Ti alloys are commonly employed for making bone plates (Fadli et al. 2019).
However, the use of metals becomes limited due to their poor biocompatibility
with their hosts as well as limited organ function and influence on the bioactivity
in the body. Metals also cannot regenerate new bone. In addition, when interacting
with the host tissue, the corrosion products of the metals cause severe infection and
implant failure. Biomaterials or bioceramics including hydroxyapatite coating on the
metal surface possess great potential to overcome these drawbacks. Hydroxyapatite
plays a double task of inhibiting the release of metal ions, making the metallic
implant more corrosion resistant and also promoting bioactivity at the metal surface
(Sridhar et al. 1997).
The results of uncoated and coated 316L stainless steel implant with HA and
ZnFHA are presented in Tables 23.11 and 23.12. Table 23.11 compares the corro-
sion parameters from potentiodynamic polarization tests, and Table 23.12 compares
the pitting corrosion characteristics for uncoated and coated 316L stainless steel.
ZnFHA coated 316 stainless steel implant displayed lower corrosion rate, pitting
resistance than uncoated and HA coated 316L stainless steel. The corrosion resis-
tance of ZnFHA coated 316L stainless steel was found to be 115 times better than
316L stainless steel implant. The coating and passive layer both play a role in
corrosion resistance.
Figure 23.11 shows the SEM micrograph of ZnFHA coated 316L stainless steel.
Figure 23.12 displays the apatite formation on ZnFHA coating on immersion in
SBF, indicating the bioactive behavior of coating. Therefore, ZnFHA coated 316L
stainless steel can be a good candidate for bio-implant applications especially in
bone repairs in dental and orthopedics and osteoporosis treatment.
Table 23.11 Corrosion parameters from potentiodynamic polarization tests
Sample
OCP
(V)
ba
(V/decade)
bc
(V/decade)
Ecorr
(V)
jcorr
(μA/
cm2)
Corrosion rate
(mm/year)
Uncoated-
316L SS