Molecular basis of cell-biomaterial interaction: insights gained from transcriptomic and proteomic studies.

With the growing interest in clinical interventions that involve medical devices, the role for new biomaterials in modern medicine is currently expanding at a phenomenal rate. Failure of most implant materials stems from an inability to predict and control biological phenomena, such as protein adsorption and cell interaction, resulting in an inappropriate host response to the materials. Contemporary advances in biological investigation are starting to shift focus in the biomaterials field, in particular with the advent of high-throughput methodologies for gene and protein expression profiling. Here, we examine the role that emerging transcriptomic and proteomic technologies could play in relation to biomaterial development and usage. Moreover, a number of studies are highlighted which have utilized such approaches in order to try to create a deeper understanding of cell-biomaterial interactions and, hence, improve our ability to predict and control the biocompatibility of new materials.

Surface-induced changes in protein adsorption and implications for cellular phenotypic responses to surface interaction.

Understanding external factors that determine cellular phenotypic responses is of key interest in the field of biomaterials. Currently, material surface characteristics, protein adsorption and cellular phenotypic responses are all considered to be interrelated and ultimately determine the biocompatibility of materials. The exact nature of the relationship between these distinct, yet related, phenomena still remains to be elucidated. Through the use of a series of thermoresponsive N-isopropylacrylamide-based co-polymer films, we aimed to shed light on the relationship between surface hydrophobicity, protein adsorption and subsequent cellular response. Despite changes in co-polymer hydrophobicity mediated by altered ratios of constituent monomers, differential cellular response was only apparent in the presence of serum. Co-polymer films displayed alterations with respect to the amount of protein adsorbed on the surface, with individual serum proteins (albumin and fibronectin) displaying contrasting adsorption characteristics. Changes in protein adsorption corresponded to changes in cell adhesion, cytoskeletal organisation and cell morphology, as well as to changes in cell movement and intracellular signalling events. Examination of focal adhesion kinase (FAK), and extracellular signal-regulated kinase (ERK 1/2), important mediators of adhesion and growth factor-related signalling events, revealed a comparative reduction in phosphorylation of these signalling proteins in cells grown on co-polymers in comparison to those cultured on tissue culture polystyrene (TCP; used as a control surface). We also associated surface-mediated phenotypic alterations of cells grown on TCP and co-polymer films with particular changes in gene expression. These results indicate that cellular response to interaction with our series of co-polymer films is determined by the surface-adsorbed protein layer, which in turn is determined by the changing surface chemistry as the ratio of the co-monomers is altered.

Poly(N-isopropylacrylamide) co-polymer films as potential vehicles for delivery of an antimitotic agent to vascular smooth muscle cells.

INTRODUCTION: Local delivery of antimitotic agents is a potential therapeutic strategy for protection of injured coronary vasculature against intimal hyperplasia and restenosis. This study sought to establish the principle that thermoresponsive poly(N-isopropylacrylamide) co-polymer films can be used to deliver, in a controlled manner, an antimitotic agent to vascular smooth muscle cells (VSMC). METHODS: A series of co-polymer films was prepared, using varying ratios (w/w) of N-isopropylacrylamide (NiPAAm) monomer to N-tert-butylacrylamide (NtBAAm) and loaded with the antimitotic agent colchicine (100 nmol/film) at room temperature. RESULTS: The extent of colchicine release at 37 degrees C was inversely proportional to the amount of NtBAAm in co-polymer films: release after 48 h from 85:15, 65:35 and 50:50 (NiPAAm:NtBAAm) films was 26, 17 and 0.5 nmol, respectively. In cytotoxicity studies, when medium incubated with co-polymers for 24 h (in the absence of colchicine) was further incubated with target bovine aortic smooth muscle cells (BASMC), no loss of cell viability occurred. Colchicine released from all three co-polymer films significantly inhibited proliferation and random migration of BASMC: 100 nM colchicine (released from 65:35 NiPAAm:NtBAAm) reduced cell proliferation to 25.7+/-1.7% of levels seen in the absence of colchicine (control) and random cell migration to 37.7+/-5.7% of control (mean+/-S.E.M., n = 3, P < .01 and P < .05, respectively). The magnitudes of these effects were comparable to those seen in separate experiments with native colchicine and were observed in samples of released colchicine which had been stored at -20 degrees C for up to 6 months. CONCLUSIONS: This study has shown that the release of the antimitotic agent colchicine, from NiPAAm/NtBAAm co-polymer films can be manipulated by changes in co-polymer composition. Furthermore, such drug released at 37 degrees C retains comparable bioactivity to that of native colchicine.

PET modulated fluorescent sensing from the BF2 chelated azadipyrromethene platform.

A convergent building block synthesis has been applied to new off/on photoinduced electron transfer (PET) modulated fluorescent sensors which are based on a BF(2) chelated tetraarylazadipyrromethene platform and operate in the biomedically important red region of the visible spectrum. Incorporation of diethylamine and morpholine receptors facilitates off/on microenvironment polarity and pH sensing. Aqueous formulation and in vitro cellular imaging demonstrates their potential for intracellular sensing.

Supramolecular photonic therapeutic agents.

A new approach to achieving selectivity for photodynamic therapy based upon the reversible off/on switching of the key therapeutic property (singlet oxygen generation) of a supramolecular photonic therapeutic agent (SPTA) in response to an external stimulus in the surrounding microenvironment is described. A series of SPTA analogues with pH responsive receptors of varying pKa are presented, in which the generation of singlet oxygen is shown to be dependent upon a proton source. For example, systems have been constructed such that the excited state energy of the photosensitizer can be decayed by a rapid photoinduced electron transfer (PET) mechanism, resulting in virtually no singlet oxygen being generated, but when the amine receptor is protonated the PET mechanism does not operate and singlet oxygen is produced. In vitro efficacy demonstrated that the SPTA derivatives can be activated within cells and one analogue is measured to have an EC50 value of 5.8 nM when assayed in the MRC5 cell line.

Interaction of soft condensed materials with living cells: phenotype/transcriptome correlations for the hydrophobic effect.

The assessment of biomaterial compatibility relies heavily on the analysis of macroscopic cellular responses to material interaction. However, new technologies have become available that permit a more profound understanding of the molecular basis of cell-biomaterial interaction. Here, both conventional phenotypic and contemporary transcriptomic (DNA microarray-based) analysis techniques were combined to examine the interaction of cells with a homologous series of copolymer films that subtly vary in terms of surface hydrophobicity. More specifically, we used differing combinations of N-isopropylacrylamide, which is presently used as an adaptive cell culture substrate, and the more hydrophobic, yet structurally similar, monomer N-tert-butylacrylamide. We show here that even discrete modifications with respect to the physiochemistry of soft amorphous materials can lead to significant impacts on the phenotype of interacting cells. Furthermore, we have elucidated putative links between phenotypic responses to cell-biomaterial interaction and global gene expression profile alterations. This case study indicates that high-throughput analysis of gene expression not only can greatly refine our knowledge of cell-biomaterial interaction, but also can yield novel biomarkers for potential use in biocompatibility assessment.