11.2018 | THE SCIENTIST 27
MODUS OPERANDI
© GEORGE RETSECK
AT A GLANCE
T
he eye presents a paradox to experimental neuroscientists. On one
hand, it’s accessible, its function is well understood, and its inputs
can be precisely controlled, says neurobiologist William Newsome
of Stanford University. “On the other hand, it is very diffi cult to record
its electrical signals while visual behavior is actually taking place.” That’s
because the hardware for electrical recordings—rigid electrodes—aren’t
compatible with small, spherical, constantly moving rodent eyes.
To record retinal cell activity, researchers tend to remove the eye from
the animal, dissect the retina, and lay it fl at on an array of microelectrodes.
While such preparations can continue to respond to light for a matter
of hours, new mesh electrodes, developed by nanotechnologist Charles
Lieber of Harvard University and colleagues, can remain inside a living ani-
mal’s eye, recording the same cells for several weeks.
Measuring 1.5 mm by 0.8 mm and containing 16 individual elec-
trodes, the polymer and metal meshes are injected, one per mouse eye,
toward the rear of the vitreous body, where they unfurl to coat the retina.
Tiny wires connected to the meshes extend out of the corner of the ani-
mals’ eyes for attachment to an external recording device. The animals are
restrained, their heads immobilized, for sessions of light stimulation and
recording, but they are free to move and behave normally between ses-
sions. Remarkably, the meshes have little eff ect on vision, and after a few
weeks they detach from the retina.
Long-term, in vivo recording ability opens a range of new research
avenues, says Lieber, whose team has used the meshes to measure
changes in retinal ganglion cell activity over the course of several day/
night cycles.
It’s a “fantastic” innovation, says Marla Feller of the University of Cal-
ifornia, Berkeley, who studies the organization of retinal neural circuits
during development but was not involved in the research. “It was exciting
to see how successful it was at being able to record from the same cells
over multiple days.” Not only might the method be useful for following
individual cells through retinal maturation, she says, but also for examining
which cells die and which survive during eye diseases such as glaucoma.
(Science, 360:1447–51, 2018) g
Ultrafl exible mesh electrodes monitor intact, functioning eyes
of awake animals.
BY RUTH WILLIAMS
Retina Recordings Reinvented
MULTI-CELL RETINAL
RECORDINGS
Ex vivo
In vivo
METHOD
The eye is removed, and the
retina is dissected and laid fl at
on an array of microelectrodes.
Mesh electrode is injected into the
eye of an anesthetized mouse.
VIABLE
RECORDING TIME
8 to 12 hours for mouse
retinas
Several weeks
NO. OF SIMULTANEOUSLY
RECORDING ELECTRODES
Approximately 500
16 so far but could
theoretically be more
INVASIVE?
Highly. Animal
sacrifi ced
Minimally.
Visual function
negligibly
aff ected
Tiny wires connected to the meshes extend out of the corner of the ani- (Science, 360:1447–51, 2018) g
AT A GLANCE
1 ^2
Light
stimulation
ENVISIONED: 1 A mesh of multiple electrodes is injected toward the rear of the mouse eye, where it unfurls onto
the retina. 2 Wires connected to the mesh extend from the corner of the animal’s eye to enable electrical recording
of retinal activity in response to stimulation, such as bars of light shown on a screen.