Comparison of different methods for dead space measurements in ventilated newborns using CO2-volume plot

The aim of the study was to test the applicability of Ventrak 1550/Capnogard 1265 (V-C) for respiratory dead space (VD) measurement and to determine anatomic (VDana), physiologic (VDphys), and alveolar dead spaces (VDalv) in ventilated neonates. Prospective study. Neonatal intensive care unit. 33 in...

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Bibliographic Details
Published in:Intensive care medicine 1999-07, Vol.25 (7), p.705-713
Main Authors: WENZEL, U, WAUER, R. R, SCHMALISCH, G
Format: Article
Language:English
Subjects:
Anesthesia. Intensive care medicine. Transfusions. Cell therapy and gene therapy
Biological and medical sciences
Birth weight
Blood Gas Monitoring, Transcutaneous
Calibration
Carbon dioxide
Carbon Dioxide - metabolism
Electrodes
Emergency and intensive respiratory care
Female
Gestational age
Humans
Infant
Infant, Newborn
Intensive care
Intensive care medicine
Lungs
Male
Medical sciences
Newborn babies
Positive-Pressure Respiration
Prospective Studies
Respiratory Dead Space
Respiratory Distress Syndrome, Newborn - physiopathology
Respiratory Distress Syndrome, Newborn - therapy
Respiratory Function Tests
Sensors
Software
Time Factors
Ventilators
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Summary:The aim of the study was to test the applicability of Ventrak 1550/Capnogard 1265 (V-C) for respiratory dead space (VD) measurement and to determine anatomic (VDana), physiologic (VDphys), and alveolar dead spaces (VDalv) in ventilated neonates. Prospective study. Neonatal intensive care unit. 33 investigations in 22 ventilated neonates; median gestational age 34.5 weeks (range 27-41), median birthweight 2658 g (range 790-3940). The single-breath CO2 test (SBT-CO2) and transcutaneous partial pressure of carbon dioxide (PCO2) were recorded simultaneously and VD was determined (1) automatically (V-C software), (2) by interactive analysis of the PCO2 volume plot, and (3) manually by Bohr/Enghoff equations using data obtained by V-C. VD measurements were possible in all cases by method 3 but not possible by methods 1 and 2 in 22 of 33 investigations (67%), especially in preterm neonates, because of disturbed signals. V.Dana/kg (1.6 +/- 0.6 ml/kg, mean +/- SD), VDana/tidal volume (VT) (0.36 +/- 0.09) were lower compared to published data in spontaneously breathing infants, whereas VDphys/kg (2.3 +/- 0.9 ml/kg) and VDphys/VT (0.50 +/- 0.12) are comparable to data obtained from the literature. Five minutes after insertion of the sensor (dead space 2.6 ml) into the ventilatory circuit, the transcutaneous PCO2 rose above baseline for 3.2% (patients > 2500 g) and 5.7% (patients < 2500 g). The time necessary for one analysis was 50-60 min. In ventilated newborns, dead space measurements were possible only in one-third by SBT-CO2, but in all cases by Bohr/Enghoff equations. Improved software could further reduce the time needed for one analysis.
ISSN:0342-4642
1432-1238
DOI:10.1007/s001340050933