CIRP Annals,
Journal Year:
2023,
Volume and Issue:
72(2), P. 569 - 592
Published: Jan. 1, 2023
Design,
development,
productization,
and
applications
of
advanced
product
concepts
are
pressing
for
higher
multifunctionality,
resilience,
maximization
available
resources
equitably
to
meet
the
growing
continuing
demands
global
customers.
These
have
further
accelerated
during
recent
COVID-19
pandemic
be
a
challenge.
Engineering
designs
one
most
effective
ways
endow
products
with
functions,
sustainability.
Biology,
through
millions
years
evolution,
has
met
these
acute
requirements
under
severe
resource
environmental
constraints.
As
manufacturing
is
reaching
fundamental
limits
raw
materials,
labor,
constraints
in
terms
availability,
accessibility,
affordability,
new
approaches
call
action
challenges.
Understanding
biology
an
attractive,
novel,
desired
frontier
learning
implementation
this
action.
This
focus
paper
discussed
examples
convergence
engineering
design
lessons
learned
applied
from
biology.
Advanced Functional Materials,
Journal Year:
2022,
Volume and Issue:
33(6)
Published: Dec. 3, 2022
Abstract
Bioadhesives
have
been
used
in
clinics
among
the
most
prospective
alternatives
to
sutures
and
staples
for
wound
sealing
repairing;
however,
they
generally
inadequate
adhesion
wet
surfaces,
improper
mechanical
strength,
poor
hemostasis,
cytotoxicity.
To
address
these
challenges,
a
robust
tissue
adhesive
based
on
collagen
starch
materials
(CoSt)
is
designed
this
study.
CoSt
hydrogels
integrate
feature
of
drainage,
molecular
penetration
strengthen
cross‐linking
similar
mussel,
ivy,
oyster
glues,
which
remove
interfacial
water
quickly,
reinforce
tough
dissipation
involve
multiple
reversible
dynamic
interactions.
Therefore,
form
strong
sutureless
injured
tissues,
accompanying
actuate
biointerfaces
direct
contact
with
liquids
or
blood,
resolving
crucial
impediments
commercially
accessible
adhesives.
The
novel
bioadhesive
shows
repeatable
adhesiveness
(62
±
4.8
KPa),
high
performance
(153.2
35.1
mmHg),
fast
self‐healing
ability,
excellent
injectability,
shape
adaptability.
For
different
hemostatic
needs
rat
models
tail
amputation,
skin
incision,
severe
liver,
abdominal
aorta,
transected
nerve
injuries,
hydrogel
better
efficiency
than
fibrin
glue
because
coordinate
efficacy
property,
outstanding
red
blood
cell
arresting
capability,
activation
barrier
membrane.
Moreover,
vivo
investigation
injury
repair
model
validate
that
accelerate
healing
functional
recovery
via
damage/defects.
Tough
adhesion,
quick
distinguished
biocompatibility,
suitability
match
irregular‐shaped
target
sites,
good
promotion
makes
it
various
biomedical
applications.
Advanced Materials Interfaces,
Journal Year:
2022,
Volume and Issue:
9(18)
Published: May 23, 2022
Abstract
Mucoadhesion
is
an
extremely
important
field
of
adhesion
science
and
the
comprehensive
understanding
modulation
mucoadhesion
can
lead
to
lifesaving
materials
technologies.
For
instance,
deadly
cases
COVID‐19
(SARS‐CoV‐2)
cytokine
storm
are
associated
with
viral
overproduction
mucus,
which
obstructs
airways.
Mucin
key
polymeric
compound
that
known
as
a
family
high
molecular
weight,
heavily
glycosylated
proteins
in
epithelial
tissues.
occur
many
different
ways
such
receptor
specific
charge
interactions,
covalent
or
noncovalent
bonds.
New
mucin‐mimic
polymers
replicate
its
beneficial
traits
prevent
biofilm
formation
biofouling
not
only
biotechnology
but
also
membrane
This
review
addresses
latest
understandings
related
mucin's
role
wet
considering
physiological
conditions
shows
how
this
translates
into
interfacial
polymer
adhesion.
Advances
measurement
techniques
including
rheological
aspects
polymer–mucin
adhesive
interactions
presented.
Specific
mucoadhesive
systems
discussed
hydrogel
mucoadhesion,
catechol/dopamine
functionalization,
nanoparticles.
overview
may
expand
current
between
soft
contributes
elastocapillary
phenomena
design
applications
new
membranes,
drugs,
pharmaceutical
devices,
lubricated
surfaces.
ACS Nano,
Journal Year:
2023,
Volume and Issue:
17(19), P. 18850 - 18863
Published: Oct. 2, 2023
The
development
of
formaldehyde-free
functional
wood
composite
materials
through
the
preparation
strong
and
multifunctional
soybean
protein
adhesives
to
replace
formaldehyde-based
resins
is
an
important
research
area.
However,
ensuring
bonding
performance
adhesive
while
simultaneously
developing
thermally
conductive
its
corresponding
composites
challenging.
Taking
inspiration
from
microphase
separation
structure
spider
silk,
boron
nitride
(BN)
soy
isolate
(SPI)
were
mixed
by
ball
milling
obtain
a
BN@SPI
matrix
combined
with
self-synthesized
hyperbranched
reactive
substrates
as
amorphous
region
reinforcer
cross-linker
triglycidylamine
prepare
cross-linked
structure.
These
findings
indicate
that
mechanical
can
be
employed
strip
BN
followed
combination
SPI,
resulting
in
tight
bonded
interface
connection.
Subsequently,
adhesive's
dry
wet
shear
strengths
increased
14.3%
90.5%
1.83
1.05
MPa,
respectively.
resultant
also
possesses
good
thermal
conductivity
(0.363
W/mK).
