Tailoring Surface Properties through in Situ Functionality Gradients in Reactively Modified Poly(2-vinyl-4,4-dimethyl azlactone) Thin Films.

Generating physical or chemical gradients in thin-film scaffolds is an efficient approach for screening and optimizing an interfacial structure or chemical functionality to create tailored surfaces that are useful because of their wetting, antifouling, or barrier properties. The relationship between the structure of poly(2-vinyl-4,4-dimethyl azlactone) (PVDMA) brushes created by the preferential assembly of poly(glycidyl methacrylate)- block-PVDMA diblock copolymers and the ability to chemically modify the PVDMA chains in situ to create a gradient in functionality are examined to investigate how the extent of functionalization affects the interfacial and surface properties. The introduction of a chemical gradient by controlled immersion allows reactive modification to generate position-dependent properties that are assessed by ellipsometry, attenuated total reflectance-Fourier transform infrared spectroscopy, contact angle measurements, and atomic force microscopy imaging. After functionalization of the azlactone rings with n-alkyl amines, ellipsometry confirms an increase in thickness and contact angle measurements support an increase in hydrophobicity along the substrate. These results are used to establish relationships between layer thickness, reaction time, position, and the extent of functionalization and demonstrate that gradual immersion into the functionalizing solution results in a linear change in chemical functionality along the surface. These findings broadly support efforts to produce tailored surfaces by in situ chemical modification, having application as tailored membranes, protein resistant surfaces, or sensors.

Effect of amine content and chemistry on long-term, three-dimensional hepatocyte spheroid culture atop aminated elastin-like polypeptide coatings.

Culture conditions that induce hepatic spheroidal aggregates sustain liver cells with metabolism that mimics in vivo hepatocytes. Here we present an array of elastin-like polypeptide conjugate coating materials (Aminated-ELPs) that are biocompatible, have spheroid-forming capacity, can be coated atop traditional culture surfaces, and maintain structural integrity while ensuring adherence of spheroids over long culture period. The Aminated-ELPs were synthesized either by direct conjugation of ELP and various polyelectrolytes or by conjugating both ELP and various small electrolytes to the reactive polymer poly(2-vinyl-4,4-dimethyl azlactone) (PVDMA). Spheroid morphology, cellular metabolic function, and liver-specific gene expression over the long-term, 20-day culture period were assessed through optical microscopy, measurement of total protein content and albumin and urea production, and quantitative real-time (qRT) PCR. We found that the amine content of the Aminated-ELP coatings dictated the initial hepatocyte attachment, but not the subsequent hepatocyte spheroid formation and their continued attachment. A lower amine content was generally found to sustain higher albumin production by the spheroids. Out of the 19 Aminated-ELP coatings tested, we found that the lysine-containing substrates comprising ELP-polylysine or ELP-PVDMA-butanediamine proved to consistently culture productive spheroidal hepatocytes. We suggest that the incorporation of lysine functional groups in Aminated-ELP rendered more biocompatible surfaces, increasing spheroid attachment and leading to increased liver-specific function. Taken together, the Aminated-ELP array presented here has the potential to create in vitro hepatocyte culture models that mimic in vivo liver functionality and thus, lead to better understanding of liver pathophysiology and superior screening methods for drug efficacy and toxicity. © 2016 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 105A: 377-388, 2017.

Synthesis and Characterization of an Array of Elastin-like Polypeptide-Polyelectrolyte Conjugates with Varying Chemistries and Amine Content for Biomedical Applications.

Many structural variants of elastin-like polypeptides (ELPs), the genetically engineered equivalents of part of human elastin, currently are being investigated for drug delivery and tissue engineering. Here, we report preparation of six different aminated ELP conjugates via two strategies. In the first, a direct linking strategy was used to couple hydrophobic ELP with either polyethyleneimine, polylysine, or polyarginine. In the second, conjugates were made by attaching ELP onto the reactive polymer, poly(2-vinyl-4,4-dimethyl azlactone), and then exhaustively reacting residual azlactone groups with either ethylenediamine, 1,4-butanediamine, or arginine. Molecular size and chemistry of the resulting six aminated-ELP conjugates were confirmed through gel electrophoresis, FTIR spectroscopy, and mass spectrometry. Dynamic light scattering analysis showed that the conjugates prepared using the "direct reaction scheme" formed small aggregates as well as retained their inverse volume-phase transition temperature behavior. The conjugates prepared using the "reactive polymer linker scheme" also retained this transition temperature behavior. o-Phthalaldehyde assay was used to measure the relative primary amine content of the ELP conjugates. Overall, we prepared an array of aminated-ELPs with independently varying amine content and chemistry (i.e., the same amine content for different materials and different amine contents for the same material). Synthesis of such amphiphilic ELP structures that otherwise cannot be prepared through genetic engineering has the potential to further extend the versatility of the ELPs for many biomedical applications.