Is It Time to Start Transitioning From 2D to 3D Cell Culture?
Frontiers in Molecular Biosciences,
Journal Year:
2020,
Volume and Issue:
7
Published: March 6, 2020
Cell
culture
is
an
important
and
necessary
process
in
drug
discovery,
cancer
research,
as
well
stem
cell
research.
Most
cells
are
currently
cultured
using
two-dimensional
(2D)
methods,
but
new
improved
methods
that
implement
three-dimensional
(3D)
techniques
suggest
compelling
evidence
much
more
advanced
experiments
can
be
performed.
When
performing
3D
experiments,
the
environment
manipulated
to
mimic
of
a
vivo
provide
accurate
data
about
cell-to-cell
interactions,
tumor
characteristics,
metabolic
profiling,
other
types
diseases.
Scaffold
based
such
hydrogel-based
support,
polymeric
hard
material-based
hydrophilic
glass
fiber,
organoids
employed,
each
provides
its
own
advantages
applications.
Likewise,
there
also
scaffold-free
used
hanging
drop
microplates,
magnetic
levitation,
spheroid
microplates
with
ultra-low
attachment
coating.
has
potential
alternative
ways
study
organ
behavior
via
use
expected
eventually
bridge
gap
between
2D
animal
models.
The
present
review
compares
culture,
details
surrounding
different
techniques,
focuses
on
future
applications
culture.
Language: Английский
Human organs-on-chips for disease modelling, drug development and personalized medicine
Nature Reviews Genetics,
Journal Year:
2022,
Volume and Issue:
23(8), P. 467 - 491
Published: March 25, 2022
The
failure
of
animal
models
to
predict
therapeutic
responses
in
humans
is
a
major
problem
that
also
brings
into
question
their
use
for
basic
research.
Organ-on-a-chip
(organ
chip)
microfluidic
devices
lined
with
living
cells
cultured
under
fluid
flow
can
recapitulate
organ-level
physiology
and
pathophysiology
high
fidelity.
Here,
I
review
how
single
multiple
human
organ
chip
systems
have
been
used
model
complex
diseases
rare
genetic
disorders,
study
host–microbiome
interactions,
whole-body
inter-organ
reproduce
clinical
drugs,
radiation,
toxins
infectious
pathogens.
address
the
challenges
must
be
overcome
chips
accepted
by
pharmaceutical
industry
regulatory
agencies,
as
well
discuss
recent
advances
field.
It
evident
instead
drug
development
avatars
personalized
medicine
ever
closer
realization.
This
Review
discusses
types
organ-on-a-chip
diverse
applications
disease
modelling,
medicine,
reach
full
potential.
Language: Английский
Engineering organoids
Nature Reviews Materials,
Journal Year:
2021,
Volume and Issue:
6(5), P. 402 - 420
Published: Feb. 19, 2021
Language: Английский
Modelling cancer in microfluidic human organs-on-chips
Nature reviews. Cancer,
Journal Year:
2019,
Volume and Issue:
19(2), P. 65 - 81
Published: Jan. 15, 2019
Language: Английский
Organs-on-chips: into the next decade
Nature Reviews Drug Discovery,
Journal Year:
2020,
Volume and Issue:
20(5), P. 345 - 361
Published: Sept. 10, 2020
Language: Английский
A complex human gut microbiome cultured in an anaerobic intestine-on-a-chip
Nature Biomedical Engineering,
Journal Year:
2019,
Volume and Issue:
3(7), P. 520 - 531
Published: May 13, 2019
Language: Английский
Organ-on-a-chip: recent breakthroughs and future prospects
BioMedical Engineering OnLine,
Journal Year:
2020,
Volume and Issue:
19(1)
Published: Feb. 12, 2020
Abstract
The
organ-on-a-chip
(OOAC)
is
in
the
list
of
top
10
emerging
technologies
and
refers
to
a
physiological
organ
biomimetic
system
built
on
microfluidic
chip.
Through
combination
cell
biology,
engineering,
biomaterial
technology,
microenvironment
chip
simulates
that
terms
tissue
interfaces
mechanical
stimulation.
This
reflects
structural
functional
characteristics
human
can
predict
response
an
array
stimuli
including
drug
responses
environmental
effects.
OOAC
has
broad
applications
precision
medicine
biological
defense
strategies.
