SYNTHETICALLY produced calcium phos

SYNTHETICALLY produced calcium phosphate ceramics and
implants have an important position among other biomaterials,
because they are considered to be almost fully biocompatible
with living bodies when replacing the hard bone tissues.
Calcium hydroxyapatite (Ca10(PO4)6(OH)2 (HA)) and tricalcium
phosphate (Ca3(PO4)2 (TCP)) are currently recognized as
ceramic materials that significantly simulate the mineralogical
structure of bone. HA and TCP bioceramic powders can be
synthesized by using techniques such as co-precipitation or
acid–base titration from aqueous solutions that contain calcium
nitrate (Ca(NO3)2) and diammonium hydrogen phosphate
((NH4)2HPO4). HA powders have been synthesized by using a
wet-chemical method, in aqueous solutions, by several researchers.
1–6 Aqueous solutions of Ca(NO3)2?4H2O and
(NH4)2HPO4 were selected as the starting materials in all the
above HA-precipitation studies. Single-phase TCP powders
have also been synthesized successfully by Tas¸ et al.,6 Akao et
al.,7 and Jarcho et al.8
Biphasic, composite calcium phosphate ceramics, until recently,
have only accidentally been encountered during the
synthesis studies of pure HA or pure b-TCP (whitlockite)
phases by the previous researchers. Masaki et al.9 studied thestability of the HA/b-TCP ceramics in vitro. Jarcho,10 Driessens,
11 LeGeros,12 and de Groot13 have claimed that HA ceramics
can be considered as bioactive and nonbiodegradable
bone-replacement materials. However, the nonbiodegradability
of HA, when used for alveolar ridge augmentation, is a disadvantage
to the host tissue that surrounds the HA. As a result,
b-TCP ceramics have been developed as a biodegradable bone
replacement.14 A material with ideal biodegradability would be
replaced by bone as it degraded. However, when used as a
biomaterial for alveolar ridge augmentation, the rate of biodegradation
of b-TCP has been shown to be too fast. To slow the
rate of biodegradation, biphasic calcium phosphate (BCP) ceramics
(i.e., composite ceramics that consist of mixtures of
both the HA and b-TCP phases) have been studied.15–21 However,
there is almost no information, in the relevant literature,
on the systematic procedures of HA–TCP composite powder
manufacture.To our knowledge, the study presented here becomes the
first systematic step taken in this field of biomaterials technology,
and it specifically describes the chemical powder synthesis
procedures of ‘‘HA–TCP composite bioceramics.’’ The
‘‘bioresorbable’’ nature of TCP in the chemically homogeneous
HA–TCP composite precursors and powders may serve
as the initial-matrix bioimplant material that will later induce
and undergo an in situ generation of different levels of porosity
and areas of new bone formation upon contact with the bodily
fluids, because of the complete resorption of the TCP phase.
The control to be gained over the phase constitution and biodegradability
of a calcium phosphate-based bioceramic implant
establishes the main driving force for this study.