Reduced Burst Release of Bioactive rhBMP-2 from a Three-phase Composite Scaffold

Grant, David William

31 December 2010

Recombinant human bone morphogenic proteins (rhBMPs) are extensively studied and employed clinically for treatment of various bone defects. Current clinical delivery vehicles suffer wasteful burst releases that mandate supra-physiological dosing driving concerns over safety and cost. It was therefore investigated whether a unique drug delivery vehicle sequestered within a composite scaffold could lower the burst release of rhBMP-2. PLGA-calcium phosphate tri-phasic composite scaffolds delivered model protein BSA with burst release of ~13% and sustained kinetics of 0.5-1.5% BSA/day up to 45 days. rhBMP-2 was delivered with zero burst release however at much lower levels, totaling 0.09% to 0.9 % release over 10 days, but had up to 6.3-fold greater bioactivity than fresh rhBMP-2 (p<0.05). In conclusion, the three-phase composite scaffold can deliver bioactive proteins with a reduced burst release and sustained secondary kinetics.

Drug delivery

Bone

Bone morphogenic protein

BMP

BMP-2

rhBMP-2

bone graft

tissue engineering

scaffold

bone tissue engineering

regenerative medicine

osteoinduction

osteoconduction

osteogenesis

generative surgery

autoraft replacement

synthetic autograft replacement

morphogenic bioactivity assay

protein release kinetics

bovine serum albumin

model protein

biomaterials

biomaterial surface analysis

scanning electron microscope application

accelerating voltage application

burst release

sustained kinetics

sustained delivery

composite scaffold

three phase scaffold

PLGA

calcium phosphate

mineral-polymer composite

sterilization

BMP sterilization

long-term storage

BMP storage

0541

Reduced Burst Release of Bioactive rhBMP-2 from a Three-phase Composite Scaffold

Grant, David William

31 December 2010

Recombinant human bone morphogenic proteins (rhBMPs) are extensively studied and employed clinically for treatment of various bone defects. Current clinical delivery vehicles suffer wasteful burst releases that mandate supra-physiological dosing driving concerns over safety and cost. It was therefore investigated whether a unique drug delivery vehicle sequestered within a composite scaffold could lower the burst release of rhBMP-2. PLGA-calcium phosphate tri-phasic composite scaffolds delivered model protein BSA with burst release of ~13% and sustained kinetics of 0.5-1.5% BSA/day up to 45 days. rhBMP-2 was delivered with zero burst release however at much lower levels, totaling 0.09% to 0.9 % release over 10 days, but had up to 6.3-fold greater bioactivity than fresh rhBMP-2 (p<0.05). In conclusion, the three-phase composite scaffold can deliver bioactive proteins with a reduced burst release and sustained secondary kinetics.

Drug delivery

Bone

Bone morphogenic protein

BMP

BMP-2

rhBMP-2

bone graft

tissue engineering

scaffold

bone tissue engineering

regenerative medicine

osteoinduction

osteoconduction

osteogenesis

generative surgery

autoraft replacement

synthetic autograft replacement

morphogenic bioactivity assay

protein release kinetics

bovine serum albumin

model protein

biomaterials

biomaterial surface analysis

scanning electron microscope application

accelerating voltage application

burst release

sustained kinetics

sustained delivery

composite scaffold

three phase scaffold

PLGA

calcium phosphate

mineral-polymer composite

sterilization

BMP sterilization

long-term storage

BMP storage

0541