ライフサイエンスコーパス: pneumothorax

1 firming catheter positioning and detecting a pneumothorax.

2 le hamartomas, kidney tumors and spontaneous pneumothorax.

3 f developing renal neoplasms and spontaneous pneumothorax.

4 2 first-degree relatives with a spontaneous pneumothorax.

5 higher frequency of chest tube placement for pneumothorax.

6 2 for pleural effusion to 0.0004 for tension pneumothorax.

7 yst-positive patients had a prior history of pneumothorax.

8 lesser extent, renal tumors and spontaneous pneumothorax.

9 management of recurrent pleural effusion and pneumothorax.

10 t catheter malposition and procedure-related pneumothorax.

11 renal neoplasia, lung cysts, and spontaneous pneumothorax.

12 tilation, cardiopulmonary resuscitation, and pneumothorax.

13 There was one case of pneumothorax.

14 velopment of signs or symptoms suggestive of pneumothorax.

15 a are strongly correlated with occurrence of pneumothorax.

16 ervation and suction because of a persistent pneumothorax.

17 ls were artificially ventilated with an open pneumothorax.

18 ntilated, vagotomized, paralysed and given a pneumothorax.

19 atients were excluded because of preexisting pneumothorax.

20 Sixty-eight patients (22%) developed a pneumothorax.

21 of any air, and give no other indication of pneumothorax.

22 correlated strongly with the development of pneumothorax.

23 tly female and had an increased incidence of pneumothorax.

24 follow-up assessment because of a prolonged pneumothorax.

25 reporting clinical manifestations of tension pneumothorax.

26 discomfort, reexpansion pulmonary edema, and pneumothorax.

27 etermined to have radiographic evidence of a pneumothorax.

28 rule out associated lung complications like pneumothorax.

29 he influence of traditional risk factors for pneumothorax.

30 raditionally recognized risk factors such as pneumothorax.

31 l venous catheter positioning and screen for pneumothorax.

32 bacterial sepsis and clinically significant pneumothoraxes.

33 There was only one pneumothorax (0.1% [95% CI, 0-0.4%]), and the rate of ca

34 ement (0 of 1154 vs. 20 of 1822, P < 0.001), pneumothorax (0/715 vs. 11/1822, P = 0.009), and all mor

35 ng the procedure and was performed to reveal pneumothorax 1 and 3 hours after the procedure.

36 The rate of pneumothorax (1.9%) decreased (p < 0.0001).

37 elated adverse events in this group included pneumothorax (18% of patients) and events requiring valv

38 ased airway placement (3/143, p = 0.001) and pneumothorax (2 of 143, P = 0.01) compared to the Tube T

39 quired chest tube placement for treatment of pneumothorax (38% vs 17%, P = .006).

40 included sepsis, cellulitis, hemorrhage, and pneumothorax (4% incidence for each condition).

41 Significant reductions were seen in pneumothorax (5 of 105 intervention group infants [4.8%]

42 ent was needed in 25 (17.4%) of 144 cases of pneumothorax (7% of all biopsies).

43 Most accurately identified pneumothorax (86% correct) and increased intrathoracic p

44 pneumonia (20% coil vs 4.5% usual care) and pneumothorax (9.7% vs 0.6%, respectively) occurred more

45 ously labelled as having primary spontaneous pneumothorax, a group in whom recommended management dif

46 Among patients with pneumothorax, a significantly higher frequency of chest

47 ry tuberculosis, pulmonary Kaposi's sarcoma, pneumothorax, adult respiratory distress syndrome, sever

48 nd is faster than radiography at identifying pneumothorax after central venous catheter insertion.

49 Patients who develop clinically important pneumothorax after FNAB can be safely treated with short

50 ed a superficial infection and 1 developed a pneumothorax after LCNB.

51 to tourniquet, and 1 (6%) each from tension pneumothorax, airway obstruction, and sepsis.

52 Fifty patients (6.9 percent) had pneumothorax and 77 (10.6 percent) had pneumothorax or o

53 noninferior to chest x-ray for screening of pneumothorax and accurate central venous catheter positi

54 Strategies to avoid obstruction, bleeding, pneumothorax and air embolism are discussed in this arti

55 Minor complications (2%) included a small pneumothorax and an instance of transient nonsustained v

56 duction in procedure time and postprocedural pneumothorax and being free from ionizing radiation.

