Frontiers in Artificial Intelligence,
Год журнала:
2023,
Номер
6
Опубликована: Фев. 28, 2023
The
brain
is
arguably
the
most
powerful
computation
system
known.
It
extremely
efficient
in
processing
large
amounts
of
information
and
can
discern
signals
from
noise,
adapt,
filter
faulty
all
while
running
on
only
20
watts
power.
human
brain's
efficiency,
progressive
learning,
plasticity
are
unmatched
by
any
computer
system.
Recent
advances
stem
cell
technology
have
elevated
field
culture
to
higher
levels
complexity,
such
as
development
three-dimensional
(3D)
organoids
that
recapitulate
functionality
better
than
traditional
monolayer
systems.
Organoid
Intelligence
(OI)
aims
harness
innate
biological
capabilities
for
biocomputing
synthetic
intelligence
interfacing
them
with
technology.
With
latest
strides
technology,
bioengineering,
machine
we
explore
ability
compute,
store
given
(input),
execute
a
task
(output),
study
how
this
affects
structural
functional
connections
themselves.
Furthermore,
understanding
learning
generates
changes
patterns
connectivity
shed
light
early
stages
cognition
brain.
Investigating
these
concepts
an
enormous,
multidisciplinary
endeavor
necessitates
engagement
both
scientific
community
public.
Thus,
Feb
22–24
2022,
Johns
Hopkins
University
held
first
Workshop
form
OI
Community
lay
out
groundwork
establishment
new
discipline.
potential
revolutionize
computing,
neurological
research,
drug
was
discussed,
along
vision
roadmap
its
over
coming
decade.
ACS Nano,
Год журнала:
2023,
Номер
17(6), С. 5211 - 5295
Опубликована: Март 9, 2023
Humans
rely
increasingly
on
sensors
to
address
grand
challenges
and
improve
quality
of
life
in
the
era
digitalization
big
data.
For
ubiquitous
sensing,
flexible
are
developed
overcome
limitations
conventional
rigid
counterparts.
Despite
rapid
advancement
bench-side
research
over
last
decade,
market
adoption
remains
limited.
To
ease
expedite
their
deployment,
here,
we
identify
bottlenecks
hindering
maturation
propose
promising
solutions.
We
first
analyze
achieving
satisfactory
sensing
performance
for
real-world
applications
then
summarize
issues
compatible
sensor-biology
interfaces,
followed
by
brief
discussions
powering
connecting
sensor
networks.
Issues
en
route
commercialization
sustainable
growth
sector
also
analyzed,
highlighting
environmental
concerns
emphasizing
nontechnical
such
as
business,
regulatory,
ethical
considerations.
Additionally,
look
at
future
intelligent
sensors.
In
proposing
a
comprehensive
roadmap,
hope
steer
efforts
towards
common
goals
guide
coordinated
development
strategies
from
disparate
communities.
Through
collaborative
efforts,
scientific
breakthroughs
can
be
made
sooner
capitalized
betterment
humanity.
Recent
advances
in
human
stem
cell-derived
brain
organoids
promise
to
replicate
critical
molecular
and
cellular
aspects
of
learning
memory
possibly
cognition
vitro
.
Coining
the
term
“organoid
intelligence”
(OI)
encompass
these
developments,
we
present
a
collaborative
program
implement
vision
multidisciplinary
field
OI.
This
aims
establish
OI
as
form
genuine
biological
computing
that
harnesses
using
scientific
bioengineering
an
ethically
responsible
manner.
Standardized,
3D,
myelinated
can
now
be
produced
with
high
cell
density
enriched
levels
glial
cells
gene
expression
for
learning.
Integrated
microfluidic
perfusion
systems
support
scalable
durable
culturing,
spatiotemporal
chemical
signaling.
Novel
3D
microelectrode
arrays
permit
high-resolution
electrophysiological
signaling
recording
explore
capacity
recapitulate
mechanisms
formation
and,
ultimately,
their
computational
potential.
Technologies
could
enable
novel
biocomputing
models
via
stimulus-response
training
organoid-computer
interfaces
are
development.
We
envisage
complex,
networked
whereby
connected
real-world
sensors
output
devices,
ultimately
each
other
sensory
organ
(e.g.
retinal
organoids),
trained
biofeedback,
big-data
warehousing,
machine
methods.
In
parallel,
emphasize
embedded
ethics
approach
analyze
ethical
raised
by
research
iterative,
manner
involving
all
relevant
stakeholders.
The
many
possible
applications
this
urge
strategic
development
discipline.
anticipate
OI-based
allow
faster
decision-making,
continuous
during
tasks,
greater
energy
data
efficiency.
Furthermore,
“intelligence-in-a-dish”
help
elucidate
pathophysiology
devastating
developmental
degenerative
diseases
(such
dementia),
potentially
aiding
identification
therapeutic
approaches
address
major
global
unmet
needs.
Nature Communications,
Год журнала:
2022,
Номер
13(1)
Опубликована: Июль 29, 2022
Human
brain
organoids
replicate
much
of
the
cellular
diversity
and
developmental
anatomy
human
brain.
However,
physiology
neuronal
circuits
within
remains
under-explored.
With
high-density
CMOS
microelectrode
arrays
shank
electrodes,
we
captured
spontaneous
extracellular
activity
from
derived
induced
pluripotent
stem
cells.
