Articles: critical-care.
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Critical care medicine · Oct 1985
Comparative StudyAPACHE II: a severity of disease classification system.
This paper presents the form and validation results of APACHE II, a severity of disease classification system. APACHE II uses a point score based upon initial values of 12 routine physiologic measurements, age, and previous health status to provide a general measure of severity of disease. ⋯ When APACHE II scores are combined with an accurate description of disease, they can prognostically stratify acutely ill patients and assist investigators comparing the success of new or differing forms of therapy. This scoring index can be used to evaluate the use of hospital resources and compare the efficacy of intensive care in different hospitals or over time.
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Critical care medicine · Oct 1985
Comparative StudyOutcome of critically injured patients treated at Level I trauma centers versus full-service community hospitals.
Critically injured patients were identified by a CRAMS (circulation, respiration, abdomen, motor, speech) score of 6 or less while still in the field. They were prospectively followed as they received their care at the nearest medical facility according to the then-existing district Emergency Medical Services protocols. Those cared for by Level I trauma centers had a significantly reduced mortality rate compared to those treated at the other large full-service community hospitals. The commitment to Level I trauma care improves outcome of the critically injured, and field triage of the critically injured patient to these centers is indicated.
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The Journal of pediatrics · Sep 1985
Comparative StudyPulse oximetry in pediatric intensive care: comparison with measured saturations and transcutaneous oxygen tension.
We evaluated a new pulse oximeter designed to monitor beat-to-beat arterial oxygen saturation (SaO2) and compared the monitored SaO2 with arterial samples measured by co-oximetry. In 40 critically ill children (112 data sets) with a mean age of 3.9 years (range 1 day to 19 years), SaO2 ranged from 57% to 100%, and PaO2 from 27 to 128 mm Hg, heart rates from 85 to 210 beats per minute, hematocrit from 20% to 67%, and fetal hemoglobin levels from 1.3% to 60%; peripheral temperatures varied between 26.5 degrees and 36.5 degrees C. ⋯ Simultaneous measurements with a tcPO2 electrode showed a similarly good correlation with PaO22 (r = 0.91), but the differences between the two measurements were much wider (mean 7.1 +/- 10.3 mm Hg, range -14 to +49 mm Hg) than the differences between pulse oximeter SaO2 and measured SaO2 (1.5% +/- 3.5%, range -7.5% to -9%) and were not predictable. We conclude that pulse oximetry is a reliable and accurate noninvasive device for measuring saturation, which because of its rapid response time may be an important advance in monitoring changes in oxygenation and guiding oxygen therapy.