57 Diagnostic yield, accuracy, and pneumothorax and chest tube placement rates were compare

58 single and multiple dependent variables for pneumothorax and chest tube placement.

59 ese and other variables were correlated with pneumothorax and chest tube rates.

60 ternational guidelines for the management of pneumothorax and much geographical variation in clinical

61 here were two minor complications: one small pneumothorax and one limited hemothorax, neither of whic

62 ith the acute respiratory distress syndrome, pneumothorax and other air leaks - any extrusion of air

63 acic lung biopsy reduces the rate of overall pneumothorax and pneumothorax necessitating a drainage c

64 Longer dwell times do not correlate with pneumothorax and should not influence the decision to ob

65 se was reviewed for complications, including pneumothorax and thoracostomy tube insertion.

66 None of the nonintubated patients with pneumothorax and two of the six intubated patients with

67 Because development of a pneumothorax and/or pulmonary blebs may be the earliest

68 Radiographs confirmed one complication (pneumothorax) and 15 catheter tip malpositions (nine in

69 osition, there were one actual complication (pneumothorax) and six actual malpositions (three axillar

70 sound reduced inadvertent arterial puncture, pneumothorax, and hematoma formation.

71 These included pain, hemorrhage, pneumothorax, and hypotension.

72 arrest, cardiac tamponade, device infection, pneumothorax, and in-hospital death even after adjustmen

73 hors defined as death, neurovascular injury, pneumothorax, and infection).

74 include carotid artery puncture, arrhythmia, pneumothorax, and infection.

75 reatment of common problems such as empyema, pneumothorax, and lung biopsy has significantly altered

76 hown 30 chest radiographs, 14 of which had a pneumothorax, and were asked to give their level of conf

77 Pathophysiological mechanisms underlying pneumothorax are now better understood and this may have

78 m hepatic venoocclusive disease, spontaneous pneumothorax associated with obstructive airway disease

79 The most common complication was pneumothorax (at 32 [28.6%] of 112 intrathoracic injecti

80 o = 1.9; 95% CI, 1.7-2.2; p < 10), including pneumothorax, atelectasis, ventilator-associated pneumon

81 cations of CLM, which may include infection, pneumothorax, bleeding and malignant transformation, jus

82 Isolated familial spontaneous pneumothorax can be caused by mutations of the FLCN gene

83 A review of pneumothorax cases showed that the database (sensitivity

84 ng its drainage, ascites drainage, ruling-in pneumothorax, central venous cannulation, particularly f

85 After pneumothorax, chest tube placements were related to the

86 sensitivity and specificity of the system's pneumothorax coding were compared with those of manual f

87 al venous catheter position and exclusion of pneumothorax compared with chest radiography.

88 Carotid puncture and pneumothorax continue to be the most frequent mechanical

89 Outcome variables included airway placement, pneumothorax, death, and radiology resource utilization.

90 rences were found in either the incidence of pneumothorax (dependent position, 62 of 210 biopsies [30

91 he reported clinical presentation of tension pneumothorax depends on the ventilatory status of the pa

92 ensitivity and specificity of ultrasound for pneumothorax detection was nearly 100% in the participat

93 Pneumothorax developed in 11 of 50 patients (22%) in the

94 Pneumothorax developed in four of the 23 patients (17%)

95 ere potentially associated with PLV included pneumothorax development in one patient and mucus plug f

96 athophysiology and physical signs of tension pneumothorax differ by subject ventilatory status.

97 CT revealed pneumothorax during the procedure and was performed to r

98 mary lung cancer (five of 13) or spontaneous pneumothorax (eight of 13) was estimated after dynamic i

99 Intraoperative complications included pneumothorax, esophageal perforation, and gastric perfor

100 ioner also was not associated with decreased pneumothorax events (OR, 0.55; 95% CI, 0.06-5.3).

101 rtion site was not associated with decreased pneumothorax events (skin marking vs no skin marking odd

102 tesis were not associated with a decrease in pneumothorax events.

103 One patient in each group had a pneumothorax from a CT-guided biopsy sample; the patient

104 Pneumothorax, growth velocity, health care-associated in

105 Seventeen patients, who developed a large pneumothorax (> 30%) during computed tomographic (CT)-gu

106 ications followed were catheter malposition, pneumothorax, hemothorax, and cardiac tamponade.

