While the reciprocity between bioceramics and living cells is complex, it is principally governed by the implant’s surface chemistry. Consequently, a deeper understanding of the chemical interactions of bioceramics with living tissue could ultimately lead to new therapeutic strategies. However, the physical and chemical principles that govern these interactions remain unclear. The intricacies of this biological synergy are explored within this paper by examining the peculiar surface chemistry of a relatively new bioceramic, silicon nitride (Si3N4). Building upon prior research, this paper aims at obtaining new insights into the biological interactions between Si3N4 and living cells, as a consequence of the off-stoichiometric chemical nature of its surface at the nanometer scale. We show here yet unveiled details of surface chemistry and, based on these new data, formulate a model on how, ultimately, Si3N4 influences cellular signal transduction functions and differentiation mechanisms. In other words, we interpret its reciprocity with living cells in chemical terms. These new findings suggest that Si3N4 might provide unique new medicinal therapies and effective remedies for various bone or joint maladies and diseases.
Osteosarcoma
cell viability, proliferation, and differentiation
into osteoblasts on a silicon nitride bioceramic were examined as
a function of chemical modifications of its as-fired surface. Biological
and spectroscopic analyses showed that (i) postsintering annealing
in N2 gas significantly improved apatite formation from
human osteosarcoma (SaOS-2) cells; (ii) in situ Raman spectroscopic
monitoring revealed new metabolic details of the SaOS-2 cells, including
fine differences in intracellular RNA and membrane phospholipids;
and (iii) the enhanced apatite formation originated from a high density
of positively charged surface groups, including both nitrogen vacancies
(VN
3+) and nitrogen N–N bonds (N4
+) formed during annealing in N2 gas.
At homeostatic pH, these positive surface charges promoted binding
of proteins onto an otherwise negatively charged surface of deprotonated
silanols (SiO–). A dipole-like electric-charge,
which includes VN
3+/N4
+ and SiO– defective sites, is proposed as a mechanism
to explain the attractive forces between transmembrane proteins and
the COO– and NH2+ termini, respectively.
This is analogous to the mechanism occurring in mineral hydroxyapatite
where protein groups are specifically displaced by the presence of
positively charged calcium loci (Ca+) and off-stoichiometry
phosphorus sites (PO4
2–).
Polyetheretherketone (PEEK) is a popular polymeric biomaterial which is primarily used as an intervertebral spacer in spinal fusion surgery; but it is developed for trauma, prosthodontics, maxillofacial, and cranial implants. It has the purported advantages of an elastic modulus which is similar to native bone and it can be easily formed into custom 3D shapes. Nevertheless, PEEK's disadvantages include its poor antibacterial resistance, lack of bioactivity, and radiographic transparency. This study presents a simple approach to correcting these three shortcomings while preserving the base polymer's biocompatibility, chemical stability, and elastic modulus. The proposed strategy consists of preparing a PEEK composite by dispersing a minor fraction (i.e., 15 vol%) of a silicon nitride (Si N ) powder within its matrix. In vitro tests of PEEK composites with three Si N variants-β-Si N , α-Si N , and β-SiYAlON-demonstrate significant improvements in the polymer's osteoconductive versus SaOS-2 cells and bacteriostatic properties versus gram-positive Staphylococcus epidermidis bacteria. These properties are clearly a consequence of adding the bioceramic dispersoids, according to chemistry similar to that previously demonstrated for bulk Si N ceramics in terms of osteogenic behavior (vs both osteosarcoma and mesenchymal progenitor cells) and antibacterial properties (vs both gram-positive and gram-negative bacteria).
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