This study reports the effects of addition of mushroom powder on the nutritional properties, predictive in vitro glycaemic response and antioxidant potential of durum wheat pasta. Addition of the mushroom powder enriched the pasta as a source of protein, and soluble and insoluble dietary fibre compared with durum wheat semolina. Incorporation of mushroom powder significantly decreased the extent of starch degradation and the area under the curve (AUC) of reducing sugars released during digestion, while the total phenolic content and antioxidant capacities of samples increased. A mutual inhibition system between the degree of starch gelatinisation and antioxidant capacity of the pasta samples was observed. These results suggest that mushroom powder could be incorporated into fresh semolina pasta, conferring healthier characteristics, namely lowering the potential glycaemic response and improving antioxidant capacity of the pasta.
Summary
In this study, a partial substitution of durum wheat semolina with three different species of mushrooms (white button, shitake and porcini) was undertaken to increase the nutritional value of the pasta. The cooking properties and textural characteristics of the pasta produced were also determined. The results showed that the addition of mushroom powder increased the cooking loss, as well as firmness and resistance of the uniaxial tension of the pasta. Porcini mushroom incorporation significantly decreased the swelling index, water absorption index and moisture content values of the cooked pasta, while, for the white button and shiitake mushrooms, there was no noticeable effect on either index compared with the control sample (containing exclusively durum wheat semolina). The addition of shiitake mushroom powder resulted in pasta with the highest firmness and tensile strength.
Recent market developments raised the need for alternatives to hydrocolloids as texture improver in gluten-free bread. Chickpea exerts several physicochemical properties (water- and oil-binding, emulsifying and foaming) that might address this need. Therefore, the effect of processing on chickpea functionality was tested on low ingredient dose, comparably to that of common hydrocolloids. Control bread was small, hard and with low gas retention ability as shown by microscopy, depicting holes inside crumb pores. Addition of chickpea flour in low dose (2% w/w) enhanced loaf volume by 20% and reduced crumb hardness by 40%, due to increased gas retention (no holes within pores) and superior homogeneity of the starch-protein network. On the contrary, chickpea paste deleteriously affected bread quality due to loss of solubility upon cooking. Interestingly, both soaking and cooking water significantly reduced crumb hardness, although to a lower extent than the flour. More homogeneous crumb structure and gas retention were observed in the micrographs, possibly due to the emulsifying activity of flavonoids and saponins (soaking) and insoluble fibre (cooking). Chickpea ingredients are promising substitute of hydrocolloids such as xanthan gum for texture improvement of gluten-free bread, although acting with different mechanisms.
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