107 injury seen on chest imaging was defined as pneumothorax, hemothorax, aortic or great vessel injury,

108 ry-cardiac fistula, flail tricuspid leaflet, pneumothorax, hemothorax, endocardial stripping and seiz

109 No instances of pneumothorax, hemothorax, or substantial bleeding compli

110 ium concentrations, gender, gestational age, pneumothorax, hyper- or hypocarbia, severity of illness,

111 Patients with unsuspected pneumothorax identified on the roentgenogram obtained im

112 f 137 patients and successfully screened for pneumothorax in 123 of 123 (100%).

113 Chest radiograph ruled out pneumothorax in 137 of 137 patients (100%).

114 patients, nonpulmonary organ failure in 20%, pneumothorax in 3%, and acute respiratory distress syndr

115 ead dislodgment was found in one patient and pneumothorax in another.

116 omplete or almost complete resolution of the pneumothorax in eight (47%) patients and partial recurre

117 Major complications were pneumothorax in five of 19 sessions (26%) and one bronch

118 ts and partial recurrence of a small, stable pneumothorax in four (24%) patients.

119 Minor complications were pneumothorax in one patient and mediastinal hematoma in

120 Initial complications were limited to one pneumothorax in the SCV group and one episode of oversed

121 e diagnosis of various conditions, including pneumothorax, in the International Space Station.

122 erformed between groups for risk factors for pneumothorax, including patient demographic characterist

123 The abnormalities included nodule, pneumothorax, interstitial disease, alveolar infiltrates

124 The detection of pneumothorax, interstitial disease, and rib fracture sho

125 ication of transthoracic needle lung biopsy, pneumothorax is common and often necessitates chest tube

126 ed subgroup of patients in whom the risk for pneumothorax is low enough (approximately 1%) with suffi

127 open surgery for the treatment of recurrent pneumothorax is questionable, because the number of rand

128 atheter aspiration of a large biopsy-induced pneumothorax is safe and easy to perform and may obviate

129 rval, 32.2 to 59.8), and among those without pneumothorax, it was 39.3 percent (95 percent confidence

130 rval, 36.4 to 43.6); among the patients with pneumothorax, it was 46.0 percent (95 percent confidence

131 Five patients developed a small pneumothorax (<10%) with use of the 25-gauge needle alon

132 n mainly by procedural complications such as pneumothorax, major bleeding, and the need for pacemaker

133 he mean cost per patient for lung biopsy and pneumothorax management was as follows: outpatients, $1,

134 h as rib fractures, lung injury, hemothorax, pneumothorax, mediastinal injuries, and others may prese

135 Pneumothorax, mortality in the NICU, and antenatal corti

136 scenarios: postoperative pulmonary embolus, pneumothorax, myocardial infarction, gastrointestinal bl

137 lications included pleural effusion (n = 7), pneumothorax (n = 2), pericarditis (n = 2), dislodged st

138 Complications included pneumothorax (n = 21) and parenchymal hemorrhage (n = 2)

139 ssive pleural adhesions (n = 4), native lung pneumothorax (n = 3), chylous effusion (n = 1), chylous

140 = 33), antibiotic desensitization (n = 30), pneumothorax (n = 3), or other reasons (n = 5).

141 case series/reports of 183 cases of tension pneumothorax (n = 86 breathing unassisted, n = 97 receiv

142 roup were oesophagitis (n=2), anaemia (n=1), pneumothorax (n=1), and abdominal pain (n=1, unlikely re

143 Major complications (3%) included pneumothorax (n=1), right ventricular laceration (n=1) a

144 reduces the rate of overall pneumothorax and pneumothorax necessitating a drainage catheter.

145 x and two of the six intubated patients with pneumothorax needed chest tubes.

146 There were no instances of pneumothorax, nerve injury, or bleeding complications.

147 Pneumothorax occurred after the placement of six cathete

148 ffusion, the needle size used, and whether a pneumothorax occurred after the procedure were determine

149 Pneumothorax occurred at 144 (40.4%) of 356 biopsies, in

150 ications occurred in 13 (2.2%) patients, and pneumothorax occurred in 10 (1.7%) patients.

