23.3.1.2 Dual-Ion Substitution in HA
Dual-ion substitution is being regarded as a promising approach for enhancing
biological and physicochemical properties of HA. Primarily, both of the two
substituted ions are cations (Lowry et al. 2018; Robinson et al. 2017), whereas in
some cases the anion/anion (Landi et al. 2010; Fahami et al. 2016) and anion/cation
(Kumar et al. 2012; Kolmas et al. 2011) combinations have also been explored.
When two or more ions are present, they can have a synergistic or antagonistic effect
on properties of HA. It has been found that when Mg2+ and CO3
2� are co-substituted
in HA, there is a synergistic effect on the dissolution properties and crystallinity,
whereas when CO3
2� and F� are co-substituted in HA, there is an antagonistic effect
and F� is more dominant.
Zn2+ and Mg2+ co-substitution in HA enhances bone formation (Kaygili and
Keser 2015). Zn2+ ions are found to be more favorably substituted into Ca site in HA
as compared to Mg. With an increase in the content of Mg2+ and Zn2+, crystallinity,
cell parameters, and unit cell volume of HA decrease drastically and also show an
improved biocompatibility. In vitro studies demonstrated a notable improvement in
cell proliferation, attachment, and adhesion in comparison to stoichiometric
HA. Lowry et al. (2017) and Ullah et al. (2020) successfully substituted Zn and Sr
ions in HA by various methods. Zn2+ partially substituted for Ca2+, whereas Sr2+ got
completely substituted for Ca2+.
In vitro studies in human osteoblast-like MG63 cells for HA co-substituted with
Sr and Mg (SrMgHA) displayed an enhanced cell attachment, proliferation, and
differentiation (Geng et al. 2016). Landi et al. (2013) studied the extended release of
Mg during the bone regeneration process and also studied the anti-osteoporotic and
anticaries properties of Sr ion in SrMgHA. Yoruc and Aydinoglu (2017) synthesized
Na- and Mg-substituted HA by a precipitation technique. The in vitro study revealed
an improved bioactive behavior, as the growth of osteoblast cells was encouraging.
Dual
substitution
of
anions
presents
another
way
to
improve
the
cytocompatibility of HA. Investigations have been carried out with various
combinations of anions including Cl�, F�, and CO3
2�. Fahami et al. (2016) found
that the co-substitution of F� and Cl� in HA could counteract probable side effect of
Cl�, e.g., dementia in elderly patients. They also found that the addition of F� could
improve the differentiation and proliferation of bone cells.
The cation-anion co-substitution in HA can influence its morphology, lattice
parameters, crystallinity, and crystallite size. Douglas et al. (2017) observed
enhanced dissolution and reduced crystallinity in the case of CO3
2� and Mg2+
co-substituted HA. When carbonates are co-substituted with Sr2+ or Zn2+, bone
remodeling is enhanced. The combination of Zn and carbonate in HA hinders the
crystal growth. The dual substitution of CO3
2� and Sr2+ in HA helps in combining
bioactivity of carbonate and therapeutic function of Sr2+ to enhance the new bone
formation rate and osteointegration (Landi et al. 2008; Kumar et al. 2012).
With an increase in CO3
2� and Na+ content, the crystallite size of CO3
2� and Na+
co-substituted HA decreases (Zyman and Tkachenko 2013). The Sr and Si
co-substitution in HA helps in the substitution levels of both the elements.
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