system compliance (C(RS)), which could serve

84 Respiratory system compliance (Crs) and lung compliance

85 Respiratory system compliance (Crs) in infants with cyst

86 act of administration order, on oxygenation, respiratory system compliance (Crs), hemodynamics, and l

87 tial inspiratory airway resistance (Raw), or respiratory system compliance (mean [index minus control

88 oxygenation indices (p < .001) and increased respiratory system compliance (p < .05).

89 Lung lavage significantly lowered respiratory system compliance (static as well as specifi

90 Accurate assessment of change in respiratory system compliance after any therapeutic inte

91 pliance measurement that incorporates static respiratory system compliance and functional residual ca

92 l of mean airway pressure after lung lavage, respiratory system compliance and functional residual ca

93 ure, pulmonary artery pressure and flow, and respiratory system compliance and resistance were measur

94 central catheters and tracheostomy to lower respiratory system compliance and worsen ventilation per

95 Group rank sums for static respiratory system compliance at 3 and 6 hrs were compar

96 the functional residual capacity and static respiratory system compliance at the same level as the p

97 in whom there was a minimal change in leak, respiratory system compliance decreased significantly (p

98 Age- and sex-adjusted total respiratory system compliance fell by 7.0% per standard

99 in all three alpha1-AT groups, but decreased respiratory system compliance in the groups given Survan

100 Also, the 3- and 6-hr static respiratory system compliance values at each of the volu

101 Global respiratory system compliance was improved in the electr

102 blood gases, pH, airway pressure, and static respiratory system compliance were measured and compared

103 normalized" functional residual capacity and respiratory system compliance).

104 ll ventilation strategies induced changes in respiratory system compliance, although the pattern of c

105 yed sternal closure on expired tidal volume, respiratory system compliance, and CO2 elimination immed

106 We evaluated oxygenation, airway pressures, respiratory system compliance, and hemodynamics at basel

107 rterial oxygen tension gradient, FIO2, PaO2, respiratory system compliance, and minute ventilation.

108 total protein, fluid balance, hemodynamics, respiratory system compliance, and oxygenation.

109 al parameters, such as the plateau pressure, respiratory system compliance, or transpulmonary pressur

110 atory drive (tidal volume/inspiratory time), respiratory system compliance, peak airway pressure, and

111 For all variables except static respiratory system compliance, the hourly rate of change

112 For static respiratory system compliance, the slope of the pressure

113 GHS-2(-/-) mice exhibited decreased baseline respiratory system compliance, whereas only allergic PGH

114 re, thereby invalidating recorded changes in respiratory system compliance.

115 ng fibrosis led to a substantial decrease in respiratory system compliance.

116 Because respiratory-system compliance (CRS) is strongly related

117 ver and PEEP titration according to the best respiratory-system compliance (n = 501; experimental gro

118 The secondary end points included respiratory-system compliance and patient outcomes.

119 ed with PEEP titration according to the best respiratory-system compliance decreases 28-day mortality

120 Respiratory-system compliance was also significantly bet

121 ociation with an improvement in oxygenation, respiratory-system compliance, and blood pressure with f

122 iciently produced in the mitochondria by the respiratory system consisting of complexes I-V.

123 The mammalian respiratory system, consisting of both trachea and lung,

124 Respiratory system cooling occurs via convective and eva

125 is is explained only partially by absence of respiratory system cooling of shunted blood.

126 an PFO- subjects due, in part, to absence of respiratory system cooling of the shunted blood and that

127 Compliance of the respiratory system (Crs) was calculated as the slope of

128 r, it has been shown to increase the risk of respiratory system defects.

129 During early respiratory system development, the foregut endoderm giv

130 re associated with inflammatory response and respiratory system disorders.

131 ulate the anastomosis of the upper and lower respiratory systems during development.

132 Changes in respiratory system dynamic compliance, mean airway press

133 ory lung volume and static compliance of the respiratory system (EELV-Cst,rs); as well as by CT scan:

134 found to significantly improve lung volumes, respiratory system elastance, and oxygenation.

135 positive end-expiratory pressure PaO2/FIO2, respiratory system elastance, lung weight, normally aera

136 companied by improvements in oxygenation and respiratory system elastance.

137 Chest wall and respiratory system elastances grew with increases in pos

138 Chest wall and respiratory system elastances increased with increases i

139 Finally, chest wall and respiratory system elastances may vary unpredictably wit

140 d-expiratory pressure levels, chest wall and respiratory system elastances were calculated at each po

141 Such a respiratory system enables rationalization in this organ

142 wn that specifically reduce As(V), namely, a respiratory system (encoded by the arr genes) and a deto

143 logical systems, such as the cardiac and the respiratory system, exhibit complex dynamics that are fu

144 The respiratory system, for a number of reasons, has proven

145 lyzed TTSPs, reported to be expressed in the respiratory system, for the ability to activate influenz

146 y derived organs of the gastrointestinal and respiratory system form at distinct anterioposterior and

147 and adaptive defense mechanisms protect the respiratory system from attack by microbes.

