Diagnostic Tests
UNDERSTANDING BRAIN INJURY DIAGNOSTIC TESTS
Midline Shift - Any mass in or outside the brain - a hematoma, edema, tumor, hygroma -- can shove the brain to one side. When severe, the shift can involve important midline structures. The brain should return to its normal position after the cause of the shift is identified and corrected.From the time of a patients arrival to the emergency room through follow-up treatment, a wide variety of complicated brain tests can be done to help determine if a brain injury may have occurred
NEUROLOGIC TESTS
There are two types of neurologic tests: those that examine the structure of the brain and those that examine the function of the brain. The CAT scan and MRI look at the structure of the brain. The electroencephalogram (EEG), SPECT scan, PET scan, and evoked studies examine the function of the brain.
MRI and CAT Scans
The MRI and CAT scan slice the brain radiographically into slabs. The MRI does this with magnetic fields; the CAT scan uses x-rays. The MRI provides more detail than the CAT scan. Hence, brain damage seen on an MRI - as small as 1-2mm in size -- may escape detection by a CAT scan. The CAT scan is superior to the MRI in detecting fresh blood in and around the brain, while the MRI is better at detecting the remnants of old hemorrhaged blood, called hemosiderin. CAT scans are often repeated to insure that a brain injury is not becoming more extensive, usually in the early stages of ER treatment.
Being so very sensitive, the MRI commonly detects clinically silent (asymptomatic) "brain damage" in the normal population. For example, as we age it is common for myelin in the white matter to degenerate. (Myelin is a jacket of insulation around axons to help them conduct their electrical discharges quickly down the axon.) An MRI can detect this myelin degeneration as white matter hyperintensities. The MRI is also sensitive to cerebral atrophy (shrinkage), another normal phenomenon as we age. Excessive numbers of white matter hyperintensities or excessive atrophy signal a possible neurologic illness, or injury.
MRA (Magnetic Resonance Angiography)
MRA, or magnetic resonance angiography, is a means of visualizing the carotid
and vertebral arterial systems in the neck and brain without having to inject
contrast into the bloodstream. The resolution is not as good as with
conventional arteriography, but the patient is spared the risks of
catheterization and allergic reactions to the dye. (In conventional
arteriography, a catheter is threaded from the femoral artery in the groin
backward up the aorta into a carotid or vertebral artery in the neck, and then
dye is injected up the catheter. As the dye flows into the brain, x-rays are
taken of the cerebral vasculature.)
EEG (Electroencephalogram)
Monitors the brain's electrical activity by means of wires attached to the
patient's scalp. These wires act like an antenna to record the brain's
electrical activity. Normally, the resting brain emits signals at a frequency of
8 to 13 cycles per second (cps), called alpha activity, which is best seen in
the occipital regions. Anything faster than 8-13cps is called beta activity.
Slower rhythms include theta activity (6-7 cps) and delta activity (3-5 cps).
Theta and delta activity occur in the normal brain as the patient descends into
sleep. If the patient is awake, any slowing of electrical activity in a focal
area of the brain may indicate a lesion there. Similarly, widespread slowing
indicates a widespread disturbance of brain. function, "Spiking" (sharp
waves of electrical activity) discharges indicate an irritable area of cerebral
cortex. If allowed to spread, the spikes can produce a seizure.
It is not uncommon for an EEG to be normal between seizures in patients with
bonafide seizures. During a seizure, however, the EEG is almost invariably
abnormal. Conversely, 15% of the population shows mild abnormalities on EEG,
representing old head trauma, old strokes, migraine, viral infections, and most
of the time for unknown reasons.
Quantitative EEG (QEEG, BEAM, Brain Mapping)
This test is performed in a way similar to EEG. Brain wave activity varies
throughout the day depending on the state of alertness. Each area of the brain
normally spends a characteristic amount of time in alpha, beta, theta, and delta
activity. Brain mapping computers are now capable of creating a map of the
brain's electrical activity depicting how long each area of the brain spends in
each of the basic rhythms. By comparing the patient's map with that of a control
population, it is possible to localize areas of focal slowing of electrical
activity. Alone, a QEEG is insufficient to diagnose brain damage but in
conjunction with other neurologic tests, QEEG can be confirmatory.
PET Scan (Positron Emission Tomography)
PET scanning (positron emission tomography) is based on the fact that the brain
uses glucose for energy. By labeling a glucose molecule with a radioactive
"tag," and then inhaling radioactive glucose and placing the patient's head
under a large geiger counter, one can identify abnormal areas of the brain that
are underutilizing glucose.
SPECT Scan (Single Photon Emission Computed Tomography)
SPECT scanning (single photon emission computed tomography) is similar to PET
scanning in that a radioactive chemical is administered intravenously to the
patient, but the radioactive chemical remains in the bloodstream and does not
enter the brain. As a result, the SPECT scan maps the brain's vascular supply.
Because damaged brain tissue normally shuts down its own blood supply, focal
vascular defects on a SPECT scan are circumstantial evidence of brain damage.
The advantage of a SPECT scan over a PET scan is its ready availability and
relatively cheap cost. Recent studies have demonstrated abnormal SPECT scans
after head trauma when the CAT and MRI were normal, suggesting that the SPECT
scan is more sensitive to brain injury then either CT or MRI scans. Because the
radioactive chemicals used in SPECT and PET scans are carried to all parts of
the body by vascular tree, SPECT scans and PET scans are used judiciously in
patients of reproductive age.
MRA (Magnetic Resonance Angiography)
MRA, or magnetic resonance angiography, is a means of visualizing the carotid
and vertebral arterial systems in the neck and brain without having to inject
contrast into the bloodstream. The resolution is not as good as with
conventional arteriography, but the patient is spared the risks of
catheterization and allergic reactions to the dye. (In conventional
arteriography, a catheter is threaded from the femoral artery in the groin
backward up the aorta into a carotid or vertebral artery in the neck, and then
dye is injected up the catheter. As the dye flows into the brain, x-rays are
taken of the cerebral vasculature.)
Evoked Potentials
Evoked studies take advantage of the fact that each time a sensory system of the
body -- vision, hearing, touch -- is stimulated, an electrical signal is
generated in the brain. These electrical signals can be detected with electrical
wires on the scalp. Thus, visual evoked recordings (VER) are recorded over the
occipital lobes; brainstem auditory evoked recordings (BAER) over the temporal
lobes; and somatosensory potentials (SSEP) over the parietal lobes.
Lumbar Puncture
A lumbar puncture (spinal tap - not the band) is used to analyze cerebrospinal
fluid. An analysis of the fluid can help tell doctors, for example, if there is
any bleeding in the brain and spinal cord areas.
Magnetic Resonance Spectroscopy (MRS)
This is an exciting new tool, used in conjunction with MRI, that detects the
intra-cellular relationship of brain metabolites. Studies show that in an
injured brain, the relationship between the amount of certain compounds in the
brain changes in predictable ways, which can be picked up, non-invasively, by
MRS.