Atta (whole wheat flour) with multi-wholegrains: flour characterization, nutritional profiling and evaluation of chapati making quality.

Non-wheat grains, complementing the nutritional profile of wheat were utilized for the development of atta with multi-whole grains. Based on the dimensions, selected grains were segregated and the grinding techniques were applied for the production of multi whole grains flour. Multi whole grains flour was replaced with whole wheat flour to obtain five different formulations and further compared with control atta. With the increase in incorporation of the multi whole grain flours reduction in brightness (L*) from 79.73 to 78.47 and redness (a*) from 2.47 to 12.12 while the increase in yellowness (b*) was observed (12.10-12.70). Protein content increased from 13.44 to 14.83% while dietary fibre content was also found to be increased in all the formulations compared to control atta. Ash content, an indicator of mineral content showed an increasing trend with the increase in the level of non-wheat grains. Shear force required for tearing the chapatis at 0 h was observed to be in the range of 15.6 and 10.1 N and moisture content between 32.6 and 30.4%. Mineral analysis carried out for the 10% replacement showed an increase in the level of the estimated minerals. An overall eating quality of the chapatis was found to be acceptable up to 10% replacement compared to control atta chapati.

Volatile organic compounds emitted by filamentous fungi isolated from flooded homes after Hurricane Sandy show toxicity in a Drosophila bioassay.

Superstorm Sandy provided an opportunity to study filamentous fungi (molds) associated with winter storm damage. We collected 36 morphologically distinct fungal isolates from flooded buildings. By combining traditional morphological and cultural characters with an analysis of ITS sequences (the fungal DNA barcode), we identified 24 fungal species that belong to eight genera: Penicillium (11 species), Fusarium (four species), Aspergillus (three species), Trichoderma (two species), and one species each of Metarhizium, Mucor, Pestalotiopsis, and Umbelopsis. Then, we used a Drosophila larval assay to assess possible toxicity of volatile organic compounds (VOCs) emitted by these molds. When cultured in a shared atmosphere with growing cultures of molds isolated after Hurricane Sandy, larval toxicity ranged from 15 to 80%. VOCs from Aspergillus niger 129B were the most toxic yielding 80% mortality to Drosophila after 12 days. The VOCs from Trichoderma longibrachiatum 117, Mucor racemosus 138a, and Metarhizium anisopliae 124 were relatively non-toxigenic. A preliminary analysis of VOCs was conducted using solid-phase microextraction-gas chromatography-mass spectrometry from two of the most toxic, two of the least toxic, and two species of intermediate toxicity. The more toxic molds produced higher concentrations of 1-octen-3-ol, 3-octanone, 3-octanol, 2-octen-1-ol, and 2-nonanone; while the less toxic molds produced more 3-methyl-1-butanol and 2-methyl-1-propanol, or an overall lower amount of volatiles. Our data support the hypothesis that at certain concentrations, some VOCs emitted by indoor molds are toxigenic.