148 Analysis of an in silico mitochondrial respiratory system further showed evidence that CSC cons

149 Recent studies have shown that the respiratory system has an extensive ability to respond t

150 d by macrophages and epithelial cells in the respiratory system have significant influence on surfact

151 /- 0.8 vs 4.6 +/- 1.5 s; p < 0.001), dynamic respiratory system hysteresis (0.6 +/- 0.3 vs 1.4 +/- 0.

152 ed per protocol, was "quantified" as dynamic respiratory system hysteresis (pressure-volume loop [in

153 To investigate the possibility of estimating respiratory system impedance (Zrs, forced oscillation te

154 putative endogenous excitatory drive to the respiratory system in rapid eye movement (REM) sleep may

155 strate an endogenous excitatory drive to the respiratory system in REM sleep and account for rapid an

156 process is formulated for both the motor and respiratory system in response to changes in motor outpu

157 esponses in local lymphoid tissues along the respiratory system in vaccinated and further aerosol-inf

158 anism, may contain a previously unrecognized respiratory system in which H(2) metabolism is coupled t

159 testing often assesses the cardiovascular or respiratory systems in isolation, ignoring the major pat

160 The avian respiratory system includes high-compliance air sacs tha

161 er recent decades, RM research regarding the respiratory system, including the trachea, the lung prop

162 ental effects on both the cardiovascular and respiratory systems, including a higher incidence of ath

163 tion of infected meat by ferrets resulted in respiratory system infection only (due to A/Muscovy duck

164 ed here, we partitioned the mechanics of the respiratory system into lung and chest-wall components,

165 The respiratory system is a complex network of many cell typ

166 s of the (clinical) application of RM to the respiratory system is discussed, and bottlenecks and rec

167 The respiratory system is highly pliable in its adaptation t

168 The respiratory system is immature at birth and significant

169 ge in maximum ventilation) suggests that the respiratory system is not the sole constraint to oxygen

170 Embryonic development of the respiratory system is regulated by a series of mesenchym

171 The Drosophila tracheal (respiratory) system is a tubular epithelial network that

172 In the respiratory system, it has been shown that the dysregula

173 is protocol generates most cell types of the respiratory system, it may be useful for deriving patien

174 In the respiratory system, loss of Hoxa5 function causes neonat

175 We measured mechanics of the respiratory system, lung, and chest wall during passive

176 No differences in the resistances of the respiratory system, lung, and chest wall were observed b

177 s of these forms of OP(DTT) deposited in the respiratory system may have differing health impacts.

178 ical injury and pulmonary edema, measured by respiratory system mechanics and lavage fluid protein.

179 s blood pressures, arterial blood gases, and respiratory system mechanics at baseline, after inductio

180 Our data thus confirm that analysis of respiratory system mechanics under dynamic conditions is

181 ide, airway hyperresponsiveness to mannitol, respiratory system mechanics using the forced oscillatio

182 n combination with PLV improved oxygenation, respiratory system mechanics, and lung pathology to a gr

183 lume was determined on each CT scan section; respiratory system mechanics, gas exchange, and hemodyna

184 ons, it is not known whether diseases of the respiratory system might be influenced by the presence o

185 e calculated the pressure to which the total respiratory system must be inflated to achieve a volume

186 were gastrointestinal tract (n=22, 39%) and respiratory system (n=14, 25%).

187 ses of the circulatory (n = 247 [46.9%]) and respiratory systems (n = 77 [14.6%]), certain infections

188 eral factors: the surface temperature of the respiratory system near the outside of the organism, the

189 Despite the importance of respiratory system neuroplasticity, and its dependence o

190 nongenomic estrogen signaling in any form of respiratory system neuroplasticity.SIGNIFICANCE STATEMEN

191 A compliance of the respiratory system of 30 mL/cm H2O was the best cut-off

192 that can penetrate into the body through the respiratory system of dental surgeons and patients.

193 We examined the neural control of the respiratory system of littermate wild-type (control) and

194 smitted through and predominantly affect the respiratory system of mammals.

195 uired for normal epithelial branching in the respiratory system of several species.

196 mpared the passive elastic properties of the respiratory system of sleeping infants with CF (n = 10)

197 ida is a mucosal pathogen that colonizes the respiratory system of susceptible hosts.

198 siological and biological differences in the respiratory systems of infants, children, and adults, it

199 and canine viruses hardly replicated in the respiratory systems of pigs, avian and seal viruses repl

200 The tracheal (respiratory) system of Drosophila melanogaster is a bran

201 ontrol in the embryonic and larval tracheal (respiratory) system of Drosophila.

