Stephen Kustra scite author profile

Synthetic biodegradable elastomers are an emerging class of materials that play a critical role in supporting innovations in bioabsorbable medical implants. This work describes the synthesis and characterization of poly (glycerol-co-sebacate)-cinnamate (PGS-CinA), a biodegradable elastomer based on hyperbranched polyesters derivatized with pendant cinnamate groups. PGS-CinA can be prepared via photodimerization in the absence of photoinitiator using monomers that are found in common foods. The resulting network exhibits a Young’s modulus of 50.5 to 152.1 kPa and a projected in vitro degradation half-life time between 90 and 140 days. PGS-CinA elastomers are intrinsically cell adherent and support rapid proliferation of fibroblasts. Spreading and proliferation of fibroblasts are loosely governed by the substrate stiffness within the range of Young’s moduli in PGS-CinA networks that were prepared. The thermo-mechanical properties, biodegradability, and intrinsic support of cell attachment and proliferation suggest that PGS-CinA networks abroadly applicable for use in next generation bioabsorable materials including temporary medical devices and scaffolds for soft tissue engineering.

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Lithography-free fabrication of reconfigurable substrate topography for contact guidance

Pholpabu

Kustra

et al. 2015

Biomaterials

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Mammalian cells detect and respond to topographical cues presented in natural and synthetic biomaterials both in vivo and in vitro. Micro- and nano-structures influence the adhesion, morphology, proliferation, migration, and differentiation of many phenotypes. Although the mechanisms that underpin cell-topography interactions remain elusive, synthetic substrates with well-defined micro- and nano-structures are important tools to elucidate the origin of these responses. Substrates with reconfigurable topography are desirable because programmable cues can be harmonized with dynamic cellular responses. Here we present a lithography-free fabrication technique that can reversibly present topographical cues using an actuation mechanism that minimizes the confounding effects of applied stimuli. This method utilizes strain-induced buckling instabilities in bi-layer substrate materials with rigid uniform silicon oxide membranes that are thermally deposited on elastomeric substrates. The resulting surfaces are capable of reversible of substrates between three distinct states: flat substrates (A = 1.53 ± 0.55 nm, Rms = 0.317 ± 0.048 nm); parallel wavy grating arrays (A|| = 483.6 ± 7.8 nm and λ|| = 4.78 ± 0.16 μm); perpendicular wavy grating arrays (A⊥ = 429.3 ± 5.8 nm; λ⊥ = 4.95 ± 0.36 μm). The cytoskeleton dynamics of 3T3 fibroblasts in response to these surfaces was measured using optical microscopy. Fibroblasts cultured on dynamic substrates that are switched from flat to topographic features (FLAT-WAVY) exhibit a robust and rapid change in gross morphology as measured by a reduction in circularity from 0.30 ± 0.13 to 0.15 ± 0.08 after 5 min. Conversely, dynamic substrate sequences of FLAT-WAVY-FLAT do not significantly alter the gross steady-state morphology. Taken together, substrates that present topographic structures reversibly can elucidate dynamic aspects of cell-topography interactions.

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High‐Throughput Arrays for Rapid Characterization of Solution‐Processable Transparent Conducting Electrodes

Kustra

Basu

et al. 2012

Small

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Smart polymers and interfaces for dynamic cell-biomaterials interactions

Kustra

Bettinger

2012

MRS Bull.

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Stephen Kustra

Topographic substrates as strain relief features in stretchable organic thin film transistors

Photocrosslinkable biodegradable elastomers based on cinnamate-functionalized polyesters

Lithography-free fabrication of reconfigurable substrate topography for contact guidance

High‐Throughput Arrays for Rapid Characterization of Solution‐Processable Transparent Conducting Electrodes

Smart polymers and interfaces for dynamic cell-biomaterials interactions

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