ライフサイエンスコーパス: chest tube

1 iopsies resulted in pneumothorax requiring a chest tube.

2 1.7 microg) or talc slurry (400 mg/kg) via a chest tube.

3 an 30% pneumothorax were treated with an 8-F chest tube.

4 intubated patients with pneumothorax needed chest tubes.

5 12F chest tube and opioids [n = 29]; or 12F chest tube and NSAIDs [n = 28]).

6 ps (24F chest tube and opioids [n = 28]; 24F chest tube and NSAIDs [n = 29]; 12F chest tube and opioi

7 = 114) were randomized to 1 of 4 groups (24F chest tube and opioids [n = 28]; 24F chest tube and NSAI

8 28]; 24F chest tube and NSAIDs [n = 29]; 12F chest tube and opioids [n = 29]; or 12F chest tube and N

9 ision if biopsy was required) received a 24F chest tube and were randomized to receive opiates (n = 1

10 hemorrhage, P > .999; pneumothorax requiring chest tube and/or admission, P = .417).

11 d-chest resuscitation with opened and closed chest tubes and medical and fluid interventions were ina

12 afely treated with short-term, small-caliber chest tubes and require hospital admission only if they

13 ds for blood vessel cannulation or epidural, chest tube, and initial trocar placement often involve t

14 Abscess drainage, placement of chest tubes, and nephrostomies have increased, but bilia

15 essfully as outpatients, with removal of the chest tube before discharge the day of FNAB.

16 A significantly higher mean 12-h chest tube blood loss (655 +/- 580 ml vs. 503 +/- 378 ml

17 bypass beta correlated well with duration of chest tube (CT) drainage (r=0.90, n =16), net perioperat

18 number of critical deficiencies remain (eg, chest tubes, diagnostics, and orthopedic and neurosurgic

19 Patients with chest tube drainage >2 weeks had an increased risk of PL

20 left atrial (>13 mm Hg) pressures, prolonged chest tube drainage (>21 days), post-operative ventricul

21 in the fenestrated group had 55% less total chest tube drainage (P=0.036), 41% shorter total hospita

22 es and studies performed and the duration of chest tube drainage and is associated with less pain and

23 The primary end point was 24-hour chest tube drainage and key secondary end point was tota

24 Mean 24-hour chest tube drainage in clopidogrel-treated patients was

25 (n = 24), defined as >1000 mL of cumulative chest tube drainage in the first 24 postoperative hours,

26 values (r2 = .71) and cumulative mediastinal chest tube drainage in the first 4 postoperative hours i

27 rative blood loss was 0 to 50 cm3, and total chest tube drainage was 110 to 395 cm3.

28 of mechanical ventilation was 1 day; median chest tube drainage was 5.5 days (range, 1 to 35).

29 of mechanical ventilation, intensive care or chest tube drainage, or adverse events.

30 >/=7 days (odds ratio [OR]=9.2, P=0.02) and chest tube duration >/=10 days (OR=22.7, P=0.009).

31 pitalization >/=7 days; OR=1.24, P=0.007 for chest tube duration >/=10 days) and total pulmonary veno

32 pitalization >/=7 days; OR=1.18, P=0.006 for chest tube duration >/=10 days).

33 nutes (range, 47 to 428 minutes), and median chest tube duration was 3 days (range, 1 to 14 days).

34 eumothoraces in patients without preexisting chest tubes; five (6.0%) episodes of bronchial hemorrhag

35 th increased duration of hospitalization and chest tube following Fontan completion.

36 Chest tube gas flow increased with increasing inspirator

37 time, amplitude, and mean airway pressure on chest tube gas flow were determined.

38 scores were lower among patients in the 12F chest tube group (n = 54) vs the 24F group (n = 56) (mea

39 enced hemorrhage or pneumothorax requiring a chest tube had longer lengths of stay (P < 0.001) and we

40 The talc group were admitted for chest tube insertion and talc for slurry pleurodesis.

41 Complications during chest tube insertion occurred more commonly with 12F tub

42 ), with a 9.8% (18 of 183 ablation sessions) chest tube insertion rate.

43 d less access to fiberoptic bronchoscopy and chest tube insertion.

44 nning of the semester and for intubation and chest tube insertion.

45 ee-choice comparison, pneumothorax requiring chest-tube insertion occurred in association with 13 (1.

46 Prehospital chest tube insertions (214 vs 158) and surgical procedur

47 ions, 457 fiberoptic bronchoscopies, and 295 chest tube insertions.

