Surgery – Diagnostic testing – Detecting brain electric signal
Reexamination Certificate
2000-11-20
2003-04-29
Doerrler, William C. (Department: 3744)
Surgery
Diagnostic testing
Detecting brain electric signal
C600S559000, C607S045000
Reexamination Certificate
active
06556861
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to medical obstetric procedures and devices and more particularly to the non-invasive monitoring of the human fetus while in the mother's uterus.
BACKGROUND OF THE INVENTION
At the present time it is conventional, in medical practice, to ascertain the status and health of a human fetus by ultrasound. Typically a pregnant female may undergo 1 to 4 ultrasound examinations during her pregnancy.
In addition, the heart of the fetus will be detected and monitored using a stethoscope. It is also conventional to monitor the heartbeat of a neonate (newly born infant) during and immediately after childbirth, using a stethoscope or a more sophisticated analysis instrument.
After childbirth, the status of pre-term neonates may be ascertained using EEG (electroencephalography).
An EEG (electroencephalograph) procedure measures neurophysiological activity by measuring the intensity and pattern of electrical signals generated by the brain. Undulations in the recorded electrical signals are called brain waves. The entire record of electrical rhythms and other electrical activity (ongoing background signals and event related transients) of the brain is an EEG. EEGs are widely used to assist in the diagnosis, in children and adults, of epilepsy, brain tumors, physiological disorders and other brain abnormalities. Because the electrical waves produced by an injured or abnormal brain will differ in predictable ways from waves produced by a normal brain, an EEG exam should disclose and help diagnose brain abnormalities and injuries.
Although EEG based brain monitoring of patients has been performed for over 70 years, it is only recently, with the advent of computers and new analysis techniques, that medical professionals have begun to recognize the benefits of EEGs as a broad based diagnostic tool. This should be contrasted with the field of cardiac monitoring in which medical professionals have long been aware of the benefits of monitoring, and have integrated electrocardiogram (“ECG”) procedures into both preventive and diagnostic health care. As a result, medical device and instrument companies have concentrated on, and provided improved technology for, the fetal cardiac monitoring market. However, EEG technology has not been applied, in general medical usage, to determine the health or status of a fetus.
It has been generally considered that meaningful data could not be gathered non-invasively from the brain of a fetus.
The fetus lies within the uterus surrounded by amniotic fluid. The uterus is within the abdominal cavity of the mother and it is surrounded by layers of skin, muscle and blood. The thickness of the uterine wall and the amount of amniotic fluid vary greatly among different mothers. Consequently, it is difficult to believe that meaningful brain wave signals could be obtained from the fetal brain through all those layers of material. The adult brain produces brain waves in the microvolt range and the fetal brain's brain waves are weaker than those of a child or adult.
A series of scientific articles have been written about the EEG of neonates. Specifically, tests have been conducted on pre-term at risk neonates (newly born babies) using auditory brain stem auditory evoked response (BAERs). In this BAER procedure a sound (auditory) is transmitted to the neonate. One, or preferably 3 or more, electrodes are placed on the baby's scalp and the baby's brain waves are detected as the neuronal responses propagate along the auditory pathways from the auditory nerve to the thalamus. By averaging a series of such responses to the sound, it is possible to identify components of the response which are reproducible, the “evoked responses” of the neonate's brain are synchronous with the sounds. The “evoked response” is in a time-locked relationship to the auditory stimuli (Taylor 1996; Pasman 1997; Singh 1998; Mercuri 1994; Yasuhara 1986; Cycowisz 1988; Murray 1988; Majnemer 1988; Cox 1992 and Hayakawa). The articles are cited by lead author and date and the patents by patent numbers. They are listed below and are incorporated by reference herein.
Several articles have reported selective vulnerability of auditory nuclei in the pre-term period, especially between 28 and 40 weeks gestational age (GA) (Griffiths, Leech). There have been several reports on the clinical utility of BAERs in newborn infants, particularly with full term infants having asphyxia or hyperbilirubemia or at risk for hearing loss. Neonatal BAER abnormalities have been found in infants with perinatal (at the time of birth) complications (Yashuhara, Cycowisz, Murray). Prognostic value of term BAER assessments has been suggested in studies of later language skills or neurodevelopmental outcome in high risk neonates (Karmel, Majnemer) with low birth weight (Cox) or with neurological signs and demonstrable brain anomalies (Salamy). While all of these reports related to full-term infants, it seems reasonable to propose that the BAER abnormalities existed before delivery and that intrauterine measurements might have provided an early warning of such abnormalities.
In Maynard U.S. Pat. No. 4,308,873 it is suggested that the ongoing EEG of a fetus may be detected by separating the EEG signals from electrocardiograph (ECG) signals. Electrodes are placed directly on the scalp of the fetus during labor (after separation from the uterus).
SUMMARY OF THE INVENTION
In accordance with the present invention, the brain waves of the fetus are non-invasively detected and analyzed in a “Fetal Brainstem Monitor” (FBM). This is a very difficult procedure and requires highly sophisticated techniques and sensitive equipment. However, the evaluation of fetal brain waves may permit the assessment of conditions which may lead to abnormal or delayed intrauterine development and provide a standard for normal fetal development.
It is important, in order to detect such faint fetal brain waves, that they be timed in response to a stimuli. The preferred stimuli are auditory. Preferably a sound generator, for example of click sounds, is placed on the belly of a pregnant woman. The click sounds are transmitted through her skin, muscles, womb and amniotic fluid, to the ears of the fetus. Such transmission of sound is possible because sound travels well through fluids.
One, or more, detecting biosensor electrodes are removably placed on the skin of the mother, proximate her womb. Preferably the electrode is a disposable biosensor which uses an adhesive hydrogel material. It does not require skin preparation or collodion and should provide a low electrical impedance (under 5000 ohms).
The biosensor electrode detects the faint micro-volt level brain waves of the fetus. Because of the faintness of the signals, the amplification which is required is much greater than with conventional EEG amplifiers. In addition, the amplifier should be low in internal noise. Preferably the amplifier connected to the biosensor electrode should have a gain of 200,000 and a noise level of less than 1 microvolt.
The analysis of the EEG is performed using advanced filtering techniques and algorithms relating to Quantitative EEG (“QEEG”). These techniques are critical to obtaining meaningful data from the faint electrical brain waves of the fetus. For example, the fetus in the embryonic sac is in almost constant movement, which is considered a muscle artifact and generates noise which may drown out the brain wave signals.
In addition to noise generated by movement of the fetus, the maternal environment produces other noises. These include the heartbeats of the fetus and the mother, movements of the mother (muscle artifacts) such as breathing and eye blinking and the mother's brain waves, including the mother's brain wave response to the auditory stimuli.
The following are some of the quantitative approaches to improve the signal-to-noise ratio in this difficult EEG environment.
1. The BAER (Brainstem Auditory Evoked Potentials) are time-locked to the auditory stimuli. The responses are in the interva
Doerrler William C.
New York University
Pay Kaplun & Marcin LLP
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