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bioadhesion

Bioadhesion describes the attachment of biological materials to surfaces or to other tissues. It encompasses cell-cell adhesion, mediated by cell adhesion molecules such as cadherins, integrins, and selectins, and cell-matrix interactions, including binding to extracellular matrix proteins. Bioadhesion also refers to attachment of tissues or organisms to biomaterials and mucosal surfaces. Natural examples include mussel adhesive proteins that function in wet environments and, conceptually, dry adhesives inspired by geckos. In research and medicine, bioadhesion is studied to understand tissue cohesion and to design compatible interfaces with living systems.

Adhesion arises from covalent bonds in some bioadhesives and from non-covalent interactions such as electrostatic forces,

Applications include mucoadhesive drug delivery, tissue sealants and wound closure, and scaffolds that promote tissue integration.

hydrogen
bonding,
hydrophobic
effects,
and
van
der
Waals
interactions.
Mechanical
interlocking
with
surface
roughness
and
disruption
of
hydration
layers
also
contribute,
particularly
on
wet
surfaces.
Adhesion
performance
depends
on
surface
chemistry,
topography,
moisture,
pH,
ionic
strength,
and
temperature,
as
well
as
the
properties
of
the
interacting
materials.
Natural
bioadhesives
are
adapted
to
aqueous
environments,
whereas
synthetic
systems
aim
for
biocompatibility,
tunable
strength,
biodegradability,
and
controlled
degradation.
Common
methods
to
assess
bioadhesion
in
the
lab
include
lap
shear,
peel,
and
tensile
strength
tests,
as
well
as
burst
pressure
for
seals,
and
measurements
of
surface
energy.
Challenges
include
achieving
durable
adhesion
in
dynamic,
wet
biological
conditions,
avoiding
immune
reactions,
and
balancing
strength
with
biodegradability.
Ongoing
research
integrates
biology
and
materials
science
to
understand
adhesion
mechanisms
and
to
develop
new
bioadhesive
technologies.