Impressively,
because
hot-pressing
helps
establish
conduction
pathway,
wood-based
10
times
higher
than
SPI
adhesive,
which
shows
similar
ceramic
tile
has
excellent
potential
for
biothermal
materials,
geothermal
floors,
energy
storage
materials.
Moreover,
possessed
effective
flame
retardancy
(limit
oxygen
index
=
36.5%)
mildew
resistance
(>50
days).
This
bionic
design
represents
efficient
technique
biomass
composites.
Progress in Polymer Science,
Journal Year:
2024,
Volume and Issue:
150, P. 101792 - 101792
Published: Jan. 26, 2024
In
the
last
decades,
adhesives
derived
from
natural
resources
(i.e.,
bioadhesives)
have
emerged
as
promising
alternative
to
standard
wound
closure
devices,
including
sutures,
clips,
and
strips,
owing
relatively
easy
rapid
application,
minimal
tissue
damage,
fast
hemostasis,
ability
decrease
risk
of
infection.
Various
synthetic
materials
been
utilized
bioadhesives.
These
find
extensive
application
in
various
biomedical
fields,
ranging
simple
sealing
controlled
drug
delivery,
regeneration,
noninvasive
therapy.
Considering
weak
underwater
adhesion,
degradability,
biological
performances
adhesives,
naturally
derived-based
are
more
attractive.
The
first
generation
these
bioadhesives
provided
primarily
only
one
function.
Moreover,
they
had
issues
long
curing
time,
slow
high
degradation
rate,
low
mechanical
properties,
transferring
contamination
wound.
chemically
genetically
engineered
strategies
applied
advance
their
multifunctionality.
synergy
bonding
chemistry,
topography,
mechanics
dissipation
structure
supports
improved
adhesion
rate.
developed
that
cover
subjects
innovative
biomaterial
synthesis
or
functionalization
cutting-edge
manufacturing
processes.
However,
fulfill
all
criteria
an
ideal
bioadhesive
for
clinical
applications,
efforts
should
be
devoted
investigating
surface
characteristics
target
tissues
long-term
relationship
between
physiochemical
properties
polymers
cohesion
mechanisms,
well
adhesive
functionality.
This
review
outlines
recent
progress
on
naturally-derived
bioadhesives,
proteins
polysaccharides,
focusing
designing
approaches
based
engineering
strategies,
development,
applications.
Furthermore,
challenges
current
studies
summarized
show
future
perspectives
developing
bioengineered
high-performance
use.
Materials Today Bio,
Journal Year:
2023,
Volume and Issue:
19, P. 100592 - 100592
Published: Feb. 24, 2023
Although
the
past
decade
has
witnessed
unprecedented
medical
advances,
achieving
rapid
and
effective
hemostasis
remains
challenging.
Uncontrolled
bleeding
wound
infections
continue
to
plague
healthcare
providers,
increasing
risk
of
death.
Various
types
hemostatic
materials
are
nowadays
used
during
clinical
practice
but
have
many
limitations,
including
poor
biocompatibility,
toxicity
biodegradability.
Recently,
there
been
a
burgeoning
interest
in
organisms
that
stick
objects
or
produce
sticky
substances.
Indeed,
applying
biological
adhesion
properties
an
interesting
approach.
This
paper
reviews
behavior,
bionics,
mechanisms
related
hemostasis.
Furthermore,
this
covers
benefits,
challenges
prospects
biomimetic
materials.
Gels,
Journal Year:
2024,
Volume and Issue:
10(9), P. 547 - 547
Published: Aug. 23, 2024
Regenerative
hydrogels
from
natural
polymers
have
come
forth
as
auspicious
materials
for
use
in
regenerative
medicine,
with
interest
attributed
to
their
intrinsic
biodegradability,
biocompatibility,
and
ability
reassemble
the
extracellular
matrix.
This
review
covers
latest
advances
used
wound
healing,
focusing
on
chemical
composition,
cross-linking
mechanisms,
functional
properties.
Key
carbohydrate
polymers,
including
alginate,
chitosan,
hyaluronic
acid,
polysaccharide
gums,
agarose,
carrageenan,
xanthan
gum,
are
discussed
terms
of
sources,
structures
specific
properties
suitable
applications.
The
further
explores
categorization
based
ionic
charge,
response
physiological
stimuli
(i.e.,
pH,
temperature)
particularized
roles
tissue
self-healing.
Various
methods
enhance
mechanical
biological
performance
these
also
examined.
By
highlighting
recent
innovations
ongoing
challenges,
this
article
intends
give
a
detailed
understanding
potential
revolutionize
medicine
improve
patient
healing
outcomes.
Small,
Journal Year:
2024,
Volume and Issue:
20(45)
Published: July 19, 2024
Abstract
Nature
serves
as
an
abundant
wellspring
of
inspiration
for
crafting
innovative
adhesive
materials.
Extensive
research
is
conducted
on
various
complex
forms
biological
attachment,
such
geckos,
tree
frogs,
octopuses,
and
mussels.
However,
significant
obstacles
still
exist
in
developing
materials
that
truly
replicate
the
behaviors
functionalities
observed
living
organisms.
Here,
overview
organs,
structures,
secretions
endowed
with
adhesion
capabilities,
delving
into
intricate
relationship
between
their
morphology
function,
potential
biomimicry
are
provided.
First,
design
principles
mechanisms
behavior
individual
organ
nature
summarized
from
perspective
structural
size
constraints.
Subsequently,
value
engineered
bioinspired
through
selective
application
cases
practical
fields
emphasized.
Then,
a
forward‐looking
gaze
conceivable
challenges
associated
opportunities
harnessing
biomimetic
strategies
advancing
material
innovation
highlighted
cast.
