Innovative machine learning method anticipates
neurocognitive changes, similar to predictive text-entry for cell
phones, Internet search engines
By Jennifer Marcus
At UCLA's Laboratory of Integrative Neuroimaging Technology,
researchers use functional MRI brain scans to observe brain signal
changes that take place during mental activity. They then employ
computerized machine learning (ML) methods to study these patterns and
identify the cognitive state — or sometimes the thought process — of
human subjects. The technique is called "brain reading" or "brain
decoding."
In a new study, the UCLA research team describes several crucial
advances in this field, using fMRI and machine learning methods to
perform "brain reading" on smokers experiencing nicotine cravings.
The research, presented last week at the Neural Information
Processing Systems' Machine Learning and Interpretation in Neuroimaging
workshop in Spain, was funded by the National Institute on Drug Abuse,
which is interested in using these method to help people control drug
cravings.
In this study on addiction and cravings, the team classified data
taken from cigarette smokers who were scanned while watching videos
meant to induce nicotine cravings. The aim was to understand in detail
which regions of the brain and which neural networks are responsible for
resisting nicotine addiction specifically, and cravings in general,
said Dr. Ariana Anderson, a postdoctoral fellow in the Integrative
Neuroimaging Technology lab and the study's lead author.
"We are interested in exploring the relationships between structure
and function in the human brain, particularly as related to
higher-level cognition, such as mental imagery," Anderson said. "The lab
is engaged in the active exploration of modern data-analysis
approaches, such as machine learning, with special attention to methods
that reveal systems-level neural organization."
For the study, smokers sometimes watched videos meant to induce
cravings, sometimes watched "neutral" videos and at sometimes watched no
video at all. They were instructed to attempt to fight nicotine
cravings when they arose.
The data from fMRI scans taken of the study participants was then
analyzed. Traditional machine learning methods were augmented by Markov
processes, which use past history to predict future states. By
measuring the brain networks active over time during the scans, the
resulting machine learning algorithms were able to anticipate changes
in subjects' underlying neurocognitive structure, predicting with a
high degree of accuracy (90 percent for some of the models tested) what
they were watching and, as far as cravings were concerned, how they
were reacting to what they viewed.
"We detected whether people were watching and resisting cravings,
indulging in them, or watching videos that were unrelated to smoking or
cravings," said Anderson, who completed her Ph.D. in statistics at
UCLA. "Essentially, we were predicting and detecting what kind of
videos people were watching and whether they were resisting their
cravings."
In essence, the algorithm was able to complete or "predict" the
subjects' mental states and thought processes in much the same way that
Internet search engines or texting programs on cell phones anticipate
and complete a sentence or request before the user is finished typing.
And this machine learning method based on Markov processes demonstrated a
large improvement in accuracy over traditional approaches, the
researchers said.
Machine learning methods, in general, create a "decision layer" —
essentially a boundary separating the different classes one needs to
distinguish. For example, values on one side of the boundary might
indicate that a subject believes various test statements and, on the
other, that a subject disbelieves these statements. Researchers have
found they can detect these believe–disbelieve differences with high
accuracy, in effect creating a lie detector. An innovation described in
the new study is a means of making these boundaries interpretable by
neuroscientists, rather than an often obscure boundary created by more
traditional methods, like support vector machine learning.
"In our study, these boundaries are designed to reflect the
contributed activity of a variety of brain sub-systems or networks whose
functions are identifiable — for example, a visual network, an
emotional-regulation network or a conflict-monitoring network," said
study co-author Mark S. Cohen, a professor of neurology, psychiatry and
biobehavioral sciences at UCLA's Staglin Center for Cognitive Neuroscience and a researcher at the California NanoSystems Institute at UCLA.
"By projecting our problem of isolating specific networks
associated with cravings into the domain of neurology, the technique
does more than classify brain states — it actually helps us to better
understand the way the brain resists cravings," added Cohen, who also
directs UCLA's Neuroengineering Training Program.
Remarkably, by placing this problem into neurological terms, the
decoding process becomes significantly more reliable and accurate, the
researchers said. This is especially significant, they said, because it
is unusual to use prior outcomes and states in order to inform the
machine learning algorithms, and it is particularly challenging in the
brain because so much is unknown about how the brain works.
Machine learning typically involves two steps: a "training phase"
in which the computer evaluates a set of known outcomes — say, a bunch
of trials in which a subject indicated belief or disbelief — and a
second, "prediction" phase in which the computer builds a boundary based
on that knowledge.
In future research, the neuroscientists said, they will be using
these machine learning methods in a biofeedback context, showing
subjects real-time brain readouts to let them know when they are
experiencing cravings and how intense those cravings are, in the hopes
of training them to control and suppress those cravings.
But since this clearly changes the process and cognitive state for
the subject, the researchers said, they may face special challenges in
trying to decode a "moving target" and in separating the "training"
phase from the "prediction" phase.
The California NanoSystems Institute
is an integrated research facility located at UCLA and UC Santa
Barbara. Its mission is to foster interdisciplinary collaborations in
nanoscience and nanotechnology; to train a new generation of scientists,
educators and technology leaders; to generate partnerships with
industry; and to contribute to the economic development and the social
well-being of California, the United States and the world. The CNSI was
established in 2000 with $100 million from the state of California. The
total amount of research funding in nanoscience and nanotechnology
awarded to CNSI members has risen to over $900 million. UCLA CNSI
members are drawn from UCLA's College of Letters and Science, the David
Geffen School of Medicine, the School of Dentistry, the School of
Public Health and the Henry Samueli School of Engineering and Applied
Science. They are engaged in measuring, modifying and manipulating
atoms and molecules — the building blocks of our world. Their work is
carried out in an integrated laboratory environment. This dynamic
research setting has enhanced understanding of phenomena at the
nanoscale and promises to produce important discoveries in health,
energy, the environment and information technology.
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