ESR, raman and conductivity studies on fractionated poly(2-methoxyaniline-5-sulfonic acid)

Synthesis methods used to produce poly(2-methoxyaniline-5-sulfonic acid) (PMAS), a water soluble, self-doped conducting polymer, have been shown to form two distinctly different polymer fractions with molecular weights of approximately 2 kDa and 8 -10 kDa. The low molecular weight (LMWT) PMAS fraction is redox inactive and non-conducting while the high molecular weight (HMWT) PMAS is electro-active with electrical conductivities of 0.94 0.05 S cm-1. Previous investigations have illustrated the different photochemical and electrochemical properties of these fractions, but have not correlated these properties with the structural and electronic interactions that drive them. Incomplete purification of the PMAS mixture, typically via bag dialysis, has been shown to result in a mixture of approximately 50:50 HMWT:LMWT PMAS with electrical conductivity significantly lower at approximately 0.10 to 0.26 S cm-1. The difference between the electrical conductivities of these fractions has been investigated by the controlled addition of the non-conducting LMWT PMAS fraction into the HMWT PMAS composite film with the subsequent electronic properties investigated by solid-state ESR and Raman spectroscopies. These studies illustrate strong electronic intereactions of the insulating LMWT PMAS with the emeraldine salt HMWT PMAS to substantially alter the population of the electronic charge carriers in the conducting polymer. ESR studies on these mixtures, when compared to HMWT PMAS, exhibited a lower level of electron spin in the presence of LMWT PMAS indicative of the the formation of low spin bipolarons without a change the oxidation state of the conducting HMWT fraction

Leishmania donovani Parasites Interact with g/dþ Human Peripheral Blood T Cells and Induce Susceptibility to NK Cell-Mediated Lysis

We recently reported that Leishmania donovani infect the human T-cell line in vitro. To examine whether primary human T cells could be infected by this parasite, a direct interaction of the peripheral blood T cells with L. donovani was examined. The percentage of g/dþ T cells was markedly increased when in vitro generated normal human T-cell blasts were cultured with L. donovani amastigotes. About 30% of the g/dþ T cells in the parasite exposed T-cell blasts expressed parasite antigens intracellularly without detectable intracellular parasites. Parasite exposed T-cell blasts had a reduced surface expression of HLA-DR and were lysed by the sorted CD56þ cells. In contrast, neither L. donovani amastigotes nor T-cell blasts exposed to heat killed amastigotes and/or were sensitive to the NK cell-mediated lysis. Of interest is that about 10% CD3þ peripheral blood T cells in two out of three Indian Kala-azar patients tested expressed intracellular L. donovani antigen