Spatial control of bone formation using a porous polymer scaffold co-delivering anabolic rhBMP-2 and anti-resorptive agents

Spatial control of bone formation using a porous polymer scaffold co-delivering anabolic rhBMP-2 and anti-resorptive agents

Current clinical delivery of recombinant human bone morphogenetic proteins (rhBMPs) utilises freeze-dried collagen. Despite effective new bone generation, rhBMP via collagen can be limited by significant complications due to inflammation and uncontrolled bone formation. This study aimed to produce a...

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Main Authors: NYC Yu, M Gdalevitch, CM Murphy, K Mikulec, L Peacock, J Fitzpatrick, LC Cantrill, AJ Ruys, JJ Cooper-White, DG Little, A Schindeler
Format: Article
Language:English
Published: AO Research Institute Davos 2014-01-01
Series:European Cells & Materials
Online Access:http://www.ecmjournal.org/papers/vol027/pdf/v027a08.pdf
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spelling doaj-012f0c2b531f480399ffedff63def9612020-11-24T23:53:51Zeng AO Research Institute DavosEuropean Cells & Materials1473-22622014-01-01279811110.22203/eCM.v027a08Spatial control of bone formation using a porous polymer scaffold co-delivering anabolic rhBMP-2 and anti-resorptive agentsNYC Yu0M GdalevitchCM MurphyK MikulecL PeacockJ Fitzpatrick LC CantrillAJ RuysJJ Cooper-WhiteDG LittleA SchindelerOrthopaedic Research & Biotechnology, Research Building, The Children's Hospital at Westmead, Locked Bag 4001, Westmead, NSW 2145, AustraliaCurrent clinical delivery of recombinant human bone morphogenetic proteins (rhBMPs) utilises freeze-dried collagen. Despite effective new bone generation, rhBMP via collagen can be limited by significant complications due to inflammation and uncontrolled bone formation. This study aimed to produce an alternative rhBMP local delivery system to permit more controllable and superior rhBMP-induced bone formation. Cylindrical porous poly(lactic-co-glycolic acid) (PLGA) scaffolds were manufactured by thermally-induced phase separation. Scaffolds were encapsulated with anabolic rhBMP-2 (20 µg) ± anti-resorptive agents: zoledronic acid (5 µg ZA), ZA pre-adsorbed onto hydroxyapatite microparticles, (5 µg ZA/2 % HA) or IkappaB kinase (IKK) inhibitor (10 µg PS-1145). Scaffolds were inserted in a 6-mm critical-sized femoral defect in Wistar rats, and compared against rhBMP-2 via collagen. The regenerate region was examined at 6 weeks by 3D microCT and descriptive histology. MicroCT and histology revealed rhBMP-induced bone was more restricted in the PLGA scaffolds than collagen scaffolds (-92.3 % TV, p < 0.01). The regenerate formed by PLGA + rhBMP-2/ZA/HA showed comparable bone volume to rhBMP-2 via collagen, and bone mineral density was +9.1 % higher (p < 0.01). Local adjunct ZA/HA or PS-1145 significantly enhanced PLGA + rhBMP-induced bone formation by +78.2 % and +52.0 %, respectively (p ≤ 0.01). Mechanistically, MG-63 human osteoblast-like cells showed cellular invasion and proliferation within PLGA scaffolds. In conclusion, PLGA scaffolds enabled superior spatial control of rhBMP-induced bone formation over clinically-used collagen. The PLGA scaffold has the potential to avoid uncontrollable bone formation-related safety issues and to customise bone shape by scaffold design. Moreover, local treatment with anti-resorptive agents incorporated within the scaffold further augmented rhBMP-induced bone formation.http://www.ecmjournal.org/papers/vol027/pdf/v027a08.pdf
collection DOAJ
language English
format Article
sources DOAJ
author NYC Yu
M Gdalevitch
CM Murphy
K Mikulec
L Peacock
J Fitzpatrick
LC Cantrill
AJ Ruys
JJ Cooper-White
DG Little
A Schindeler
spellingShingle NYC Yu
M Gdalevitch
CM Murphy
K Mikulec
L Peacock
J Fitzpatrick
LC Cantrill
AJ Ruys
JJ Cooper-White
DG Little
A Schindeler
Spatial control of bone formation using a porous polymer scaffold co-delivering anabolic rhBMP-2 and anti-resorptive agents
European Cells & Materials
author_facet NYC Yu
M Gdalevitch
CM Murphy
K Mikulec
L Peacock
J Fitzpatrick
LC Cantrill
AJ Ruys
JJ Cooper-White
DG Little
A Schindeler
author_sort NYC Yu
title Spatial control of bone formation using a porous polymer scaffold co-delivering anabolic rhBMP-2 and anti-resorptive agents
title_short Spatial control of bone formation using a porous polymer scaffold co-delivering anabolic rhBMP-2 and anti-resorptive agents
title_full Spatial control of bone formation using a porous polymer scaffold co-delivering anabolic rhBMP-2 and anti-resorptive agents
title_fullStr Spatial control of bone formation using a porous polymer scaffold co-delivering anabolic rhBMP-2 and anti-resorptive agents
title_full_unstemmed Spatial control of bone formation using a porous polymer scaffold co-delivering anabolic rhBMP-2 and anti-resorptive agents
title_sort spatial control of bone formation using a porous polymer scaffold co-delivering anabolic rhbmp-2 and anti-resorptive agents
publisher AO Research Institute Davos
series European Cells & Materials
issn 1473-2262
publishDate 2014-01-01
description Current clinical delivery of recombinant human bone morphogenetic proteins (rhBMPs) utilises freeze-dried collagen. Despite effective new bone generation, rhBMP via collagen can be limited by significant complications due to inflammation and uncontrolled bone formation. This study aimed to produce an alternative rhBMP local delivery system to permit more controllable and superior rhBMP-induced bone formation. Cylindrical porous poly(lactic-co-glycolic acid) (PLGA) scaffolds were manufactured by thermally-induced phase separation. Scaffolds were encapsulated with anabolic rhBMP-2 (20 µg) ± anti-resorptive agents: zoledronic acid (5 µg ZA), ZA pre-adsorbed onto hydroxyapatite microparticles, (5 µg ZA/2 % HA) or IkappaB kinase (IKK) inhibitor (10 µg PS-1145). Scaffolds were inserted in a 6-mm critical-sized femoral defect in Wistar rats, and compared against rhBMP-2 via collagen. The regenerate region was examined at 6 weeks by 3D microCT and descriptive histology. MicroCT and histology revealed rhBMP-induced bone was more restricted in the PLGA scaffolds than collagen scaffolds (-92.3 % TV, p < 0.01). The regenerate formed by PLGA + rhBMP-2/ZA/HA showed comparable bone volume to rhBMP-2 via collagen, and bone mineral density was +9.1 % higher (p < 0.01). Local adjunct ZA/HA or PS-1145 significantly enhanced PLGA + rhBMP-induced bone formation by +78.2 % and +52.0 %, respectively (p ≤ 0.01). Mechanistically, MG-63 human osteoblast-like cells showed cellular invasion and proliferation within PLGA scaffolds. In conclusion, PLGA scaffolds enabled superior spatial control of rhBMP-induced bone formation over clinically-used collagen. The PLGA scaffold has the potential to avoid uncontrollable bone formation-related safety issues and to customise bone shape by scaffold design. Moreover, local treatment with anti-resorptive agents incorporated within the scaffold further augmented rhBMP-induced bone formation.
url http://www.ecmjournal.org/papers/vol027/pdf/v027a08.pdf
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