The Incidence and Severity of Hypocarbia in Neonates Undergoing General Anesthesia

Discussion

Our study identified that the incidence of any hyperventilation and significant hyperventilation in neonates during general anesthesia was 33% and 12%, respectively. There were only 2 subjects in the study cohort with extreme hyperventilation ( ≤ 25  mm  Hg). The subjects who had a lower body weight were more likely to have significant hyperventilation. All the subjects were managed by a pressure control ventilation mode, and multivariate analysis did not confirm any statistical significance with regard to subject or ventilation characteristics.

In recent years, significant data have emerged from neonatal ICUs with regard to the potential deleterious effects of hyperventilation on the central nervous and pulmonary systems. Two major determinants of long-term morbidity in preterm infants are intraventricular hemorrhage/periventricular leukomalacia and bronchopulmonary dysplasia. Hypocapnia in the neonate has been shown to be a risk factor for periventricular leukomalacia, intraventricular hemorrhage, cerebral palsy, cognition development disorder, and auditory deficits.⁷ The duration of hypocapnia has also been demonstrated to play a role in the incidence of periventricular leukomalacia, intraventricular hemorrhage, and bronchopulmonary dysplasia. Ikonen et al⁸ demonstrated that an increasing duration of hypocapnia ( < 30  mm  Hg) in the first 72 h of life was associated with an increased severity of periventricular leukomalacia and subsequent development of neurologic impairment and cerebral palsy. A subsequent study by Erickson et al⁴ demonstrated that an increasing duration of hypocarbia was associated with an increased incidence of bronchopulmonary dysplasia.

A decrease in the will lead to cerebral vasoconstriction and to decreased cerebral blood flow and decreased cerebral oxygen delivery. These effects on the neonatal brain may be exaggerated or exacerbated in the operating room by other variables, such as hypotension, hyperoxia, hypoglycemia, anemia, and hyperthermia. As these data have emerged, there has been a shift in ventilation strategies in the neonatal ICU, with a focus on permissive hypercapnia guiding ventilation. However, these strategies may not be well known by anesthesia providers and have not necessarily been adopted during intraoperative anesthetic care.

During intraoperative care, even in previously intubated and mechanically ventilated neonates, patients are transported to the operating room. During an anesthetic procedure, ventilation parameters and requirements may be changed as an intraoperative ventilator is used or there may be variations in basal metabolic rate related to anesthetic agents or physiologic stresses imposed by the surgical procedure. The issues of intraoperative mechanical ventilation are compounded by difficulties with the accurate measurement of tidal volume and minute ventilation, especially in the neonatal population. This can be related to many factors, including the use of a cuffed versus uncuffed endotracheal tube, dead space in the anesthesia circuit, and the type of anesthesia ventilator used. Chambers et  al⁹ demonstrated that, not only do uncuffed endotracheal tubes exhibit a higher leak, independent of the mode of ventilation, but the delivered tidal volumes and leak percentage change over time, particularly when pressure-controlled ventilation is used. It is not unusual for flexible elbow connectors or heat-and-moisture exchangers to be added to a circuit, both of which contribute to an increase in circuit dead space.¹⁰ Anesthesia ventilators equipped with compliance compensation have been shown to accurately deliver small tidal volumes, whereas those without this technology are far less accurate.¹¹

A small percentage of neonates presenting to the operating room have an arterial line in situ or require one for the surgical procedure. ABG measurements only provide a single snapshot of ventilation, which makes following trends more difficult. End-tidal carbon dioxide pressure ( ) monitoring is standard in the operating room but is not standard in all neonatal intensive care settings. Various factors, including high fresh gas flows, sampling errors, small tidal volumes, ventilation-perfusion inequalities, and changes in dead space affect the accuracy of monitoring.¹² These factors affect the correlation between the and , which makes the gradient variable during prolonged cases. Transcutaneous CO₂ monitoring has been shown to be as accurate as monitoring in patients with normal respiratory function and may be more accurate in patients with shunts or ventilation perfusion abnormalities; however, transcutaneous CO₂ is not readily available in most pediatric operating rooms.¹²

A previous prospective study from the neonatal ICU with a large cohort in Europe showed that the incidence of hypocapnia ( < 30  mm  Hg or 4 kPa) is relatively uncommon (4% of blood gases).¹³ The most recent retrospective study from a single-center, neonatal ICU also demonstrated a very low incidence of hypocapnia ( < 30  mm  Hg), which is <2% of all the ABG samples.¹⁴ Analysis of our data demonstrated that this incidence is higher during intraoperative care in the neonatal population. Our cohort of neonates revealed that one third had at least one ABG that demonstrated inadvertent hyperventilation, and 12% experienced significant hyperventilation with a ≤ 30  mm  Hg. With the increasing volume of literature emerging with regard to deleterious effects of hypocapnia, continuous monitoring of ventilation in neonates during an anesthetic may be warranted.¹⁴

With our data, we were not able to compare the modes of ventilation and the incidence of hyperventilation because all the subjects were ventilated by using a pressure-control mode of ventilation. This strong preference for use of pressure control is likely institution-dependent and related to problems with measuring small tidal volumes with current anesthesia-based ventilators and flow meters. However, data from neonatal ICU studies does clearly demonstrate several advantages of volume-targeted modes of ventilation compared with pressure-limited modes of ventilation. Two different meta-analyses that compared volume-targeted to pressure-limited ventilation in preterm infants showed reductions in incidence of bronchopulmonary dysplasia, hypocarbia, grade III/IV intraventricular hemorrhage, pneumothorax, and duration of mechanical ventilation.^15,16 It is possible that, by decreasing the variability of delivered tidal volumes by using a volume-targeted mode of ventilation, there may be a decrease in volutrauma and lung injury. Reducing the incidence of hypocarbia and large variations in may lead to more stable cerebral perfusion and, subsequently, less neonatal brain injury.¹⁵

Interestingly, we noted that the subjects in our study who experienced significant hyperventilation had a lower minute ventilation and breathing frequency than those who were not hyperventilated. This may be due to active adjustments made during surgery by anesthesia providers in response to ABG values. Without demonstrating a clear relationship between increased minute ventilation and decreased , other factors may be playing a role in determining during the intraoperative period, including changes in dead space or ventilation-perfusion matching, depth of anesthesia, and metabolic rate (CO₂ production).

Permissive hypercapnia has become a commonly used ventilation strategy in neonatal intensive care settings.¹⁷ However, analysis of our data demonstrates that inadvertent hyperventilation is common during intraoperative anesthetic care. Although it is unknown if these limited periods of hyperventilation are detrimental, when combined with other potential complications of surgery and anesthesia, including hypotension, bleeding and resultant anemia, and hypoglycemia, unintentional harm may occur in our youngest and most vulnerable population. Combined with the potential for anesthetic-induced neurotoxicity, it may be time to reevaluate our intraoperative ventilation strategies and CO₂ monitoring devices for this population.

The potential limitations of this study should be acknowledged. First, because we evaluated data, we only included subjects who had an arterial line and ABG data during surgery. This might suggest that our patient population was comparatively sicker or the procedure was more invasive compared with the patients who did not require intraoperative arterial line or ABG sampling, thereby impacting the incidence of hyperventilation if it is more common in this subset of patients. Second, subject and ventilation characteristics data were limited in this study because we used a retrospective design. Therefore, other possible confounding factors related to hyperventilation, such as leak, type of endotracheal tube, and exact ventilation parameters, were not able to be captured. However, with these limitations in mind, this was the first study to our knowledge that investigated the incidence of inadvertent hyperventilation during intraoperative care in neonates.