48 Smaller chest tubes may be less painful than larger tubes, but e

49 The clopidogrel group had higher 24-h mean chest tube output (1,224 ml vs. 840 ml, p = 0.001), and

50 carriers, and evaluated the impact of FVL on chest tube output and transfusion by using univariate an

51 (IF) or extracardiac Fontan (EF), days with chest tube output per day >5, 10, and/or 20 mL. kg(-1).

52 he ReVS+ patients had prolonged LOS, greater chest tube output, and more pleurodesis (P<0.05), and PA

53 d need for transfusion of blood products and chest tube output.

54 Early postoperative chest-tube output, blood-product transfusion requirement

55 a chest tube vs 81% in those not requiring a chest tube, P = .006) and FEV1/FVC (forced vital capacit

56 the incidence of pneumothorax that required chest tube placement (dependent position, 10 of 210 biop

57 sions along fissures predisposed patients to chest tube placement (P <.05).

58 ch was associated with a higher frequency of chest tube placement for pneumothorax.

59 more group B than group A patients required chest tube placement for treatment of pneumothorax (38%

60 nostic yield, accuracy, and pneumothorax and chest tube placement rates were compared between the two

61 Once pneumothorax occurred, chest tube placement related to the severity of the pati

62 rax occurred in 20 (27%) of 75 biopsies, but chest tube placement was necessary in only three cases (

63 Chest tube placement was needed in 25 (17.4%) of 144 cas

64 Chest tube placement was required in 2.0% of procedures

65 othorax, a significantly higher frequency of chest tube placement was seen in those with severe obstr

66 agement, including the use of thoracentesis, chest tube placement, fibrinolytic therapy and open thor

67 dle biopsy and otherwise would have required chest tube placement, underwent percutaneous aspiration

68 ses of pneumothoraces (two patients required chest tube placement, while 10 were asymptomatic and req

69 neumothorax is common and often necessitates chest tube placement.

70 n, number of needle passes, and frequency of chest tube placement.

71 t CT), with eight (5%) biopsies resulting in chest tube placement.

72 hysema were three times as likely to require chest tube placement.

73 the incidence of pneumothorax that requires chest tube placement.

74 It can occur with barotrauma and after chest tube placement.

75 is safe and easy to perform and may obviate chest tube placement.

76 Twelve (70%) patients did not require chest tube placement.

77 ple dependent variables for pneumothorax and chest tube placement.

78 heir pneumothorax, which ultimately required chest tube placement.

79 After pneumothorax, chest tube placements were related to the presence of em

80 iables were correlated with pneumothorax and chest tube rates.

81 th a median of 7.5 days from intervention to chest tube removal and 15 days from intervention to disc

82 age at 6 hours, 24 hours, and at the time of chest tube removal in the high-dose adenosine cardiopleg

83 Chest tube removal, wound drain removal, and arterial li

84 Results were evaluated 1 and 3 months after chest tube removal.

85 ), catheter wiring for retention (one case), chest tube suctioning (two cases), and surgical removal

86 erial and venous catheterizations, bilateral chest tube thoracostomies, and tracheostomies were perfo

87 Other treatment included chest tube thoracostomy, sump drainage of proximal esoph

88 Chest tube treatment was required in eight (14%).

89 me in 1 second) (51% in patients requiring a chest tube vs 81% in those not requiring a chest tube, P

90 Placement of 12F chest tubes vs 24F chest tubes was associated with a sta

91 ; 95% CI, -11.7 to -0.2 mm; P = .04) and 12F chest tubes vs 24F chest tubes were associated with high

92 After 2 hours, the chest tube was clamped, and if the lung remained expande

93 Pain while chest tube was in place (0- to 100-mm visual analog scal

94 st tube was placed, and gas flow through the chest tube was measured with a pneumotachometer during H

95 A chest tube was placed, and gas flow through the chest tu

96 emained expanded for an additional hour, the chest tube was removed and the patients were discharged

97 of six catheters (2.5%); in two patients, a chest tube was required for decompression.

98 occurred in 54 of 121 procedures (44.6%); a chest tube was required in 18 cases (14.9%).

99 Gas flow through the chest tube was significantly higher (p <.001) at 5 Hz (6

100 t alveolar ventilation, gas flow through the chest tube was significantly lower at 15 Hz compared wit

101 Placement of 12F chest tubes vs 24F chest tubes was associated with a statistically signific

102 -0.2 mm; P = .04) and 12F chest tubes vs 24F chest tubes were associated with higher pleurodesis fail

103 Chest tubes were left in place for at least 72 h.

104 Chest tubes were placed in 14 patients (4%): Six patient