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1 cost-effective alternative to admission to a pediatric intensive care unit.
2 ere caused by microorganisms acquired on the pediatric intensive care unit.
3 as performed in a university hospital 20-bed pediatric intensive care unit.
4 cluded in the myriad ethical dilemmas in the pediatric intensive care unit.
5 ajor cause of morbidity and mortality in the pediatric intensive care unit.
6 caring for the severely injured child in the pediatric intensive care unit.
7 ition and common reason for admission to the pediatric intensive care unit.
8 eived propofol compared with controls in the pediatric intensive care unit.
9 with inflicted injury who is admitted to the pediatric intensive care unit.
10             A single patient admitted to the pediatric intensive care unit.
11 a patients by patient characteristics and by pediatric intensive care unit.
12 lected from the emergency department and the pediatric intensive care unit.
13 lemented successfully in a tertiary center's pediatric intensive care unit.
14  assess the needs of parents bereaved in the pediatric intensive care unit.
15 anical ventilation longer than 48 hrs in the pediatric intensive care unit.
16        He was intubated and transferred to a pediatric intensive care unit.
17 ntly contribute to the pathology seen in the pediatric intensive care unit.
18 c diseases to be monitored or managed in the pediatric intensive care unit.
19  evidence to guide thromboprophylaxis in the pediatric intensive care unit.
20  recognized with increasing frequency in the pediatric intensive care unit.
21 asure for assessing organ dysfunction in the pediatric intensive care unit.
22 nts requiring a prolonged stay in a regional pediatric intensive care unit.
23 l conducted between 2009 and 2013 in 31 U.S. pediatric intensive care units.
24 ure monitoring on admission across the three pediatric intensive care units.
25 ts were consistently applied across multiple pediatric intensive care units.
26 spital coverage during daytime hours in many pediatric intensive care units.
27 ance bundles on CLABSI rates in neonatal and pediatric intensive care units.
28 e of morbidity and mortality in neonatal and pediatric intensive care units.
29 n has dramatically increased in neonatal and pediatric intensive care units.
30 acterial/yeast microorganism acquired on the pediatric intensive care unit; 4.0% (50 of 1,241) of chi
31                          Among this group of pediatric intensive care units, adding complex chronic c
32 tween any acute kidney injury at the time of pediatric intensive care unit admission, any acute kidne
33 rangement during the period <or=6 hrs before pediatric intensive care unit admission.
34 d O(2) >/= 30%, hospitalization >5 days, and pediatric intensive care unit admission.
35                       Fifty-three percent of pediatric intensive care unit admissions had complex chr
36                                              Pediatric intensive care unit and hospital length of sta
37 lowed liberal physical activity have shorter pediatric intensive care unit and hospital lengths of st
38                                      Overall pediatric intensive care unit and hospital mortality wer
39 e acute postoperative Fontan patients on the pediatric intensive care unit and nine anesthetized pati
40 ead, if altered standards of care quadrupled pediatric intensive care unit and non-intensive care uni
41 cted monogenic disorders in the neonatal and pediatric intensive care units and its use has a notable
42 l tubes (ETTs) commonly used in neonatal and pediatric intensive care units and the relationship of r
43 arious classes of drugs commonly used in the pediatric intensive care unit, and lists the techniques
44 rain injury is the leading cause of death in pediatric intensive care units, and improvements in ther
45 ildren aged 1 mo-20 y who were admitted to a pediatric intensive care unit at a tertiary-care center
46 thdrawal of life-sustaining treatment in the pediatric intensive care unit at three teaching hospital
47                         An in-hospital 24-hr pediatric intensive care unit attending coverage model h
48 er the implementation of a 24-hr in-hospital pediatric intensive care unit attending physician model.
49 linking staff intensivists on home-call with pediatric intensive care unit bedside care providers, pa
50 ne has grown rapidly, leading to a number of pediatric intensive care units being opened across the c
51 ted to a 20-bed, multidisciplinary, tertiary pediatric intensive care unit between January 1, 2009 an
52 of a child's being discharged alive from the pediatric intensive care unit by a given day, under a ra
53                             However, limited pediatric intensive care unit capacity would still requi
54 ncluding 30% severely ill/injured warranting pediatric intensive care unit care, with high (76%) pred
55 mine the impact of nutritional variables and pediatric intensive care unit characteristics on 60-day
56                                         In a pediatric intensive care unit, chest radiographs were ob
57   Forty-five patients were identified by the pediatric intensive care unit clinical team as meeting c
58        Multivariate analysis, accounting for pediatric intensive care unit clustering and important c
59 se, or any worsening RIFLE scores during the pediatric intensive care unit course and increased pedia
60 d any acute kidney injury develop during the pediatric intensive care unit course had a four-fold inc
61 , any acute kidney injury present during the pediatric intensive care unit course, or any worsening R
62 s had acute kidney injury develop during the pediatric intensive care unit course.