We
inferred
functional
connectivity
spike
timing,
revealing
a
large
number
weak
connections
skeleton
significantly
fewer
strong
connections.
A
benzodiazepine
increased
uniformity
firing
patterns
decreased
relative
fraction
weakly
connected
edges.
Our
analysis
local
field
potential
demonstrate
that
contain
assemblies
sufficient
size
to
co-activate
generate
potentials
their
collective
transmembrane
currents
phase-lock
spiking
activity.
These
results
point
for
study
neuropsychiatric
diseases,
drug
action,
effects
external
stimuli
upon
networks.
Chemical Reviews,
Год журнала:
2024,
Номер
124(2), С. 455 - 553
Опубликована: Янв. 4, 2024
In
the
era
of
Internet-of-things,
many
things
can
stay
connected;
however,
biological
systems,
including
those
necessary
for
human
health,
remain
unable
to
connected
global
Internet
due
lack
soft
conformal
biosensors.
The
fundamental
challenge
lies
in
fact
that
electronics
and
biology
are
distinct
incompatible,
as
they
based
on
different
materials
via
functioning
principles.
particular,
body
is
curvilinear,
yet
typically
rigid
planar.
Recent
advances
design
have
generated
tremendous
opportunities
wearable
bioelectronics,
which
may
bridge
gap,
enabling
ultimate
dream
healthcare
anyone,
anytime,
anywhere.
We
begin
with
a
review
historical
development
healthcare,
indicating
significant
trend
healthcare.
This
followed
by
focal
point
discussion
about
new
design,
particularly
low-dimensional
nanomaterials.
summarize
material
types
their
attributes
designing
bioelectronic
sensors;
we
also
cover
synthesis
fabrication
methods,
top-down,
bottom-up,
combined
approaches.
Next,
discuss
energy
challenges
progress
made
date.
addition
front-end
devices,
describe
back-end
machine
learning
algorithms,
artificial
intelligence,
telecommunication,
software.
Afterward,
integration
systems
been
applied
various
testbeds
real-world
settings,
laboratories
preclinical
clinical
environments.
Finally,
narrate
remaining
conjunction
our
perspectives.
Brain
organoids
are
important
models
for
mimicking
some
three-dimensional
(3D)
cytoarchitectural
and
functional
aspects
of
the
brain.
Multielectrode
arrays
(MEAs)
that
enable
recording
stimulation
activity
from
electrogenic
cells
offer
notable
potential
interrogating
brain
organoids.
However,
conventional
MEAs,
initially
designed
monolayer
cultures,
limited
contact
area
restricted
to
bottom
3D
Inspired
by
shape
electroencephalography
caps,
we
developed
miniaturized
wafer-integrated
MEA
caps
The
optically
transparent
shells
composed
self-folding
polymer
leaflets
with
conductive
polymer–coated
metal
electrodes.
Tunable
folding
minicaps’
guided
mechanics
simulations
enables
versatile
different
sizes,
validate
feasibility
electrophysiology
400-
600-μm-sized
up
4
weeks
in
response
glutamate
stimulation.
Our
studies
suggest
shell
MEAs
great
high
signal-to-noise
ratio
spatiotemporal
organoid
recording.
Advanced Materials,
Год журнала:
2022,
Номер
34(11)
Опубликована: Янв. 11, 2022
Human
induced
pluripotent
stem
cell
derived
brain
organoids
have
shown
great
potential
for
studies
of
human
development
and
neurological
disorders.
However,
quantifying
the
evolution
electrical
properties
during
is
currently
limited
by
measurement
techniques,
which
cannot
provide
long-term
stable
3D
bioelectrical
interfaces
with
developing
organoids.
Here,
a
cyborg
organoid
platform
reported,
in
"tissue-like"
stretchable
mesh
nanoelectronics
are
designed
to
match
mechanical
be
folded
organogenetic
process
progenitor
or
cells,
distributing
electrode
arrays
across
The
tissue-wide
integrated
show
no
interruption
development,
adapt
volume
morphological
changes
organogenesis,
contacts
neurons
within
development.
seamless
noninvasive
coupling
electrodes
enables
stable,
continuous
recording
captures
emergence
single-cell
action
potentials
from
early-stage
Electronic
devices
with
engineered
three-dimensional
(3D)
architectures
are
indispensable
for
frictional-force
sensing,
wide-field
optical
imaging,
and
flow
velocity
measurement.
Recent
advances
in
mechanically
guided
assembly
established
deterministic
routes
to
3D
structures
high-performance
materials,
through
controlled
rolling/folding/buckling
deformations.
The
resulting
are,
however,
mostly
formed
on
planar
substrates
cannot
be
transferred
directly
onto
another
curved
substrate.
Here,
we
introduce
an
ordered
strategy
allow
transformation
of
2D
thin
films
into
sophisticated
diverse
surfaces.
leverages
predefined
mechanical
loadings
that
deform
elastomer
flat/cylindrical
configurations,
followed
by
additional
uniaxial/biaxial
prestretch
drive
buckling-guided
assembly.
Release
results
can
accurately
captured
mechanics
modeling,
as
illustrated
dozens
complex
assembled
substrates.
Demonstrated
applications
include
tunable
dipole
antennas,
sensors
inside
a
tube,
integrated
electronic
systems
capable
conformal
integration
the
heart.
