ライフサイエンスコーパス: resuscitative

1 orrhagic shock with the addition of moderate resuscitative (28 degrees to 32 degrees C) hypothermia l

2 hydrate or glucagon administration, or other resuscitative actions) overall (three vs 18; p=0.0036).

3 ry and repair and account for the effects of resuscitative and rehabilitative care are needed.

4 erstanding clinical course and to anticipate resuscitative and therapeutic needs.

5 mbat casualties, which require a totally new resuscitative approach; the limits and potentials of rea

6 Current resuscitative approaches may not adequately alleviate im

7 Unfortunately, the outcome of prolonged resuscitative attempts cannot be predicted.

8 rences in the quality of simulated pediatric resuscitative care across a spectrum of EDs.

9 Importance: The quality of pediatric resuscitative care delivered across the spectrum of emer

10 ctive: To measure and compare the quality of resuscitative care delivered to simulated pediatric pati

11 esentation, location at second dose, initial resuscitative care, and antimicrobial activity mechanism

12 lated to ischemia, necrosis, reperfusion, or resuscitative dilution.

13 rred in residential neighborhoods with fewer resuscitative efforts before ambulance arrival and lower

14 in in patients aged >/=18 years who received resuscitative efforts by emergency medical services (EMS

15 e of provider ambiguity in prioritization of resuscitative efforts during an arrest.

16 irected order may state 'The patient desires resuscitative efforts during surgery and in the postoper

17 tionwide initiatives to facilitate bystander resuscitative efforts, including bystander defibrillatio

18 in Denmark to facilitate bystander-mediated resuscitative efforts, including bystander defibrillatio

19 ion, started as soon as possible after acute resuscitative efforts, may serve therapeutic roles beyon

20 arrest represents a fundamental component of resuscitative efforts, yet little is known about tempora

21 during out-of-hospital cardiac arrest (OHCA) resuscitative efforts.

22 rapy was administered during cardiopulmonary resuscitative efforts.

23 r about prognosis and preferences for future resuscitative efforts.

24 In a porcine model of hemorrhagic shock, resuscitative endovascular balloon aortic occlusion (REB

25 Resuscitative Endovascular Balloon Occlusion of the Aort

26 Resuscitative endovascular balloon occlusion of the aort

27 Resuscitative Endovascular Balloon Occlusion of the Aort

28 A new device, resuscitative endovascular balloon occlusion of the aort

29 clusion at the level of the renal ostia (via Resuscitative Endovascular Balloon Occlusion of the Aort

30 Resuscitative endovascular balloon occlusion of the aort

31 Resuscitative endovascular balloon occlusion of the aort

32 ing (PP), pelvic angioembolization (AE), and resuscitative endovascular balloon occlusion of the aort

33 rrhage is potentiated by aortic occlusion or resuscitative endovascular balloon occlusion of the aort

34 Resuscitative endovascular balloon occlusion of the aort

35 ctice of providing options to parents during resuscitative events.

36 observed, and prehospital and hospital-based resuscitative factors deserves further exploration.

37 All rats received 50 mL/kg 0.9% saline resuscitative fluid at 2 hrs.

38 rolled clinical trials evaluating its use as resuscitative fluid in brain-injured patients with hemor

39 adhesion may vary, depending on the type of resuscitative fluid used.

40 ic venous hypertension and administration of resuscitative fluids induces intestinal edema, mimicking

41 All artificial resuscitative fluids may not be similar or innocuous, as

42 iming and technique of infusing advantageous resuscitative fluids such as hypertonic saline and hemog

43 Resuscitative hypothermia after cardiac arrest, traumati

44 rmic cardiac arrest of 11 mins in dogs, mild resuscitative hypothermia from 15 mins to 12 hours after

45 mal duration of, and rewarming methods from, resuscitative hypothermia need clarification.

46 Resuscitative hypothermia was explored in the 1950s and

47 he main outcome was the odds of higher-level resuscitative interventions in the delivery room (DR).

48 ts from undergoing unwanted or inappropriate resuscitative interventions, and DNR orders are frequent

49 The volume of resuscitative IV fluid administered before the end of ho

50 t practice variation exists in the amount of resuscitative IV fluid given to patients with sepsis.

51 estrictive group received significantly less resuscitative IV fluid than the usual care group (47.1 v

52 With oxygenation proposed as a resuscitative measure during hypothermic models of prese

53 and the role of open-heart vs. closed-chest resuscitative measures are discussed.

54 eve that a DNR order indicates limitation of resuscitative measures only on cardiopulmonary arrest.

55 s decreased mortality; therefore, aggressive resuscitative measures seem merited in these patients.

56 e setting of moderate or severe hypothermia, resuscitative measures were facilitated with significant

57 ble patients, the management should focus on resuscitative measures, diagnostic testing, potential re

58 Often our resuscitative measures, while necessary, cause a wide ra

59 Resuscitative mild hypothermia, however, may be benefici

60 Resuscitative (postinsult) hypothermia is less well stud

61 es and vasopressor infusion >60 minutes) and resuscitative practices (homologous red blood cell [RBC]

62 pulmonary resuscitation interruptions, guide resuscitative procedures, and provides a continuous imag

63 auma for emergency surgeries or life-saving (resuscitative) situations and in everyday elective surge

64 Diaspirin crosslinked hemoglobin is a resuscitative solution with excellent oxygen-carrying ca

65 ween more restrictive and more liberal fluid resuscitative strategies (certainty of evidence: low); 2

66 rity of global tissue hypoxia resulting from resuscitative strategies on these early biomarker patter

67 With further understanding of new resuscitative strategies, the need for damage control su

68 used to provide diagnostic, therapeutic, and resuscitative support after sudden cardiac arrest from m

69 rrest no-flow, to buy time for transport and resuscitative surgery (hemostasis) performed during no-f

70 ere brain trauma, by enabling evacuation and resuscitative surgery during circulatory arrest, followe

71 m, flying ambulance surgical trauma, forward resuscitative surgery system teams) has been amply demon

72 creases the time available for transport and resuscitative surgery, followed by delayed resuscitation

73 oversy whether AO should be accomplished via resuscitative thoracotomy (RT) or via endovascular ballo

74 etween survivors and nonsurvivors undergoing resuscitative thoracotomy (RT).

75 hort study examined all cases of prehospital resuscitative thoracotomy for TCA in London from January

76 Prehospital resuscitative thoracotomy for TCA.

77 This study found that resuscitative thoracotomy is feasible in a mature, physi

78 Prehospital resuscitative thoracotomy was undertaken in 601 patients

79 We used resuscitative transesophageal echocardiography (TEE) to

80 improve access to early high-quality initial resuscitative trauma care for children.