63 d 3 of sepsis, and in 14 control children on pediatric intensive care unit day 1.
64        Outcomes were measured at the time of pediatric intensive care unit discharge by the Pediatric
65  c) correlation of the score with outcome at pediatric intensive care unit discharge; d) subsequent p
66 en younger than 18 years discharged from the pediatric intensive care unit during the 3-year preinter
67 ion was collected on all the patients in the pediatric intensive care unit during the study period.
68 with suspected influenza infection across 38 pediatric intensive care units during November 2008 to A
69 including a catheterization (preadmission to pediatric intensive care unit), electrocardiogram, cardi
70 ease in relative risk (RR) of admission to a pediatric intensive-care unit for mechanical ventilation
71 nts in a 21-bed quaternary multidisciplinary pediatric intensive care unit had CVCs placed by attendi
72 </=16 years of age) who were admitted to the pediatric intensive care unit (ICU) and were expected to
73     Midazolam and morphine are often used in pediatric intensive care unit (ICU) for analgesia and se
74  providing late parenteral nutrition) in the pediatric intensive care unit (ICU) is clinically superi
75 16 years or younger who were admitted to the pediatric intensive care unit (ICU) of the University Ho
76                                          For pediatric intensive care unit (ICU) survivors, to determ
77 rates of unexpected autopsy findings between pediatric intensive care unit (ICU), emergency departmen
78 chanically ventilated children in nine large pediatric intensive care units (ICUs) across North Ameri
79  and diagnosis-adjusted mortality rates from pediatric intensive care units (ICUs) staffed by physici
80 siologic variables varied between individual pediatric intensive care units (ICUs), and c) if so, how
81                                There were 32 pediatric intensive care units (ICUs): 16 pediatric ICUs
82 d, double-blind study conducted in a level 3 pediatric intensive care unit in Rotterdam, The Netherla
83                Point-prevalence study in 101 pediatric intensive care units in 21 countries, on 6 pre
84                                           31 pediatric intensive care units in academic hospitals in
85                                              Pediatric intensive care units in two teaching hospitals
86 provider resources were not optimized when a pediatric intensive care unit increased by 22,000 square
87 e after a cardiac arrest in a patient in the pediatric intensive care unit is reported to be as low a
88 on (heart rate 0.81, p = .060) and decreased pediatric intensive care unit length of stay (heart rate
89 core (p = .001), poor disposition (p = .02), pediatric intensive care unit length of stay (rate ratio
90                                              Pediatric intensive care unit length of stay was less in
91 ric intensive care unit course and increased pediatric intensive care unit length of stay were identi
92 care unit course had a four-fold increase in pediatric intensive care unit length of stay.
93 ciated with neutrophil priming had prolonged pediatric intensive care unit length of stay.
94 ssociated with significantly greater odds of pediatric intensive care unit mortality (odds ratios 1.2
95  chronic conditions were at greater risk for pediatric intensive care unit mortality and prolonged le
96 servational study of factors associated with pediatric intensive care unit mortality at a tertiary ca
97 of complex chronic conditions into models of pediatric intensive care unit mortality improved model a
98              P-MODS correlated strongly with pediatric intensive care unit mortality in both study se
99         Those variables were correlated with pediatric intensive care unit mortality rate.
100 elated strongly and in a graded fashion with pediatric intensive care unit mortality rate.
101 ssociated or were negatively associated with pediatric intensive care unit mortality, and most were n
102 s were not associated with increased odds of pediatric intensive care unit mortality.
103  criteria (PaO2/FIO2 104 mm Hg +/- 36 mm Hg; pediatric intensive care units mortality 30.5%), whereas
104 patients (19.2%) had a PaO2/FIO2 >200 mm Hg (pediatric intensive care units mortality 7.1%) (p = .014
105                                              Pediatric intensive care unit of a children's hospital.
106 tices in a 36-bed, combined medical/surgical pediatric intensive care unit of an urban, academic, ter
107 operative polysomnogram was performed in the pediatric intensive care unit on the first operative nig
108 randomized and controlled trial of only four pediatric intensive care units over an 18-month period.
