Abstract
BackgroundSevere fetal acidemia during labour with arterial pH below 7.00 is associated with increased risk of hypoxic-ischemic brain injury. Electronic fetal heart rate (FHR) monitoring, the mainstay of intrapartum surveillance, has poor specificity for detecting fetal acidemia. We studied brain electrical activity measured with electrocorticogram (ECOG) in the near term ovine fetus subjected to repetitive umbilical cord occlusions (UCO) inducing FHR decelerations, as might be seen in human labour, to delineate the time-course for ECOG changes with worsening acidemia and thereby assess the potential clinical utility of fetal ECOG.Methodology/Principal FindingsTen chronically catheterized fetal sheep were studied through a series of mild, moderate and severe UCO until the arterial pH was below 7.00. At a pH of 7.24±0.04, 52±13 min prior to the pH dropping <7.00, spectral edge frequency (SEF) increased to 23±2 Hz from 3±1 Hz during each FHR deceleration (p<0.001) and was correlated to decreases in FHR and in fetal arterial blood pressure during each FHR deceleration (p<0.001).Conclusions/SignificanceThe UCO-related changes in ECOG occurred in advance of the pH decreasing below 7.00. These ECOG changes may be a protective mechanism suppressing non-essential energy needs when oxygen supply to the fetal brain is decreased acutely. By detecting such “adaptive brain shutdown,” the need for delivery in high risk pregnant patients may be more accurately predicted than with FHR monitoring alone. Therefore, monitoring fetal electroencephalogram (EEG, the human equivalent of ECOG) during human labour may be a useful adjunct to FHR monitoring.
Highlights
Studies of electrocortical activity in the ovine fetus near term using electrocorticogram (ECOG) recordings reveal alternating epochs of low-voltage/high frequency (LV/HF) electrocortical activity with high-voltage/low frequency (HV/LF) ECOG indicative of behavioural states that relate to cortical neuronal activity [1,2,3]
We studied ECOG in the near term ovine fetus, a well established model of human pregnancy, subjected to repetitive umbilical cord occlusions (UCO) leading to fetal heart rate (FHR) decelerations with worsening acidemia as might be seen in human labour
The key finding relevant to interpreting the cardiovascular and ECOG responses presented is that fetal arterial pH values showed a progressive decrease throughout the UCO series from baseline values of 7.3660.01 to 6.9060.04 following completion of the severe UCO series (p,0.05)
Summary
Studies of electrocortical activity in the ovine fetus near term using electrocorticogram (ECOG) recordings reveal alternating epochs of low-voltage/high frequency (LV/HF) electrocortical activity with high-voltage/low frequency (HV/LF) ECOG indicative of behavioural states that relate to cortical neuronal activity [1,2,3] (reviewed in [4]) This ECOG state activity becomes altered in response to induced hypoxia both chronically by reducing maternal inspired oxygen over several hours [5] and acutely by occluding the umbilical circulation over several minutes [6], with disruption in behavioural state cyclicity and flattening of the ECOG voltage amplitude. We studied brain electrical activity measured with electrocorticogram (ECOG) in the near term ovine fetus subjected to repetitive umbilical cord occlusions (UCO) inducing FHR decelerations, as might be seen in human labour, to delineate the time-course for ECOG changes with worsening acidemia and thereby assess the potential clinical utility of fetal ECOG
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