151 Pneumothorax occurred in 124 (38%) of 324 patients who u

152 Pneumothorax occurred in 153 patients older than 60 year

153 Pneumothorax occurred in 19 (34%) of 56 biopsy procedure

154 Pneumothorax occurred in 20 (27%) of 75 biopsies, but ch

155 Pneumothorax occurred in 226 of 846 patients.

156 low-up of 26.1 months, recurrent ipsilateral pneumothorax occurred in 3 patients (3.8%) in the pleure

157 Pneumothorax occurred in 54 of 121 procedures (44.6%); a

158 Pneumothorax occurred in 54%.

159 Pneumothorax occurred in four of the 45 patients (9%) wh

160 In patients with emphysema, pneumothorax occurred in three of the 20 patients (15%)

161 Pneumothorax occurred in two subjects.

162 No pneumothorax occurred within 30 days of treatment.

163 Once pneumothorax occurred, chest tube placement related to t

164 Two patients developed a transient pneumothorax (one requiring drainage) but we recorded no

165 mation resulting from therapeutic artificial pneumothorax or from tuberculosis pleuritis.

166 Procedure duration, postprocedural pneumothorax or hemorrhage, and sample adequacy were rec

167 No independent predictor was identified for pneumothorax or insertion of a drainage catheter in grou

168 ividually reviewed to verify the presence of pneumothorax or misplacement, and any intervention perfo

169 Pneumothorax or other air leaks were not associated with

170 pressures or volumes and the development of pneumothorax or other air leaks.

171 ) had pneumothorax and 77 (10.6 percent) had pneumothorax or other air leaks.

172 ot affect either the incidence of postbiopsy pneumothorax or the incidence of pneumothorax that requi

173 with the pressures and volumes in those with pneumothorax or with any air leaks (the highest values d

174 cal ventilation (OR = 0.19, p = 0.001), or a pneumothorax (OR = 0.08, p = 0.001) were associated with

175 depth was the most significant predictor of pneumothorax (P = .002).

176 mpared with six of 24 patients (25%) without pneumothorax (P = .02).

177 edle track were independent risk factors for pneumothorax (P = .032 and .021, respectively), and emph

178 size also correlated with increased risk of pneumothorax (P = .04).

179 spiratory rate <10 or >29, flail chest, hemo/pneumothorax, paralysis, and multisystem trauma.

180 ions, significantly reduced the frequency of pneumothorax-particularly of large pneumothoraces-and, t

181 m), and 1 patient died of sepsis and tension pneumothorax (placebo arm).

182 body left during procedure (FB), iatrogenic pneumothorax (PTX), and postoperative wound dehiscence (

183 ong predisposition toward the development of pneumothorax, pulmonary cysts, and renal carcinoma, aris

184 The relationship between pneumothorax rate and age as a continuous distribution w

185 The difference in the pneumothorax rate between intubated and nonintubated pat

186 The pneumothorax rate was 15% (16 of 105) if no aerated lung

187 The overall pneumothorax rate was 28.4% (52 of 183 ablation sessions

188 and patient age had a significant effect on pneumothorax rate.

189 llow pleural puncture angle may increase the pneumothorax rate.

190 d level of training were not correlated with pneumothorax rate.

191 ures were associated with higher [corrected] pneumothorax rates (P <.05).

192 and prior surgery were associated with lower pneumothorax rates (P <.05).

193 ns for offering pleurodesis after an initial pneumothorax rather than postponing the procedure until

194 The prevalence rate of pneumothorax recorded was 0.4%, and accidental arterial

195 quently results in spontaneous lung rupture (pneumothorax; refs. 1-3).

196 CI, 2.5 to 44.4), and operator suspicion of pneumothorax (relative risk ratio, 25.9; CI, 8.6 to 78.5

197 surgery, 1 pocket hematoma, 1 seroma, and 1 pneumothorax required treatment.

198 cations, those who experienced hemorrhage or pneumothorax requiring a chest tube had longer lengths o

199 I, 6.0% to 7.2%) of all biopsies resulted in pneumothorax requiring a chest tube.

200 lications (symptomatic hemorrhage, P > .999; pneumothorax requiring chest tube and/or admission, P =

201 In the three-choice comparison, pneumothorax requiring chest-tube insertion occurred in

202 2.1 to -0.1; P = .03), increased the risk of pneumothorax requiring drainage (3.2% vs 1.2%; differenc

203 l stay; ventilator-free days through day 28; pneumothorax requiring drainage within 7 days; barotraum

204 children (n=183) likely to have spontaneous pneumothorax, scoliosis, and striae but were comparable

205 osed in childhood had similar occurrences of pneumothorax, shortness of breath, hemoptysis, nephrecto

206 patients with recurrent pleural effusions or pneumothorax should be investigated.