109                                              Pediatric intensive care unit patients are exposed to mu
110 at can capture, store, and archive data from pediatric intensive care unit patients for subsequent ti
111  the prevalence and characteristics of adult pediatric intensive care unit patients have not been rep
112                          We asked parents of pediatric intensive care unit patients to review the han
113                        Discharge data showed pediatric intensive care unit patients were discharged a
114                              Considering all pediatric intensive care unit patients, 3.1%, 32.0%, and
115 isk factors for gastrointestinal bleeding in pediatric intensive care unit patients, and the use of u
116 l gastric pH control in a high percentage of pediatric intensive care unit patients.
117 urately reflect arterial pH and PCO2 in most pediatric intensive care unit patients.
118 ted injury represent a growing challenge for pediatric intensive care unit personnel in terms of the
119  also explore the legal issues that confront pediatric intensive care unit physicians in relation to
120 ure and survival in patients admitted to the pediatric intensive care unit (PICU) after cardiac arres
121 ngth of stay, and functional outcomes in the pediatric intensive care unit (PICU) by using multi-inst
122 f early hyperthermia to neurologic status at pediatric intensive care unit (PICU) discharge and to PI
123 rventions to improve end-of-life care in the pediatric intensive care unit (PICU) has been performed.
124 SV) bronchiolitis requiring admission to the pediatric intensive care unit (PICU) have no risk factor
125                        Length of stay in the pediatric intensive care unit (PICU) is a reflection of
126 ute care period associated with survival and pediatric intensive care unit (PICU) length of stay (LOS
127 (NIV) has become increasingly popular in the pediatric intensive care unit (PICU) over the last decad
128 tion was compared with strict handwashing in pediatric intensive care unit (PICU) patients with solid
129 , multicenter, cohort study that included 59 pediatric intensive care units (PICUs) from 15 countries
130 h general/medical and cardiac/cardiovascular pediatric intensive care units (PICUs) in the Collaborat
131  aged 6 months to 17 years admitted to 21 US pediatric intensive care units (PICUs) with acute severe
132  Cluster randomized trial conducted in 31 US pediatric intensive care units (PICUs).
133                 The relevance of VILI in the pediatric intensive care unit population is thus unclear
134 nital heart surgery was better than that for pediatric intensive care unit populations as a whole.
135                          Most parents in the pediatric intensive care unit prefer their role in decis
136 and opiate administration, which may improve pediatric intensive care unit resource utilization.
137 tritional practices were recorded during the pediatric intensive care unit stay for a maximum of 10 d
138  worsening of acute kidney injury during the pediatric intensive care unit stay were independently as
139 ive care unit, the therapies used during the pediatric intensive care unit stay, and patient outcomes
140 dominantly occurred within the first week of pediatric intensive care unit stay.
141 nit (within 1 hr) and at any time during the pediatric intensive care unit stay.
142 acquired at least one infection during their pediatric intensive care unit stay.
143 iral infections (24.5%) were acquired during pediatric intensive care unit stay.
144 hat septic children with this SNP had longer pediatric intensive care unit stays, we speculate that t
145  care units that participated in the Virtual Pediatric Intensive Care Unit Systems database in 2008.
146                         She rounded with the pediatric intensive care unit team approximately two tim
147 n important and cost-effective member of the pediatric intensive care unit team.
148           Therapies and outcomes vary across pediatric intensive care units that care for children wi
149 is of 52,791 pediatric admissions to 54 U.S. pediatric intensive care units that participated in the
150                                              Pediatric intensive care units that utilized protocols f
151 mine severity of illness on admission to the pediatric intensive care unit, the therapies used during
152 pective study involving patients admitted to pediatric intensive care units to define the incremental
153 nt per day by the clinical pharmacist in the pediatric intensive care unit was 0.73 hrs or 0.02 full-
154 ield or emergency department, but not in the pediatric intensive care unit, was associated with poor
155 gnosed in children with prolonged illness on pediatric intensive care unit were due to microorganisms
156 ithout MOF admitted to a university hospital pediatric intensive care unit were enrolled in a prospec
157                                   All of the pediatric intensive care units were located in children'
158     In these scenarios, physician leaders in pediatric intensive care units were more likely to presc
159            Consecutive admissions from three pediatric intensive care units were recorded prospective
160 hs to 18 years of age who were admitted to a pediatric intensive care unit with clinically significan
161                 All patients admitted to the pediatric intensive care unit with length of stay of 4 h
162                     Children admitted to the pediatric intensive care unit with the diagnosis of seps
163 e enrolled children across 34 North American pediatric intensive care units with acute respiratory fa
164 ll pediatric patients admitted to two large, pediatric intensive care units with ALI/ARDS using Conse

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