Here,
we
introduce
concepts
review
its
application
construction
models,
development,
toxicology
from
perspective
different
organs.
We
further
discuss
existing
challenges
provide
future
perspectives
for
application.
Language: Английский
Homeostatic mini-intestines through scaffold-guided organoid morphogenesis
Nature,
Journal Year:
2020,
Volume and Issue:
585(7826), P. 574 - 578
Published: Sept. 16, 2020
Language: Английский
Microfluidic Organ-on-a-Chip Models of Human Intestine
Cellular and Molecular Gastroenterology and Hepatology,
Journal Year:
2018,
Volume and Issue:
5(4), P. 659 - 668
Published: Jan. 1, 2018
Microfluidic
organ-on-a-chip
models
of
human
intestine
have
been
developed
and
used
to
study
intestinal
physiology
pathophysiology.
In
this
article,
we
review
field
describe
how
microfluidic
Intestine
Chips
offer
new
capabilities
not
possible
with
conventional
culture
systems
or
organoid
cultures,
including
the
ability
analyze
contributions
individual
cellular,
chemical,
physical
control
parameters
one-at-a-time;
coculture
cells
commensal
microbiome
for
extended
times;
create
human-relevant
disease
models.
We
also
discuss
potential
future
applications
Chips,
they
might
be
drug
development
personalized
medicine.
SummaryOrgans-on-chips
are
cell
that
recapitulate
structure,
function,
physiology,
pathology
living
organs
in
vitro.
recent
various
intestine-on-a-chip
their
value
modeling,
discovery,
Organs-on-chips
The
major
organ
function
is
carry
out
digestion,
absorption,
secretion,
motility,1Silverthorn
D.U.
Ober
W.C.
Garrison
C.W.
Silverthorn
A.C.
Johnson
B.R.
Human
physiology:
an
integrated
approach.
Pearson/Benjamin
Cummings,
San
Francisco2009Google
Scholar
addition
establishing
a
protective
epithelial
barrier
between
digestive
environment
body.
addition,
intestines
regulate
systemic
by
metabolizing
drugs2Benet
L.Z.
Wu
C.-Y.
Hebert
M.F.
Wacher
V.J.
Intestinal
metabolism
antitransport
processes:
paradigm
shift
oral
delivery.J
Control
Release.
1996;
39:
139-143Crossref
Scopus
(188)
Google
Scholar;
communicate
other
organs,
such
as
liver3Moore
F.A.
Moore
E.E.
Poggetti
R.
McAnena
O.J.
Peterson
V.M.
Abernathy
C.M.
Parsons
P.E.
Gut
bacterial
translocation
via
portal
vein:
clinical
perspective
torso
trauma.J
Trauma
Acute
Care
Surg.
1991;
31:
629-638Crossref
(447)
Scholar,
4Bloemen
J.G.
Venema
K.
van
de
Poll
M.C.
Damink
S.W.O.
Buurman
W.A.
Dejong
C.H.
Short
chain
fatty
acids
exchange
across
gut
liver
humans
measured
at
surgery.Clin
Nutr.
2009;
28:
657-661Abstract
Full
Text
PDF
PubMed
(217)
pancreas,5Ahuja
M.
Schwartz
D.M.
Tandon
Son
A.
Zeng
Swaim
W.
Eckhaus
Hoffman
V.
Cui
Y.
Xiao
B.
Orai1-mediated
antimicrobial
secretion
from
pancreatic
acini
shapes
regulates
innate
immunity.Cell
Metab.
2017;
25:
635-646Abstract
(84)
flow;
contain
enteric
nervous
system
forms
part
gut-brain
axis.6Cryan
J.F.
Dinan
T.G.
Mind-altering
microorganisms:
impact
microbiota
on
brain
behaviour.Nat
Rev
Neurosci.
2012;
13:
701-712Crossref
(2487)
7Mayer
E.A.
feelings:
emerging
biology
gut–brain
communication.Nat
2011;
12:
453-466Crossref
(986)
site
which
microbes
live
interact
lymphoid
tissues
host
immune
system,
contributes
significantly
homeostasis.8Garrett
W.S.
Gordon
J.I.
Glimcher
L.H.
Homeostasis
inflammation
intestine.Cell.
2010;
140:
859-870Abstract
(556)
9Round
J.L.
