Polypyrrole (PPy) is a conjugated polymer that displays particular electronic properties including conductivity. In biomedical applications, it is usually electrochemically generated with the incorporation of any anionic species including also negatively charged biological macromolecules such as proteins and polysaccharides to give composite materials. In biomedical research, it has mainly been assessed for its role as a reporting interface in biosensors. However, there is an increasing literature on the application of PPy as a potentially electrically addressable tissue/cell support substrate. Here, we review studies that have considered such PPy based conducting polymers in direct contact with biological tissues and conclude that due to its versatile functional properties, it could contribute to a new generation of biomaterials.
Variously loaded polypyrrole films, including those containing proteins and polysaccharides, were prepared on gold-coated polycarbonate coverslips. The characteristics of human keratinocytes were studied on these films by microscopy, biochemical assays, and immunocytochemistry. We found keratinocyte viability to be load dependent. For chloride, polyvinyl sulphate, dermatan sulphate, and collagen-loaded polypyrrole films, keratinocyte viability as assessed by the AlamarBlue assay was respectively 47.22, 60.43, 87.71, and 22.65% of tissue culture polystyrene controls after 5 days. This was found to require a previously unreported polymer washing step prior to cell seeding due to the observed toxicity of untreated films. In the case of bare polycarbonate and gold substrates, viability was respectively 75.44 and 61.04% of tissue culture polystyrene controls after 5 days. Keratinocytes stained positive for PCNA (proliferation), K10 (suprabasal differentiation), and K16 (hyperproliferation) markers although cell morphology was poor for organotypical cultures on dermatan- loaded polypyrrole compared with de-epidermalized dermis. From our studies, we concluded that optimized polypyrrole films adequately support keratinocyte growth in submerged cultures with some improvements needed for organotypical cultures. Polypyrrole composites are attractive candidates for tissue-engineering applications since they may incorporate biomolecules and are electrically addressable with the potential to both direct and report on cell activity.
Phagocytosis is defined as the ingestion of particulates over 0.5 microm in diameter and is associated with cells of the immune system such as macrophages or monocytes. Neurones are not generally recognized to be phagocytic. Using light, confocal, time-lapse and electron microscopy, we carried out a wide range of in-vitro and in-vivo experiments to examine the phagocytic capacity of different neuronal cell types. We demonstrated phagocytosis of material by neurones, including cell debris and synthetic particles up to 2.8 microm in diameter. We showed phagocytosis in different neuronal types, and demonstrated that debris can be transported from neurite extremities to cell bodies and persist within neurones. Flow cytometry analysis demonstrated the lack of certain complement receptors on neurones but the presence of others, including integrin receptors known to mediate macrophage phagocytosis, indicating that a restricted set of phagocytosis receptors may mediate this process. Neuronal phagocytosis occurs in vitro and in vivo, and we propose that this is a more widespread and significant process than previously recognized. Neuronal phagocytosis may explain certain inclusions in neurones during disease, cell-to-cell spread of disease, neuronal death during disease progression and provide a potential mechanism for therapeutic intervention through the delivery of particulate drug carriers.
Polypyrrole (PPy) is a conducting polymer that may be electrochemically generated with the incorporation of any anionic species, including net-negatively charged biological molecules such as proteins and polysaccharides. In this article, dermatan and chloride-loaded PPy films were prepared on gold sputter-coated coverslips and various skin derived cells were studied on them by electrochemical impedance spectroscopy. Impedance spectra in the frequency range 1-100 kHz were either determined at specific times or impedance was monitored continuously at specific frequencies. An equivalent impedance circuit was fitted to the recorded impedance spectra to obtain parameters whose contributions could be mapped to intracellular and intercellular current pathways, and the membrane properties of cells. Results show cell-induced impedance changes were detected over PPy modified electrodes and were dependent on cell density and type, monitoring frequency, material composition, and treatment. Lower cell densities were detected on PPy when compared with bare gold. Keratinocyte confluence, as determined by impedimetric analysis, was reached more rapidly on PPy than on gold. This was consistent with previous, more cumbersome, biochemical assays. Electrical equivalent circuit analysis provided evidence that the technique may be extended to discriminate cell type because of the intracellular and intercellular resistance, and cell membrane capacitance being related to cell morphology.
These results suggest that dynein-dynactin complex subunits may have specific subcellular roles, and primary events that disturb the function of individual components may result in disequilibrium of subunit pools, with the possibility that availability for normal cytoplasmic functions becomes impaired, with consequent organelle and axonal transport misfunction.
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