CONTROLLING GENES WITH YOUR THOUGHTS
It sounds like something from the scene in Star Wars where Master Yoda
instructs the young Luke Skywalker to use the force to release his stricken
X-Wing from the swamp: Marc Folcher and other researchers from the group led by
Martin Fussenegger, Professor of Biotechnology and Bioengineering at the
Department of Biosystems (D-BSSE) in Basel, have developed a novel gene
regulation method that enables thought-specific brainwaves to control the
conversion of genes into proteins -- called gene expression in technical terms.
"For the first
time, we have been able to tap into human brainwaves, transfer them wirelessly
to a gene network and regulate the expression of a gene depending on the type
of thought. Being able to control gene expression via the power of thought is a
dream that we've been chasing for over a decade," says Fussenegger.
A source of
inspiration for the new thought-controlled gene regulation system was the game
Mindflex, where the player wears a special headset with a sensor on the
forehead that records brainwaves. The registered electroencephalogram (EEG) is
then transferred into the playing environment. The EEG controls a fan that
enables a small ball to be thought-guided through an obstacle course.
Wireless Transmission
to Implant
The system, which the
Basel-based bioengineers recently presented in the journalNature Communications,
also makes use of an EEG headset. The recorded brainwaves are analysed and
wirelessly transmitted via Bluetooth to a controller, which in turn controls a
field generator that generates an electromagnetic field; this supplies an
implant with an induction current.
A light then literally
goes on in the implant: an integrated LED lamp that emits light in the
near-infrared range turns on and illuminates a culture chamber containing
genetically modified cells. When the near-infrared light illuminates the cells,
they start to produce the desired protein.
Thoughts Control
Protein Quantity
The implant was
initially tested in cell cultures and mice, and controlled by the thoughts of
various test subjects. The researchers used SEAP for the tests, an easy-to-detect
human model protein which diffuses from the culture chamber of the implant into
the mouse's bloodstream.
To regulate the
quantity of released protein, the test subjects were categorised according to
three states of mind: bio-feedback, meditation and concentration. Test subjects
who played Minecraft on the computer, i.e. who were concentrating, induced
average SEAP values in the bloodstream of the mice. When completely relaxed
(meditation), the researchers recorded very high SEAP values in the test animals.
For bio-feedback, the test subjects observed the LED light of the implant in
the body of the mouse and were able to consciously switch the LED light on or
off via the visual feedback. This in turn was reflected by the varying amounts
of SEAP in the bloodstream of the mice.
New Light-sensitive
Gene Construct
"Controlling
genes in this way is completely new and is unique in its simplicity,"
explains Fussenegger. The light-sensitive optogenetic module that reacts to
near-infrared light is a particular advancement. The light shines on a modified
light-sensitive protein within the gene-modified cells and triggers an
artificial signal cascade, resulting in the production of SEAP. Near-infrared
light was used because it is generally not harmful to human cells, can
penetrate deep into the tissue and enables the function of the implant to be
visually tracked.
The system functions
efficiently and effectively in the human-cell culture and human-mouse system.
Fussenegger hopes that a thought-controlled implant could one day help to
combat neurological diseases, such as chronic headaches, back pain and
epilepsy, by detecting specific brainwaves at an early stage and triggering and
controlling the creation of certain agents in the implant at exactly the right
time.
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