207 including cardiac perforation and tamponade, pneumothorax, stroke, transient ischemic attack, vascula

208 , cardiac tamponade, or pericardiocentesis), pneumothorax, stroke, vascular complications (consisting

209 systematic literature search for studies on pneumothorax surgery in Medline, Embase, Cochrane Librar

210 symptomatic thrombosis and a higher risk of pneumothorax than jugular-vein or femoral-vein catheteri

211 g this technique, there was a single delayed pneumothorax that occurred because of deviation from the

212 biopsies [27%]; P = .60) or the incidence of pneumothorax that required chest tube placement (depende

213 postbiopsy pneumothorax or the incidence of pneumothorax that requires chest tube placement.

214 a radiologic chest catheter to evacuate the pneumothorax, thereby allowing the biopsy to continue.

215 In a neonatal piglet model of pneumothorax treated with HFOV, with amplitude adjusted

216 In contrast, the risk for any pneumothorax was 15.0% (CI, 14.0% to 16.0%), and 6.6% (C

217 The pneumothorax was almost completely aspirated in all 17 p

218 An increased rate of pneumothorax was correlated with smaller lesion size (P

219 After saline lavage, a model of experimental pneumothorax was created by selective right mainstem int

220 6) in intraprocedural lung biopsy-associated pneumothorax was found when the experimental guide needl

221 The frequency of postbiopsy pneumothorax was identical (69%) in the two groups.

222 Pneumothorax was more than three times less frequent if

223 mplications occurred in 28 biopsies (25.4%); pneumothorax was most common (22.7%).

224 One small pneumothorax was noted during RF ablation but stabilized

225 Postprocedural pneumothorax was observed in 25 of 170 (14.7%) CT-guided

226 ve their level of confidence as to whether a pneumothorax was present.

227 After insertion, pneumothorax was ruled out by the presence of lung slidi

228 dures identified 8 pneumothoraces; the other pneumothorax was seen incidentally on a delayed roentgen

229 Pneumothorax was suspected in 5 of the 8 cases, and tube

230 Pneumothorax was the most common adverse event, occurrin

231 The detection of pneumothorax was the only abnormality with a statistical

232 is and all of those with desensitization and pneumothorax were alive 1 yr after ICU discharge.

233 variables that correlated significantly with pneumothorax were aspiration of air during the procedure

234 of highly active antiretroviral therapy and pneumothorax were significant independent predictors of

235 09, a total of 369 patients with spontaneous pneumothorax were treated by video-assisted thoracoscopi

236 symptomatic, enlarging, or greater than 30% pneumothorax were treated with an 8-F chest tube.

237 ry manifestations, most commonly spontaneous pneumothorax, were the primary events leading to the dia

238 ost common complication of thoracentesis was pneumothorax, which occurred in 6.0% of cases (95% CI, 4

239 five (29%) patients had recurrence of their pneumothorax, which ultimately required chest tube place

240 nt, underwent percutaneous aspiration of the pneumothorax while on the CT scanner table.

241 orted that none of the patients with tension pneumothorax who were breathing unassisted versus 39.6%

242 s reported among 43 (50.0%) cases of tension pneumothorax who were breathing unassisted versus 89 (91

243 entify subgroups at higher risk of recurrent pneumothorax who would benefit from early intervention t

244 his needle in comparison to the incidence of pneumothorax with a standard 18-gauge guide needle in a

245 e produces a substantially decreased risk of pneumothorax with comparable diagnostic accuracy, sensit

246 verse events, one patient (0.7%) developed a pneumothorax with hydrothorax after CVC placement for PB

247 l placement during intubation; 0.4% and 2.3% pneumothorax with jugular and subclavian central venous

248 guide needle and evaluated the incidence of pneumothorax with this needle in comparison to the incid

249 Thirty-eight (62%) patients had pneumothorax, with 19 (31%) requiring thoracostomy tube