Modulating Bioglass
Concentration in 3D Printed Poly(propylene fumarate) Scaffolds
for Post-Printing Functionalization with Bioactive Functional Groups
posted on 2019-11-21, 12:35authored byAlex P. Kleinfehn, Jan A. Lammel Lindemann, Ali Razvi, Phinu Philip, Katelyn Richardson, Karissa Nettleton, Matthew L. Becker, David Dean
Poly(propylene fumarate) (PPF) has shown potential for
the treatment
of bone defects as it can be 3D printed into scaffolds to suit patient-specific
needs with strength comparable to that of bone. However, the lack
of specific cell attachment and osteogenic signaling moieties have
limited their utility as it is necessary to provide these signals
to aid in bone tissue formation. To address this issue and provide
a platform for functionalization, Bioglass (∼1–2 μm)
microparticles have been incorporated into PPF to create a 3D printable
resin with concentrations ranging from 0 to 10 wt %. The zero-shear
viscosity of PPF-Bioglass resins increased proportionally from 0 to
2.5 wt % Bioglass, with values of 0.22 and 0.34 Pa·s, respectively.
At higher Bioglass concentrations, 5 and 10 wt %, the resin viscosity
increased to 0.44 and 1.31 Pa·s, exhibiting a 2- and 6-fold increase
from the 0 wt % Bioglass resin. Despite this increase in viscosity,
all resins remained printable with no print failures. In addition,
the surface available Bioglass can tether catechol containing molecules
for postprinting functionalization. Analysis of PPF-Bioglass functionalization
using a catechol dye analyte shows functionalization increases with
Bioglass concentration, up to 157 nmol/cm2, and demonstrates
it is possible to modulate functionalization. This presents a versatile
and highly translationally relevant strategy to functionalize 3D printed
scaffolds post printing with a diverse array of functional species.