Polymeric nanofibers for the removal of Cr(III) from tannery waste water.

We demonstrate the use of cysteine-modified polymer nanofibers for the rapid and efficient removal of Cr(III) from real tannery waste water samples. Various parameters such as pH, load of nanofibers and time of exposure were optimized to achieve maximum removal. The optimum parameters were found to be 0.1 mg of nanofibers per mL of tannery waste water with a pH of 5.5 and an exposure time of 45 min. Almost 99% Cr(III) was removed at these ideal conditions thus demonstrating the efficacy of our material. The maximum removal capacity at these ideal conditions was estimated to be approximately 1.75 g of chromium/gram of polymeric material. This is probably due to a variety of factors including the apparent high surface to volume ratio exhibited by these nanofibers and also due to the availability of numerous cysteine groups that are known to have high binding affinities with heavy metal ions. These nanoscale polymeric materials show great potential towards the removal of heavy metal cations from waste waters.

Towards biosensors based on conducting polymer nanowires.

We report the electrochemical deposition of poly(pyrrolepropylic acid) nanowires, their covalent modification with antibodies and their conversion into potential functional sensor devices. The nanowires and the devices were characterised by optical microscopy, fluorescence microscopy, electron microscopy and electrical measurements. Fluorescence images, current-voltage (I-V) profiles and real-time sensing measurements demonstrated a rapid and highly sensitive and selective detection of human serum albumin (HSA), a substance that has been used to diagnose incipient renal disease. The detection is based on the selective binding of HSA onto anti-HSA that is covalently attached to the nanowires. The binding changes the electrical properties of the nanowires thus enabling the real-time detection. Whilst the utility of the research was demonstrated for protein binding/detection, the technology could easily be designed for the detection of other analytes by the modification of polymer nanowires with other analyte-specific molecules/biomolecules. Therefore, the technology has the potential to positively impact broad analytical applications in the biomedical, environmental and other sectors.

Redox protein-polymer films for simultaneous determination of ascorbic acid and hydrogen peroxide.

Layer by layer films of protein and redox polymer were constructed and used to simultaneously analyze ascorbic acid and hydrogen peroxide. The films were made using hemoglobin and poly[4-vinylpyridine Os(bipyridine)(2)Cl]-co-ethylamine (Pos-Ea). The film growth was monitored using cyclic voltammetry, quartz crystal microbalance (QCM) and atomic force microscopy (AFM). Reversible pairs of oxidation-reduction peaks were observed using cyclic voltammetry corresponding to the Os(II)/Os(III) from redox polymer and HbFe(III)/HbFe(II) redox couples at 0.35 and -0.25 V vs. Ag/AgCl, respectively. The two redox centers were independent of each other. This enabled the simultaneous and independent determination of ascorbic acid and hydrogen. Peak currents were linearly related to concentration for both analytes in a mixture. The linear range of ascorbic acid was 0-1 mM (R(2) = 0.9996, n = 5) at scan rate of 50 mV s(-1) (sensitivity 3.5 microA/mM) while hydrogen peroxide linear range was 1.0-10.0 microM (R(2) = 0.991, n = 6) with sensitivity of 1.85 microA/microM.