Mazmanian
S.K.
responses
during
health
disease.Nat
Immunol.
9:
313-323Crossref
(3250)
For
example,
its
metabolites
(eg,
short-chain
acids)
recently
shown
play
central
role
maintenance
health,
modulation,
both
enteral
nonenteral
diseases.10Wong
J.M.
De
Souza
Kendall
Emam
Jenkins
D.J.
Colonic
health:
fermentation
short
acids.J
Clin
Gastroenterol.
2006;
40:
235-243Crossref
(1832)
11Smith
P.M.
Howitt
M.R.
Panikov
N.
Michaud
Gallini
C.A.
Bohlooly-y
Glickman
J.N.
Garrett
microbial
metabolites,
acids,
colonic
Treg
homeostasis.Science.
2013;
341:
569-573Crossref
(3048)
However,
analysis
interactions
has
limited
genetic
metagenomics
because
it
these
epithelium
more
than
about
1
day
using
even
sophisticated
cultures.
Thus,
there
great
efforts
develop
experimental
vitro
ex
vivo
permit
pathophysiology
presence
absence
microbiome.
most
common
model
absorption
involve
culturing
established
line
Caco-212Hidalgo
I.J.
Raub
T.J.
Borchardt
R.T.
Characterization
colon
carcinoma
(Caco-2)
permeability.Gastroenterology.
1989;
96:
736-749Abstract
(1952)
13Artursson
P.
Karlsson
J.
Correlation
apparent
permeability
coefficients
cells.Biochem
Biophys
Res
Commun.
175:
880-885Crossref
(1674)
HT-2914Pinto
M.G.V.
Gómez
Seifert
S.
Watzl
Holzapfel
W.H.
Franz
Lactobacilli
stimulate
response
modulate
TLR
expression
HT29
vitro.Int
J
Food
Microbiol.
133:
86-93Crossref
(113)
15Eveillard
Fourel
Bare
Kernéis
Coconnier
M.H.
Karjalainen
T.
Bourlioux
Servin
A.L.
Identification
characterization
adhesive
factors
Clostridium
difficile
involved
adhesion
enterocyte-like
Caco-2
mucus-secreting
culture.Mol
1993;
7:
371-381Crossref
(74)
cells)
extracellular
matrix
(ECM)-coated,
porous
membranes
within
Transwell
insert
devices.
Although
commonly
pharmaceutical
industry,
2-dimensional
(2D)
format
fails
physiological
3-dimensional
(3D)
tissue
morphology
re-establish
key
differentiated
functions
mucus
production,
villi
formation,
cytochrome
P-450-based
metabolism).16Kim
H.J.
Huh
D.
Hamilton
G.
Ingber
D.E.
gut-on-a-chip
inhabited
flora
experiences
peristalsis-like
motions
flow.Lab
Chip.
2165-2174Crossref
(1046)
17Kim
Gut-on-a-Chip
microenvironment
induces
undergo
villus
differentiation.Integr
Biol.
5:
1130-1140Crossref
(443)
These
static
cannot
support
cells,
critical
physiology,16Kim
bacteria
rapidly
overgrow
contaminate
cultures
day.
Several
models,
everted
sac18Alam
M.A.
Al-Jenoobi
F.I.
Al-mohizea
A.M.
Everted
sac
tool
research:
limitations
applications.J
Pharm
Pharmacol.
64:
326-336Crossref
(131)
Ussing
chamber,19Rozehnal
Nakai
Hoepner
U.
Fischer
Kamiyama
E.
Takahashi
Yasuda
Mueller
small
mounted
chamber
characterizing
drugs.European
Journal
Pharmaceutical
Sciences.
46:
367-373Crossref
(104)
20Smith
Mirabelli
C.
Fondacaro
Ryan
F.
Dent
5-fluorouracil
absorption:
Use
chambers
assess
transport
metabolism.Pharm
Res.
1988;
598-603Crossref
(45)
assays;
however,
expected
lifespan
(<8
hours)
sufficient
enable
many
studies
normal
clinically
relevant
host-microbiome
crosstalk.
had
technically
challenging
primary
3D
derived
either
crypts
containing
endogenous
induced
pluripotent
stem
revolutionized
maintaining
niches
supporting
differentiation
subtypes
vitro.21Sato
Van
Es
J.H.
