Fetal electroencephalography, also known as prenatal EEG includes any recording of electrical fluctuations arising from the brain of a fetus. Doctors and scientists use EEGs to detect and characterize brain activity, such as sleep states, potential seizures, or levels of a coma. EEG captures the electrical activity in the vicinity of the recording electrodes. The majority of the neural electrical activity arises from the flow of current from the cell bodies of

pyramidal neurons Pyramidal cells, or pyramidal neurons, are a type of multipolar neuron found in areas of the brain including the cerebral cortex, the hippocampus, and the amygdala. Pyramidal neurons are the primary excitation units of the mammalian prefrontal cor ...

to their

apical dendrite An apical dendrite is a dendrite that emerges from the apex of a pyramidal cell. Apical dendrites are one of two primary categories of dendrites, and they distinguish the pyramidal cells from spiny stellate cells in the cortices. Pyramidal cells a ...

s, which become

depolarized In biology, depolarization or hypopolarization is a change within a cell, during which the cell undergoes a shift in electric charge distribution, resulting in less negative charge inside the cell compared to the outside. Depolarization is esse ...

by excitatory inputs from other

neuron A neuron, neurone, or nerve cell is an electrically excitable cell that communicates with other cells via specialized connections called synapses. The neuron is the main component of nervous tissue in all animals except sponges and placozoa. N ...

s. To record the most accurate signals, scientists try to minimize the distance between the recording electrode and the neural activity that they want to detect. Given the difficulty of attaching electrodes to a

fetus A fetus or foetus (; plural fetuses, feti, foetuses, or foeti) is the unborn offspring that develops from an animal embryo. Following embryonic development the fetal stage of development takes place. In human prenatal development, fetal deve ...

inside a uterus, doctors and scientists use a variety of techniques to record fetal brain activity. The three most common techniques for recording electrical brain activity before birth include: * Attaching electrodes directly onto the fetus' scalp during surgical removal of the fetus * Attaching electrodes on the maternal abdomen or cervix to record activity from the fetus in the third trimester * Attaching electrodes to the scalp of an infant during labor and delivery. The recording of the youngest fetus was performed between 43 and 45 days gestation and revealed some EEG features observed in newborns.

History

In 1942, Dr. Lindsley recorded the first electrical activity from the brain of an unborn infant when he noticed that an electrical recording from his pregnant wife's lower abdomen resembled the electrical recordings from the scalp of a newborn. To follow up, in 1955, Bernstine, Borkowski and Price examined and described 32 fetal EEGs recorded from the maternal abdomen and cervix during labor. However, since scientists could not affix the electrodes to the fetus's scalp, continuous recordings were difficult to obtain. With the invention of suction cup electrodes, doctors could get continuous recordings from the same brain location during labor and delivery. From 1955 to 1976, many scientific groups made EEG recordings from electrodes placed on the maternal abdomen, or placed on the cervix using a speculum, and techniques continued improving. In the 1980s,

functional MRI Functional magnetic resonance imaging or functional MRI (fMRI) measures brain activity by detecting changes associated with blood flow. This technique relies on the fact that cerebral blood flow and neuronal activation are coupled. When an area o ...

magnetoencephalography Magnetoencephalography (MEG) is a functional neuroimaging technique for mapping brain activity by recording magnetic fields produced by electrical currents occurring naturally in the brain, using very sensitive magnetometers. Arrays of SQUIDs (su ...

became the primary research tools for the prenatal study of human brain development; however, fetal EEG prevailed in clinical settings for determining sleep states in the unborn, or fetal distress.

Fetal EEG patterns

Healthy newborns display two patterns of electrical activity described as "discontinuous" and "trace alternant" activity. "Discontinuous" electrical activity describes sharp bursts of electrical activity followed by low frequency waves; "trace alternant" electrical activity describes sharp bursts followed by short high amplitude intervals. Trace alternant activity has been correlated with quiet sleep. In the third trimester, normally developing fetuses show discontinuous and trace alternant patterns resembling those measured from normal newborns. Interestingly, as preterm infants advance in

gestational age In obstetrics, gestational age is a measure of the age of a pregnancy which is taken from the beginning of the woman's last menstrual period (LMP), or the corresponding age of the gestation as estimated by a more accurate method if available. Suc ...

