Carbon Dioxide Levels When Starting High Frequency Ventilation in Neonates ()
1. Introduction
One of the major problems when starting high-frequency ventilation (HFV) in neonates is knowing which amplitude can be set to achieve an acceptable pCO2 level. Initial amplitude is usually set at a level that achieves adequate chest wiggle as assessed by the clinician.
Often the first pCO2 level after starting HFV can be outside the acceptable range, which can be harmful. Hypocapnia causes cerebral vasoconstriction, decreased cerebral blood flow, cerebral is chaemia, and periventricular leukomalacia. Hypercapnia induces cerebral vasodilation with increased CBF increasing the risk for severe intraventricular haemorrhage. Both can lead to poor neurological outcomes for preterm infants. There is only anecdotal evidence available of how often the first pCO2 level is outside acceptable values. Also, the first blood gas after starting HFV may not be done in a timely manner. The extent of these problems is unknown.
Our aims were to determine the initial pCO2 levels that occurred after starting HFV, and the time taken to obtain the initial blood gas.
2. Methods
We conducted an observational service evaluation using a retrospective cohort of neonates that required their first HFV episode from 1 January 2017 to 31 March 2019 in the Grantley Stable Neonatal Unit at the Royal Brisbane and Women’s Hospital.
In our, unit HFV is generally started when high pressures are required to achieve adequate oxygenation despite a fraction of inspired oxygen > 80%, or large tidal volumes are required to achieve adequate CO2 clearance, using conventional mechanical ventilation. This is regardless of gestational age or weight. After starting HFV a blood gas should be done within 30 minutes.
Data were collected on gestational age at birth, birth weight, sex, condition before starting HFV (post-natal age, post-menstrual age, lung disease, ventilation settings, last pCO2 level, use of postnatal steroids prior to starting HFV), and initial HFV episode (reason for starting HFV, duration of HFV required, first blood gas result after starting HFV, initial ventilation settings on HFV).
Statistical analysis: Data were analysed using simple descriptive statistics presented as number (percent), mean (standard deviation—SD), or median (interquartile range—IQR) and was performed using Microsoft® Excel for Mac (version 16.25 (19051201), Product ID 02954-050-803041, Redmond, Washington, USA).
3. Results
A total of 112 neonates were included in the study. The median (IQR) birth weight was 938 (692 - 1549) grams, and the median (IQR) gestational age was 27.2 (24.6 - 30.7) weeks. Fifty-five percent (61/112) were male. Before starting HFV the median (IQR) FiO2 was 0.55 (0.43 - 1.0); 97/112 (87%) were on conventional mechanical ventilation and in the remaining 15 (13%) HFV was the first mode of ventilation used. The mean (SD) pCO2 prior to starting HFV was 61.7 (17.0) mmHg. The median (IQR) post-natal age at starting HFV was 0.61 (0.11 - 2.45) days.
After HFV started the initial ventilation used was as follows: mean (SD) amplitude of 21.3 (6.2) cmH2O; mean (SD) frequency of 13 (2.7) Hz; mean (SD) mean airway pressure (MAP) of 15.4 (2.8) cmH2O, and median (IQR) FiO2 of 0.60 (0.35 - 1.0). The mean (SD) first pCO2 after starting HFV was 53.7 (22) mmHg. The median (IQR) duration of HFV was 3.9 (1.1 - 10) days.
Of the 112 neonates started on HFV, the first blood gas results were obtained within 30 minutes in 47 neonates (42%) and within one hour in 85 neonates (76%), with a significant delay of two or more hours in eight (7.1%).
Thirty-two of the 112 initial pCO2 levels (28.6%) were significantly hypo- or hypercapnic; 15 (13.4%) hypocapnic (pCO2 < 35 mmHg), and 17 (15.2%) hypercapnic (pCO2 > 65 mmHg). The frequency distribution of first pCO2 level is shown in Figure 1.
4. Discussion
We have demonstrated that a large proportion (29%) of neonates are either significantly hypocapnic (pCO2 < 35 mmHg) or significantly hypercapnic (pCO2 > 65 mmHg) when starting on HFV. There is also a significant delay in obtaining blood gas after starting HFV.
To our knowledge, this is the first study investigating the incidence of the initial pCO2 levels after starting HFV. Our study not only highlights the problem of obtaining the initial pCO2 level in a timely fashion, but also the resulting delays in reaching an acceptable pCO2 level.
Figure 1. Frequency distribution of first pCO2 level after starting HFV.
Ventilation (CO2 clearance) during HFV happens predominantly by facilitated diffusion with CO2 exchange mostly dependent on the set amplitude and frequency [1]. Evidence on how to optimise amplitude, other than the objective assessment of the amount of chest wiggle, is emerging by way of measuring and controlling tidal volume (VThf) using volume guarantee (VG) and CO2 diffusion coefficient (DCO2) levels [1] [2] [3] [4] [5]. Recent studies show that methods such as using VG can minimize the amount of time spent to achieve acceptable pCO2 levels, better achieve pCO2 levels in the target range and reduce fluctuations in pCO2 levels [2]. To date the optimal DCO2, VThf, and VG values have not yet been established, with studies reporting on these parameters showing great variations between populations of infants, lung pathology, initial ventilator settings used (especially frequency), and targeted pCO2 levels [1] [2] [3] [4] [5]. Nevertheless, there is enough data to enable a reasonable estimate of the tidal volume to target when starting HFV, as opposed to guessing the best amplitude to set based on an inaccurate assessment of chest wiggle.
The presence or absence of brain lesions (e.g. haemorrhage or ischaemia) will affect acceptable pCO2 levels. Hypocapnia causes cerebral vasoconstriction, decreased cerebral blood flow, cerebral ischaemia, and periventricular leukomalacia. Hypercapnia induces cerebral vasodilation with increased CBF increasing the risk for severe intraventricular haemorrhage. Both can lead to poor neurological outcomes for preterm infants.
Implementing changes resulting from these findings to improve clinical practice will include early and more timely blood gas assessments and the use of VG when starting HFV (using an estimated targeted VThf for a given frequency). We anticipate that this will lead to more initial pCO2 levels in the target range and a shortened duration to achieve acceptable pCO2 levels.
5. Conclusion
In conclusion, a large proportion of neonates have unacceptable pCO2 levels values upon starting HFV for the first time. There are also significant delays in obtaining the initial pCO2 levels.
Acknowledgements
Many thanks to Dr. David Cartwright for his assistance with the data extraction.