Snippert
Stange
Vries
R.G.
Den
Born
Barker
Shroyer
N.F.
Wetering
Clevers
H.
Paneth
constitute
niche
Lgr5
crypts.Nature.
469:
415-418Crossref
(1723)
22Jung
Sato
Merlos-Suárez
Barriga
F.M.
Iglesias
Rossell
Auer
Gallardo
Blasco
Sancho
Isolation
expansion
cells.Nat
Med.
17:
1225-1227Crossref
(497)
When
cultured
ECM
gel
medium
Wnt,
R-spondin,
noggin,
growth
factors,
organoids
(enteroids)
spontaneously
villus-crypt
morphologic
organization
histogenesis.22Jung
Each
biopsy
patient
can
grown,
frozen,
revived
multiple
reuses,
potentially
establish
biobanks23van
Francies
H.E.
Francis
Bounova
Iorio
Pronk
Houdt
Gorp
Taylor-Weiner
Kester
L.
Prospective
derivation
biobank
colorectal
cancer
patients.Cell.
2015;
161:
933-945Abstract
(1348)
24Sato
SnapShot:
growing
cells.Cell.
1700-1700.e1Abstract
(97)
multiplexed
screening
platforms
validating
candidates
advance
medicine.25Fatehullah
Tan
S.H.
Organoids
Cell
2016;
18:
246-254Crossref
(837)
lack
types
found
intestine,
endothelium-lined
blood
vessels
important
transport,
pharmacokinetic
(PK)
analysis,
modeling.
They
do
experience
fluid
flows
cyclic
mechanical
deformations
similar
those
experienced
peristalsing
contribute
function.
Furthermore,
each
enteroid
closed
lumen
when
surrounding
gel,
experimentally
difficult
sample
manipulate
luminal
components
nutrients,
drugs,
toxins).
This
structure
limits
researchers
PK,
metabolism),
interactions.26Park
G.-S.
Park
Shin
Zhao
Sheikh
Oh
S.J.
Kim
Emulating
ecosystem
gastrointestinal
tract
vitro.Stem
Rep.
321-334Crossref
(43)
challenges
overcome
Organ
Chip
intestine.
devices,
originally
fabricated
methods
adapted
computer
microchip
manufacturing
soft
lithography),
continuously
perfused
arranged
simulate
tissue-
organ-level
physiology.27Bhatia
S.N.
organs-on-chips.Nat
Biotechnol.
2014;
32:
760-772Crossref
(1976)
Over
past
5
years,
engineered
increasing
complexity
include
neighboring
channels
lined
microvascular
endothelium,
microbes,
pathogenic
bacteria,
some
application
forces
mimic
(Figure
1).
Next
emulate
(Table
Also
considered
implications
work
complex
development,
medicine
future.Table
1Design
Characteristics
ModelsModelTEERAbsorptionCocultureMicrobiomeDifferentiationPeristalsisDrug
metabolismCrypt-villus
axisOxygen
modulationDisease
modelingStatic
TranswellYes12Hidalgo
ScholarYes12Hidalgo
ScholarNoYes14Pinto
(<24
h)NoNoNoNoNoNo
OrganoidNoYes95Zietek
Rath
Haller
Daniel
assessing
nutrient
sensing
incretin
secretion.Sci
16831Crossref
ScholarNoYes96Zhang
Y.G.
Xia
Sun
Salmonella-infected
crypt-derived
host–bacterial
interactions.Physiol
2:
e12147Crossref
(150)
(<1
h)Yes21Sato
ScholarNoYes97Lu
Rettenmeier
Paszek
Yueh
M.-F.
Tukey
R.H.
Trottier
Barbier
O.
Chen
Crypt
cytotoxicity
studies.Drug
Metab
Dispos.
45:
748-754Crossref
(28)
ScholarYes21Sato
ScholarNoYes22Jung
Ex
vivoYes19Rozehnal
98Madsen
Cornish
Soper
McKaigney
Jijon
Yachimec
Doyle
Jewell
Simone
Probiotic
enhance
murine
function.Gastroenterology.
2001;
121:
580-591Abstract
(890)
ScholarYes19Rozehnal
(<3
h)Yes19Rozehnal
ScholarNoYes100Sjöberg
Å.
Lutz
Tannergren
Wingolf
Borde
Ungell
A.-L.