, the more likely they are to display low frequency waves and trace alternant activity; discontinuous activity becomes more rare the older a preterm infant is born.

Techniques

Recordings from surgical termination of pregnancy

Between 1955 and 1961, Winslow Borkowski and Richard Bernstine, doctors at Jefferson Medical College Hospital, temporarily preserved tiny unborn fetuses removed during ectopic pregnancies and recorded from their brains. The team used needle electrodes to record brain activity at 3 millimeters and 1 centimeter below the brain surface. These electrodes penetrated the cranial tissue, which solves the problem of electrical interference from nearby muscles. The youngest fetus that Borkowski and Bernstine studied was between 43 and 45 days post-conception – only 16mm long. At 45 days after conception, the brain is bent forward and is almost as large as the entire body of the fetus, allowing for these deep recordings. The 45-day-old fetus's electrical signals resembled the "discontinuous" patterns observed in healthy newborns, premature infants, and fetuses in the last trimester of pregnancy. The doctors also observed patterns that resembled "

sleep spindle Sleep spindles are bursts of neural oscillatory activity that are generated by interplay of the thalamic reticular nucleus (TRN) and other thalamic nuclei during stage 2 NREM sleep in a frequency range of ~11 to 16 Hz (usually 12–14 Hz) ...

s" in adults. The scientists continued recording until they consistently observed patterns of

brain death Brain death is the permanent, irreversible, and complete loss of brain function which may include cessation of involuntary activity necessary to sustain life. It differs from persistent vegetative state, in which the person is alive and some aut ...

, since the fetuses could not survive outside the uterus.

Recordings from the maternal abdomen

To record the most accurate brain signals, scientists try to minimize the distance between the recording electrode and fetal

cortex Cortex or cortical may refer to: Biology * Cortex (anatomy), the outermost layer of an organ ** Cerebral cortex, the outer layer of the vertebrate cerebrum, part of which is the ''forebrain'' *** Motor cortex, the regions of the cerebral cortex i ...

by using an ultrasound to get the electrodes on the maternal abdomen as close to the fetal head as possible. The original fetal EEGs came from recordings through the maternal abdomen. However, electrical activity from the mother's heart, abdominal and uterine muscles all create artifacts in the fetal EEG recording. An artifact is electrical activity detected by the EEG that comes a source that the scientist does not want to measure. Muscles create electrical activity in the range of 20–100 Hz, and the uterine wall creates slow-wave activity and fast-wave activity related to the intrauterine pressure. Furthermore, the maternal heartbeat dominates recordings in every electrode and must be filtered out with computer algorithms. Recordings from the maternal abdomen or cervix have less than 5 cm of tissue between the maternal skin and the fetal

. A typical human slow wave is 100-500 mV in amplitude, but the voltage strength declines with the square of the distance between the neural activity and the recording electrode. Even with modern techniques, scientists still have difficulties detecting brain activity recorded from outside the womb.

Recordings from the scalp during labor

Doctors can safely record EEG from the fetus without interference from the maternal heartbeat and uterine muscles by attaching suction-cup electrodes to the scalp of the unborn during labor and delivery. These electrodes are held in place using suction and can be applied as soon as a mother's amniotic membranes break and her cervix is dilated to 3 cm. The advantage of suction-cup electrodes are that they provide continuous recordings from the same fetal brain location, unlike electrodes on the maternal abdomen. Both before and during labor, trace alternant patterns can be observed in the fetal EEG. The trace alternant pattern has been correlated with quiet sleep in newborn babies. During active REM sleep, EEG recordings from the fetus mostly show low voltage fast activity. During quiet non-REM sleep, EEG recordings from the fetus mostly show high voltage slow activity. Amazingly, the fetus spends most of the time of his labor and delivery asleep.

References

{{Reflist Electroencephalography Tests during pregnancy