TY - JOUR
T1 - Hydroxyapatite bone substitutes developed via replication of natural marine sponges
AU - Cunningham, Eoin
AU - Dunne, Nicholas
AU - Walker, Gavin
AU - Maggs, Christine
AU - Wilcox, Ruth
AU - Buchanan, Fraser
N1 - Publisher Copyright:
© Springer Science+Business Media, LLC 2009.
PY - 2010/8
Y1 - 2010/8
N2 - The application of synthetic cancellous bone has been shown to be highly successful when its architecture mimics that of the naturally interconnected trabeculae bone it aims to replace. The following investigation demonstrates the potential use of marine sponges as precursors in the production of ceramic based tissue engineered bone scaffolds. Three species of natural sponge, Dalmata Fina (Spongia officinalis Linnaeus, Adriatic Sea), Fina Silk (Spongia zimocca, Mediterranean) and Elephant Ear (Spongia agaricina, Caribbean) were selected for replication. A high solid content (80 %wt), low viscosity (126 mPas) hydroxyapatite slurry was developed, infiltrated into each sponge species and subsequently sintered, producing a scaffold structure that replicated pore architecture and interconnectivity of the precursor sponge. The most promising of the ceramic tissue engineered bone scaffolds developed, Spongia agaricina replicas, demonstrated an overall porosity of 56–61% with 83% of the pores ranging between 100 and 500 μ (average pore size 349 μ) and an interconnectivity of 99.92%.
AB - The application of synthetic cancellous bone has been shown to be highly successful when its architecture mimics that of the naturally interconnected trabeculae bone it aims to replace. The following investigation demonstrates the potential use of marine sponges as precursors in the production of ceramic based tissue engineered bone scaffolds. Three species of natural sponge, Dalmata Fina (Spongia officinalis Linnaeus, Adriatic Sea), Fina Silk (Spongia zimocca, Mediterranean) and Elephant Ear (Spongia agaricina, Caribbean) were selected for replication. A high solid content (80 %wt), low viscosity (126 mPas) hydroxyapatite slurry was developed, infiltrated into each sponge species and subsequently sintered, producing a scaffold structure that replicated pore architecture and interconnectivity of the precursor sponge. The most promising of the ceramic tissue engineered bone scaffolds developed, Spongia agaricina replicas, demonstrated an overall porosity of 56–61% with 83% of the pores ranging between 100 and 500 μ (average pore size 349 μ) and an interconnectivity of 99.92%.
UR - http://www.scopus.com/inward/record.url?scp=84928537972&partnerID=8YFLogxK
U2 - 10.1007/s10856-009-3961-4
DO - 10.1007/s10856-009-3961-4
M3 - Article
C2 - 20012771
AN - SCOPUS:84928537972
SN - 0957-4530
VL - 21
SP - 2255
EP - 2261
JO - Journal of Materials Science: Materials in Medicine
JF - Journal of Materials Science: Materials in Medicine
IS - 8
ER -