STEIN RESEARCH GROUP
POROUS SOLIDS — NANOCOMPOSITES — SELF-ASSEMBLED FRAMEWORKS
 |
 |
 |
 |
 |
Templated
Bioactive Glasses
(Bone Graft Substitutes)
Bioactive
glasses are materials that form a biologically compatible hydroxycarbonate
apatite (HCA) layer at the interface with bone in vivo. This layer allows
the glass to establish a continuous bond with bone. An HCA layer can
be formed on the surface of bioactive materials when they are soaked
in simulated
body fluid (SBF), an aqueous solution that has approximately the same
ion concentration and pH as human blood plasma. Traditionally, bioactive
glasses
have been prepared from a melt of glass components or from sol-gel precursors.
We have investigated the use of colloidal crystal templating to produce
threedimensionally ordered macroporous (3DOM) bioactive glasses (mixed
SiO2/CaO compositions). In vitro hydroxycarbonate apatite growth is studied
by soaking the bioactive glass in SBF at body temperature. The formation
of a hydroxycarbonate apatite layer on the glass can be followed by diffraction,
microscopic, spectrocopic and chemical analysis. We have demonstrated
that the 3DOM bioactive glass exhibited faster growth of apatite
than a non-templated
control sample, probably due to the more accessible surface in the 3DOM
material. 3DOM glasses possess several features relevant for bioactive
materials that result in their faster dissolution and more rapid growth
of HCA in SBF. These features include (1) the size of the overall 3DOM
particle (up to mm-size), which should prevent rejection of the particle
by the body defense system; (2) the large pores which permit facile transport
of SBF and probably also natural body fluids; (3) the thin walls which
are generated by filling interstices between close-packed templating
spheres; and (4) the relatively large accessible surface. In a related
project,
we have synthesized 3DOM hydroxyapatite materials directly by colloidal
crystal templating and investigated the product as a host for uptake
and controlled release of drug components.
Fig.
3. SEM images of 3DOM hydroxyapatite/tricalcium phosphate.
Fig.
1. Schematic diagram of bioglass conversion in simulated body fluid.
It is believed that apatite forms from the dissolved precursor species
on top of a silica nucleation layer.
Fig. 2.
SEM
images of 3DOM CaO/SiO2 before exposure to SBF (top), after
immersion in SBF for 3 h (middle), and after immersion in SBF for 4
days.
Fig. 4. Release
of norfloxacin from charged 3DOM hydroxyapatite/tricalcium phosphate
in SBF at 37°C.