Your search keyword '"Reilly, G.C."' showing total 2 results

1. Composite porous scaffold of PEG/PLA support improved bone matrix deposition in vitro compared to PLA‐only scaffolds

Author

Bhaskar, B., Owen, R., Bahmaee, H., Wally, Z., Sreenivasa Rao, P., and Reilly, G.C.

Subjects

technology, industry, and agriculture, macromolecular substances, equipment and supplies

Abstract

Controllable pore size and architecture are essential properties for tissue-engineering scaffolds to support cell ingrowth colonization. To investigate the effect of PEG addition on porosity and bone-cell behavior, porous Polylactic acid (PLA)-Polyethylene glycol (PEG) scaffolds were developed with varied weight ratios of PLA-PEG (100/0, 90/10, 75/25) using solvent casting and porogen leaching. Sugar 200-300 µm in size was used as a porogen. To assess their suitability for bone tissue engineering, MLO-A5 murine osteoblast cells were cultured and cell metabolic activity, alkaline phosphatase (ALP) activity and bone-matrix production determined (alizarin red S staining for calcium, direct red 80 staining for collagen). It was found that metabolic activity was significantly higher over time on scaffolds containing PEG, ALP activity and mineralized matrix production were also significantly higher on scaffolds containing 25% PEG. Porous architecture and cell distribution and penetration into the scaffold were analyzed using SEM and confocal microscopy, revealing that inclusion of PEG increased pore interconnectivity and therefore cell ingrowth in comparison to pure PLA scaffolds. The results of this study confirmed that PLA-PEG porous scaffolds support mineralizing osteoblasts better than pure PLA scaffolds, indicating they have a high potential for use in bone tissue engineering applications. This article is protected by copyright. All rights reserved.

Published

2018

2. Nanoscopic mechanical anisotropy in hydrogel surfaces

Author

Flores-Merino, M.V., Chirasatitsin, S., LoPresti, C., Reilly, G.C., Battaglia, G., and Engler, A.J.

Subjects

technology, industry, and agriculture, macromolecular substances

Abstract

The bulk mechanical properties of soft materials have been studied widely, but it is unclear to what extent macroscopic behavior is reflected in nanomechanics. Using an atomic force microscopy (AFM) imaging method called force spectroscopy mapping (FSM), it is possible to map the nanoscopic spatial distribution of Young's modulus, i.e. “stiffness,” and determine if soft or stiff polymer domains exist to correlate nano- and macro-mechanics. Two model hydrogel systems typically used in cell culture and polymerized by a free radical polymerization process, i.e. poly (vinyl pyrrolidone) (PVP) and poly(acrylamide) (PAam) hydrogels, were found to have significantly different nanomechanical behavior despite relatively similar bulk stiffness and roughness. PVP gels contained a large number of soft and stiff nanodomains, and their size was inversely related to crosslinking density and changes in crosslinking efficiency within the hydrogel. In contrast, PAam gels displayed small nanodomains occuring at low frequency, indicating relatively uniform polymerization. Given the responsiveness of cells to changes in gel stiffness, inhomogeneities found in the PVP network indicate that careful nanomechanical characterization of polymer substrates is necessary to appreciate complex cell behavior.

Published

2010