Comprehensive
regional
prediction
fraction
absorbed
drugs
technique.Eur
Sci.
48:
166-180Crossref
(151)
ScholarYes99Worton
Candy
Wallis
Clarke
Osborne
Haddon
Stephen
Studies
early
association
Salmonella
typhimurium
mucosa
vitro:
relationship
virulence.J
Med
29:
283-294Crossref
(31)
ScholarYes98Madsen
ScaffoldNoNoNoNoYes40Wang
Gunasekara
D.B.
Reed
M.I.
DiSalvo
Bultman
Sims
C.E.
Magness
S.T.
Allbritton
N.L.
A
microengineered
collagen
scaffold
generating
polarized
crypt-villus
architecture
epithelium.Biomaterials.
128:
44-55Crossref
(191)
ScholarNoNoYes40Wang
ScholarNoNoMicrofluidic
2-channelYes32Maoz
B.M.
Herland
Henry
O.Y.F.
Leineweber
Yadid
Mannix
Kujala
Fitzgerald
Parker
K.K.
combined
multi-electrode
array
transepithelial
electrical
resistance
measurement
capabilities.Lab
2294-2302Crossref
ScholarYes30Gao
Liu
Lin
J.-M.
Wang
Jiang
monolayers
mass
spectrometry
membrane-based
device.Lab
978-985Crossref
(94)
ScholarYes37Esch
M.B.
Mahler
G.J.
Stokol
Shuler
M.L.
Body-on-a-chip
simulation
suggests
ingested
nanoparticles
cause
injury.Lab
14:
3081-3092Crossref
ScholarNoNoNoYes39Shim
K.-Y.
Lee
Han
Nguyen
N.-T.
Sung
three-dimensional
structure.Biomed
Microdevices.
19:
37Crossref
(120)
ScholarYes39Shim
ScholarNoNo
vivoNoYes99Worton
ScholarNoNoYes101Dawson
Dyer
Macfie
Davies
Karsai
Greenman
Jacobsen
chip
based
full
thickness
dual
flow.Biomicrofluidics.
10:
064101Crossref
(32)
ScholarNoYes101Dawson
Multichannel
(HuMiX)Yes41Shah
Fritz
J.V.
Glaab
Desai
M.S.
Greenhalgh
Frachet
Niegowska
Estes
Jäger
Seguin-Devaux
microfluidics-based
human–microbe
interface.Nat
11535Crossref
(326)
ScholarNoNoYes41Shah
h)NoNoNoNoYes41Shah
ScholarNo
ChipYes16Kim
42Kim
Li
Collins
J.J.
Contributions
deformation
overgrowth
gut-on-a-chip.Proc
Natl
Acad
113:
E7-E15Crossref
(549)
ScholarYes16Kim
ScholarNoYes16Kim
(>7
d)Yes17Kim
ScholarNoYes42Kim
ScholarTEER,
resistance.
Open
table
tab
TEER,
devices
hollow
microchannels
less
mm
width
laminar
flow
nanoliter
microliter
scale
volumes,
thus,
amenable
use
cells.
By
syringe
peristaltic
pump,
may
desired
rates
through
microchannel,
dynamic
ranges
associated
shear
stresses
surface
observed
lumen,28Vickerman
Blundo
Chung
Kamm
Design,
fabrication
implementation
novel
multi-parameter
platform
real-time
imaging.Lab
2008;
8:
1468-1477Crossref
(294)
29Tanaka
Yamato
Okano
Kitamori
Evaluation
effects
stress
hepatocytes
microchip-based
system.Meas
Sci
Technol.
3167-3170Crossref
(87)
capillaries.
fluidic
enables
delivery
compounds,
toxins
grown
highly
regulated
spatiotemporal
manner.
Most
2
separated
porous,
ECM-coated
polyester
polycarbonate
membrane,
immortalized
surfaces.30Gao
monolayer
formed
device
c
Language: Английский
Reproducing human and cross-species drug toxicities using a Liver-Chip
Science Translational Medicine,
Journal Year:
2019,
Volume and Issue:
11(517)
Published: Nov. 6, 2019
A
rat,
dog,
and
human
Liver-Chip
designed
using
microengineered
Organs-on-Chips
technology
recapitulates
species-specific
drug
toxicities.
Language: Английский
