Biomedical Engineering Reference
In-Depth Information
highl
[KAP
PEG
prote
ly active ag
P 04] bacter
is one of th
ein resistance
gainst both
ria such as
E
e most comm
e to a surface
Gram negat
E. coli
and
monly used
e [BAN 11].
tive [ITO 0
S.
epidermid
synthetic po
05] and pos
dis
, respectiv
lymers to im
sitive
vely.
mpart
In
activi
bio-in
synth
(bio)m
(in a
polye
ancho
group
polym
is exp
temp
quino
ancho
polym
thiol
extern
consi
n this work,
ities are affo
nspired strat
hetic polyme
molecules ar
aqueous me
electrolyte, a
oring polym
ps serve as
mer-bearing
ploited to pr
erature that
one-function
or active (b
mer) through
end-functio
nal cysteine
idered for the
long-term an
orded to indu
tegy (Figure
ers, the film
re possible u
edia and a
a polycation
mer while
s the cross-
primary am
repare a stab
can be easily
alized surfa
io)molecules
h thiol/quinon
onalized Dsp
es (and thu
e conjugation
ntibacterial,
ustrial SS su
e 6.3). Star
cross-linkin
under environ
at room tem
n-bearing cat
poly(methac
-linking age
mine groups.
ble solution o
y deposited
aces that ar
s (antibiofilm
ne reactions
p B and P
us thiol gro
n.
antiadhesion
rfaces follow
rting from
ng and the g
nmentally fri
mperature).
techol, is us
crylamide)-b
ent in comb
The amine/q
of nanogels i
to SS. This
re then use
m enzyme a
[FAU 12].
F
PEG-SH tha
ups) in its
n and antibio
wing a green
catechol-bea
grafting of ac
iendly condit
A bio-insp
sed as the f
bearing quin
bination wit
quinone reac
in water at r
coating prov
d to covale
and antiadhe
For that purp
at contains
sequence w
ofilm
n and
aring
ctive
tions
pired
film-
none
th a
ction
room
vides
ently
esion
pose,
two
were
Figur
re 6.3.
Schemat
process on
tic description o
to stainless stee
of the “grafting
el surfaces
g to”
