Low-temperature, high-performance solution-processed metal oxide thin-film transistors formed by a 'sol­gel on chip' process.

At present there is no 'ideal' thin-film transistor technology for demanding display applications, such as organic light-emitting diode displays, that allows combining the low-temperature, solution-processability offered by organic semiconductors with the high level of performance achievable with microcrystalline silicon1. N-type amorphous mixed metal oxide semiconductors, such as ternary oxides Mx1My2Oz, where M1 and M2 are metals such as In, Ga, Sn, or Zn, have recently gained momentum because of their high carrier mobility and stability2, 3 and good optical transparency, but they are mostly deposited by sputtering. So far no route is available for forming high-performance mixed oxide materials from solution at low process temperatures <250 °C. Ionic mixed metal oxides should in principle be ideal candidates for solution-processable materials because the conduction band states derived from metal s-orbitals are relatively insensitive to the presence of structural disorder and high charge carrier mobilities are achievable in amorphous structures2. Here we report the formation of amorphous metal oxide semiconducting thin-films using a 'sol­gel on chip' hydrolysis approach from soluble metal alkoxide precursors, which affords unprecedented high field-effect mobilities of 10 cm2 V−1 s−1, reproducible and stable turn-on voltages Von≈0 V and high operational stability at maximum process temperatures as low as 230 °C.

Regulation of rat olfactory glutathione S-transferase expression. Investigation of sex differences, induction, and ontogenesis.

The glutathione S-transferases (GSTs) of rat olfactory epithelium have been characterised with regard to sex differences, induction, and developmental regulation, and compared to those of the liver. Olfactory cytosolic GST activity with 1-chloro-2,4-dinitrobenzene (CDNB) as substrate was similar in both male and female animals, and there were no differences in subunit profile. Administration of trans-stilbene oxide and beta-naphthoflavone had no effect on olfactory GST activity with CDNB, although phenobarbitone treatment resulted in a small, but significant, increase in activity (130% compared to controls). HPLC analysis of subunit profiles indicated that all three agents induced olfactory subunit 1b and decreased subunit 6. The effect of age (3 to 84 days) on both cytosolic and microsomal CDNB activity was examined. In the liver, cytosolic activity was low at 3 days and climbed steadily to reach maximal levels around 28 days, but microsomal activity was relatively constant at all ages. Olfactory cytosolic activity was similar at all ages; microsomal activity was low until 21 days and then increased to reach a maximum at 56 days. Changes in individual cytosolic subunits were assessed by SDS-PAGE followed by immunoblotting. The significance of these results with regard to putative physiological roles for olfactory GSTs is discussed.

Olfactory toxicity of methyl iodide in the rat.

The monohalomethanes (methyl iodide, methyl bromide and methyl chloride) are widely used industrial methylating agents with pronounced acute and chronic toxicity in both experimental animals and man. Recently inhalation exposure of rats to methyl bromide has been shown to result in severe olfactory toxicity. This study examined the effects on the rat nasal cavity of inhalation of methyl iodide (100 ppm for 0.5-6 h), and demonstrated that methyl iodide is a more potent olfactory toxin than methyl bromide. Within the nasal cavity the olfactory epithelium was the principle target tissue, and it was only at high doses (600 ppm.h) that limited damage to transitional epithelium occurred. The squamous and respiratory epithelia were consistently unaffected. Within olfactory epithelium the sustentacular cells were the primary cellular target and damage to sensory cells appeared to be a secondary event. Methyl iodide induced olfactory damage was reversible, and 2 weeks after exposure almost complete repair had taken place.

Immunohistochemical localisation of six glutathione S-transferases within the nasal cavity of the rat.

Many xenobiotics induce lesions within the nasal cavity of experimental animals which are site specific. This site selectivity may be due to regional deposition within the nasal cavity and/or the localisation of biotransformation enzymes. We have developed methodology which allows immunohistochemical localisation of xenobiotic biotransformation enzymes in transverse sections of the rat nasal cavity identical to those normally taken for pathological examination. We report the application of this methodology to six isoenzymes of the glutathione S-transferases (GSTs). All six isoenzymes were predominantly located within olfactory epithelium covering the ethmoturbinates (levels III and IV) and extending forwards into the dorsal meatus (level II). Squamous and transitional epithelia showed little or no staining while respiratory epithelium was weakly stained. Within the respiratory epithelium only the ciliated columnar cells and, to a lesser extent, some of the seromucous glands contained GSTs. Within olfactory epithelium the sustentacular cells, basal cells and subepithelial glands all stained positive for GSTs. The different cell types of olfactory epithelium preferentially express different GST isoenzymes: 1-1 and 2-2 were predominantly located in the subepithelial glands; 3-3, 4-4 and 8-8 in sustentacular and basal cells; 7-7 in basal cells.

The characterization of glutathione S-transferases from rat olfactory epithelium.

The glutathione S-transferases (GSTs) of rat olfactory epithelium have been characterized with regard to substrate specificity and subunit composition and compared to those of the liver. The presence of cytosolic GST activity in rat olfactory epithelium was confirmed and, using 1-chloro-2,4-dinitrobenzene as substrate, was found to be approximately one-third that of the liver. Olfactory microsomal GST activity was greater than that of liver microsomes and could be activated by treatment with the sulphydryl agent N-ethylmaleimide. The subunit and isoenzyme profile of GSTs in the olfactory epithelium was investigated using a number of techniques. (1) Olfactory GSTs were characterized using a range of relatively subunit-specific substrates. Activities ranged from 40-90% of those found in liver. Most noticeable was the extremely low olfactory activity with the substrate specific for subunit 1. (2) Immunoblotting with antibodies against specific rat hepatic GSTs confirmed the presence of a number of subunits and the absence of subunit 1. (3) F.p.l.c. chromatofocusing and reverse-phase h.p.l.c. indicated that the cytosolic GST profile of olfactory epithelium is unique and is made up of subunits 2, 3, 4, 7, 8 and 11 with subunits 3 and 4 predominating. There is an absence of isoenzymes containing subunit 1.