posted on 2022-08-17, 13:36authored byEdward G. Chadwick, O.M. Clarkin, Ramesh Raghavendra, David TannerDavid Tanner
The properties of porous silicon make it a promising material for a host of
applications including drug delivery, molecular and cell-based biosensing, and tissue
engineering. Porous Silicon has previously shown its potential for the controlled release of
pharmacological agents and in assisting bone healing. Hydroxyapatite, the principle
constituent of bone, allows osteointegration in vivo, due to its chemical and physical
similarities to bone. Synthetic hydroxyapatite is currently applied as a surface coating to
medical devices and prosthetics, encouraging bone in-growth at their surface & improving
osseointegration. This paper examines the potential for the use of an economically produced
porous silicon particulate-polytetrafluoroethylene sheet for use as a guided bone regeneration
device in periodontal and orthopaedic applications. The particulate sheet is comprised of a
series of microparticles in a polytetrafluoroethylene matrix and is shown to produce a stable
hydroxyapatite on its surface under simulated physiological conditions. The microstructure of
the material is examined both before and after simulated body fluid experiments for a period
of 1, 7, 14 and 30 days using Scanning Electron Microscopy. The composition is examined
using a combination of Energy Dispersive X-ray Spectroscopy, Thin film X-ray diffraction,
Attenuated Total Reflectance-Fourier Transform Infrared Spectroscopy and the
uptake/release of constituents at the fluid-solid interface is explored using Inductively Coupled
Plasma-Optical Emission Spectroscopy. Microstructural and compositional analysis reveals
progressive growth of crystalline, ´bone-like´ apatite on the surface of the material, indicating
the likelihood of close bony apposition in vivo.
History
Publication
Bio-Medical Materials and Engineering;24, pp. 1563-1574
Publisher
IOS Press
Note
peer-reviewed
Other Funding information
EI, PRTLI cycle 4, Waterford Institute of Technology's South Eastern Applied Research Centre
Rights
This is the author's version of a work that was published in Bio-Medical Materials and Engineering, 2014, 24, pp. 1563-1574, http://dx.doi.org/10.3233/BME-140961