Correlating cell morphology and osteoid mineralization relative to strain profile for bone tissue engineering applications

Wood, Mairead A.; Yang, Ying; Baas, Elbert; Meredith, D.O.; Richards, R. Geoff; Kuiper, Jan Herman; Haj, Alicia J. El

doi:10.1098/rsif.2007.1265

Cited by 5 publications

(2 citation statements)

References 25 publications

(28 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…At day 7, cell morphology on Chi coatings are spindle with thin pseudopods and prolonged thread-like morphology; however, cells on nanotopographical MBGN-0.50 composite coatings are dumbbell-like in shape during spreading. These cell morphologies indicate the fully differentiated osteoblasts embedded in the bone matrix . Previously, we have reported that presence of small amount of BGN in coatings significantly improved the in vitro apatite-forming ability and osteogenic differentiation …”

Section: Resultsmentioning

confidence: 60%

Combined Effects of Nanoroughness and Ions Produced by Electrodeposition of Mesoporous Bioglass Nanoparticle for Bone Regeneration

Patel

Buitrago

Parthiban

et al. 2019

ACS Appl. Bio Mater.

View full text Add to dashboard Cite

Providing appropriate biophysical and biochemical cues to the interface is a facile strategy to enhance the osteogenic ability of metallic implants. Here we exploited this through the incorporation of mesoporous bioactive glass nanoparticles (MBGN) at a high content (1:1 by weight) to a biopolymer chitosan in the electrodeposition process of titanium. The MGBN/chitosan layer thickness, tunable by electrodeposition parameters, exhibited an accelerated ability of apatite mineral induction in a body simulating medium. Of note, the involvement of MBGN could generate nanoscale roughness in a unique range of 10 ~ 25 nm.Moreover, the layer showed a slowly releasing profile of ions (calcium and silicate) over weeks at therapeutically relevant doses. The ion-releasing nanotopological surface was demonstrated to alter the pre-osteoblasts responses in a way favorable for the osteogenic differentiation. The combinatory cues of nanotopology (25 nm roughness) and ion release enabled highly accelerated cellular anchorage with somewhat limited spreading area at initial periods. The subsequent osteoblastic differentiation behaviors on the engineered surface, as examined up to 21 days, showed significantly enhanced alkaline phosphate activity and up-regulated expression of bone-associated genes (ALP, Col I, OPN, and OCN).These results indicate that the combinatory cues provided by nanotopology (25 nm roughness) and ions released from MBGN are highly effective in stimulating osteoblastic differentiation and that suggest the MBGN/chitosan may serve as a potential composition for bone implant coatings.

show abstract

Section: Resultsmentioning

confidence: 60%

Combined Effects of Nanoroughness and Ions Produced by Electrodeposition of Mesoporous Bioglass Nanoparticle for Bone Regeneration

Patel

Buitrago

Parthiban

et al. 2019

ACS Appl. Bio Mater.

View full text Add to dashboard Cite

show abstract

“…The authors have designed a model system to investigate the effects of strain profile on bone cell behaviour within a pore. This simplified model has been designed with a view to providing insight into the types of strain distribution occurring across a single pore of a scaffold subjected to perfusion compression conditioning [25]. These studies demonstrated a direct correlation between stress applied and the mineralization of the matrix surrounding the cells within a pore.…”

Section: Compression Systemsmentioning

confidence: 99%

Bioreactors for bone tissue engineering

Haj

Cartmell

2010

Proc Inst Mech Eng H

View full text Add to dashboard Cite

Engineering bone tissue for use in orthopaedics poses multiple challenges. Providing the appropriate growth environment that will allow complex tissues such as bone to grow is one of these challenges. There are multiple design factors that must be considered in order to generate a functional tissue in vitro for replacement surgery in the clinic. Complex bioreactors have been designed that allow different stress regimes such as compressive, shear, and rotational forces to be applied to three-dimensional (3D) engineered constructs. This review addresses these considerations and outlines the types of bioreactor that have been developed and are currently in use.

show abstract