202 ull mutants (eth(-)) fail to inflate the new respiratory system on schedule, do not perform the ecdys

203 ificantly increased SMRs for diseases of the respiratory system or heart, or for haematological malig

204 This method of "correcting" the total respiratory system P-V curve for the chest wall allows f

205 chest wall had little influence on the total respiratory system P-V curve.

206 Fio2 (p = .08), and static compliance of the respiratory system (p = .006).

207 The respiratory system participates in acid-base homeostasis

208 elative humidity of 99.5% reveal significant respiratory system particle deposition enhancements at s

209 properties of vertebrate cardiovascular and respiratory systems, plant vascular systems, insect trac

210 ods to assess the chest wall effect on total respiratory system pressure-volume (P-V) curves in acute

211 ike plant stems, leaf veins and vascular and respiratory systems provide hierarchical branching and p

212 nificantly correlated with compliance of the respiratory system (r = .58), but not with tidal volume.

213 These results show that the respiratory system reached or approached its physiologic

214 ght of the object (light or heavy) while the respiratory system reflected responses seen when lifting

215 e requires additional inputs (e.g., from the respiratory system), remains unclear.

216 suring respiratory impedance, which includes respiratory system resistance (Rrs) and reactance (Xrs).

217 Using end-inspiratory airway occlusion, respiratory system resistance (Rrs) can be partitioned i

218 lthy subjects underwent MCh challenges until respiratory system resistance (Rrs) had increased by app

219 inistered methacholine, ROFA increased total respiratory system resistance and decreased compliance 1

220 acholine challenge as evidenced by increased respiratory system resistance and elastance (p < 0.05).

221 Spirometry, inspiratory capacity, respiratory system resistance and reactance, tidal breat

222 rol subjects exhibited a uniform decrease in respiratory system resistance at all frequencies, wherea

223 We partitioned total respiratory system resistance into airway (Raw) and tiss

224 thma had a significantly different change in respiratory system resistance with weight loss: control

225 Respiratory system resistance, FEV1/FVC, and expiratory

226 y was transiently inhibited by inflating the respiratory system several times to a volume at an airwa

227 In the respiratory system, stimulation of T2Rs expressed in res

228 sumed to arise from specific features of the respiratory system, such as an enclosed intrapulmonary b

229 l in treating inflammatory conditions of the respiratory system, such as asthma and allergic rhinitis

230 These include defects in the respiratory system, such as lung hypoplasia and agenesis

231 al immunosenescence seen between the gut and respiratory system suggests the nasal route of vaccinati

232 The particle depositions in the respiratory system tend to be more severe during hazy da

233 lations, are more common for diseases of the respiratory system than for those of other organ systems

234 It has an anaerobic respiratory system that consists of a single enzyme, a m

235 The higher the compliance of the respiratory system, the better the prediction of fluid r

236 plicated in host defense is activated in the respiratory system, the trachea, of Drosophila.

237 ring development of the Drosophila tracheal (respiratory) system, the cell bodies and apical and basa

238 The mammalian respiratory system--the trachea and the lungs--arises fr

239 at if there was a REM-dependent drive to the respiratory system, then respiratory activity should eme

240 ports showing effects of volcanic ash on the respiratory system, there are limited data evaluating ce

241 acic compliance (Crs), resistance (Rrs), and respiratory system time constant (Trs).

242 In the respiratory system, TLR activation has both beneficial a

243 Given the resistance of the respiratory system to develop tolerance, desensitization

244 ion of the kidney is to collaborate with the respiratory system to maintain systemic acid-base status

245 rdia [2] and full voluntary control of their respiratory system to such extent that even mild anesthe

246 much to learn about the ability of the adult respiratory system to undergo repair and to replace cell

247 al terminal cells, a component of the insect respiratory system, to investigate branching morphogenes

248 (Rti-z) were extracted from measurements of respiratory system transfer impedance (Ztr[omega]) over

249 ed and deposited in different regions in the respiratory system, transition metal ions predominately

250 the evolution of a key feature of the avian respiratory system, unidirectional airflow, is that it i

251 If compliance of the respiratory system was >30 mL/cm H2O, then the area unde

252 If compliance of the respiratory system was </= 30 mL/cm H2O, then pulse pres

253 By contrast, if compliance of the respiratory system was </= 30 mL/cm H2O, then the area u

254 ess syndrome patients, the compliance of the respiratory system was 45 +/- 9 mL/cm H2O.

255 is possible that the default pattern of the respiratory system was due to a lack of visual size cues

256 ace elements in various regions of the human respiratory system was estimated using a Multiple-Path P

257 The respiratory system, which consists of the lungs, trachea

258 to regulatory mechanisms of the cardiac and respiratory systems, which influence respiratory sinus a

259 collapsible tube closely simulated the human respiratory system with flow limitation.

260 a novel pathway linking the inflammatory and respiratory systems, with implications for inspiration a

261 protect against infectious challenges to the respiratory system yet also may be associated with exace