Z. Ilke Kalcioglu scite author profile

Both human embryonic stem (hES) cells and induced pluripotent stem (hiPS) cells can self-renew indefinitely in culture, however current methods to clonally grow them are inefficient and poorly-defined for genetic manipulation and therapeutic purposes. Here we develop the first chemically-defined, xeno-free, feeder-free synthetic substrates to support robust self-renewal of fully-dissociated hES and hiPS cells. Materials properties including wettability, surface topography, surface chemistry and indentation elastic modulus of all polymeric substrates were quantified using high-throughput methods to develop structure/function relationships between materials properties and biological performance. These analyses show that optimal hES cell substrates are generated from monomers with high acrylate content, have a moderate wettability, and employ integrin αvβ3 and αvβ5 engagement with adsorbed vitronectin to promote colony formation. The structure/function methodology employed herein provides a general framework for the combinatorial development of synthetic substrates for stem cell culture.

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From macro- to microscale poroelastic characterization of polymeric hydrogels via indentation

Kalcioglu

et al. 2012

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Electrochemically Controlled Swelling and Mechanical Properties of a Polymer Nanocomposite

Schmidt¹,

Cebeci²,

Kalcioglu³

et al. 2009

ACS Nano

129

110

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We present the layer-by-layer assembly of an electroactive polymer nanocomposite thin film containing cationic linear poly(ethyleneimine) (LPEI) and 68 vol % anionic Prussian Blue (PB) nanoparticles, which allow for electrochemical control over film thickness and mechanical properties. Electrochemical reduction of the PB doubles the negative charge on the particles, causing an influx of water and ions from solution to maintain electroneutrality in the film; concomitant swelling and increased elastic compliance of the film result. Reversible swelling upon reduction is on the order of 2-10%, as measured via spectroscopic ellipsometry and electrochemical atomic force microscopy. Reversible changes in the Young's elastic modulus of the hydrated composite film upon reduction are on the order of 50% (from 3.40 to 1.75 GPa) as measured with in situ nanoindentation, and a qualitative increase in viscous contributions to energy dissipation upon redox is indicated by electrochemical quartz crystal microbalance. Electrochemical stimuli maintain a mild operating environment and can be applied rapidly, reversibly, and locally. We maintain that electrochemical control over the swelling and mechanical behavior of polymer nanocomposites could have important implications for responsive coatings of nanoscale devices, including mechanically tunable surfaces to modulate behavior of adherent cells.

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Marrow‐Derived stem cell motility in 3D synthetic scaffold is governed by geometry along with adhesivity and stiffness

Peyton

Kalcioglu

Cohen

et al. 2011

Biotech & Bioengineering

105

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Design of 3D scaffolds that can facilitate proper survival, proliferation, and differentiation of progenitor cells is a challenge for clinical applications involving large connective tissue defects. Cell migration within such scaffolds is a critical process governing tissue integration. Here, we examine effects of scaffold pore diameter, in concert with matrix stiffness and adhesivity, as independently tunable parameters that govern marrow-derived stem cell motility. We adopted an “inverse opal” processing technique to create synthetic scaffolds by crosslinking poly(ethylene glycol) at different densities (controlling matrix elastic moduli or stiffness) and small doses of a heterobifunctional monomer (controlling matrix adhesivity) around templating beads of different radii. As pore diameter was varied from 7 to 17 µm (i.e., from significantly smaller than the spherical cell diameter to approximately cell diameter), it displayed a profound effect on migration of these stem cells—including the degree to which motility was sensitive to changes in matrix stiffness and adhesivity. Surprisingly, the highest probability for substantive cell movement through pores was observed for an intermediate pore diameter, rather than the largest pore diameter, which exceeded cell diameter. The relationships between migration speed, displacement, and total path length were found to depend strongly on pore diameter. We attribute this dependence to convolution of pore diameter and void chamber diameter, yielding different geometric environments experienced by the cells within.

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Z. Ilke Kalcioglu

Combinatorial development of biomaterials for clonal growth of human pluripotent stem cells

From macro- to microscale poroelastic characterization of polymeric hydrogels via indentation

Electrochemically Controlled Swelling and Mechanical Properties of a Polymer Nanocomposite

Marrow‐Derived stem cell motility in 3D synthetic scaffold is governed by geometry along with adhesivity and stiffness

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