The most commonly used brain-scanning tool is fMRI, which provides relatively high spatial resolution of one to three
millimeters (not high enough to image individual neurons) but low temporal (time) resolution of a few seconds. Recent
generations of fMRI technology provide time resolution of about one second, or a tenth of a second for a thin brain
slice.
Another
commonly used technique is MEG, which measures weak magnetic fields outside the skull, produced
principally by the pyramidal neurons of the cortex. MEG is capable of rapid (one millisecond) temporal resolution but
only very crude spatial resolution, about one centimeter.
Fritz Sommer, a principal investigator at Redwood Neuroscience Institute, is developing methods of combining
fMRI and MEG to improve the spatiotemporal precision of the measurements. Other recent advances have
demonstrated fMRI techniques capable of mapping regions called columnar
and laminar structures, which are only a
fraction of a millimeter wide, and of detecting tasks that take place in tens of milliseconds.
32
fMRI and a related scanning technique using positrons called positron-emission tomography (PET) both gauge
neuronal activity through indirect means. PET measures regional cerebral blood flow (rCBF), while tMRI measures
blood-oxygen levels.
33
Although the relationship of these blood-flow amounts to neural activity is the subject of some
controversy, the consensus is that they reflect local synaptic activity, not the spiking of neurons. The relationship of
neural activity to blood flow was first articulated in the late nineteenth century.
34
A
limitation of tMRI, however, is
that the relationship of blood flow to synaptic activity is not direct: a variety of metabolic mechanisms affect the
relationship between the two phenomena.
However, both PET and tMRI are believed to be most reliable for measuring relative changes in brain state. The
primary method they use is the "subtraction paradigm," which can show regions that are most active during particular
tasks.
35
This procedure involves subtracting data produced by a scan when the subject is not performing an activity
from data produced while the subject is performing a specified mental activity. The difference represents the change in
brain state.
An invasive technique that provides high spatial and temporal resolution is "optical imaging," which involves
removing part of the skull, staining the living brain tissue with a dye that fluoresces upon neural activity, and then
imaging the emitted light with a digital camera. Since optical
imaging requires surgery, it has been used mainly in
animal, particularly mouse, experiments.
Another approach to identifying brain functionality in different regions is transcranial magnetic stimulation
(TMS), which involves applying a strong-pulsed magnetic field from outside the skull, using a magnetic coil precisely
positioned over the head. By either stimulating or inducing a "virtual lesion" of (by temporarily disabling)
small
regions of the brain, skills can be diminished or enhanced.
36
TMS can also be used to study the relationship of different
areas of the brain on specific tasks and can even induce sensations of mystical experiences.
37
Brain scientist Allan
Snyder has reported that about 40 percent of his test subjects hooked up to TMS display significant new skills, many
of which are remarkable, such as drawing abilities.
38
If we have the option of destroying
the brain that we are scanning, dramatically higher spatial resolution becomes
possible. Scanning a frozen brain is feasible today, though not yet at sufficient speed or bandwidth to fully map all
interconnections. But again, in accordance with the law of accelerating returns, this potential
is growing exponentially,
as are all other facets of brain scanning.
Carnegie Mellon University's Andreas Nowatzyk is scanning the nervous system of the brain and body of a mouse
with a resolution of less than two hundred nanometers, which is approaching the resolution needed for full reverse
engineering. Another destructive scanner called the "Brain Tissue Scanner" developed at the Brain Networks
Laboratory at Texas A&M University is able to scan an entire mouse brain at a resolution of 250 nanometers in one
month, using slices.
39
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