Effect of cooking temperature on cooked pasta quality and sustainability.

BACKGROUND: Everyday pasta cooking has a large environmental impact. The aims of this work were to assess the effect of cooking temperatures (TC ) that were lower than the water boiling point (TBW ) on the main chemico-physical quality parameters of two pasta shapes (i.e., ziti and spaghetti) cooked at the conventional and minimum water-to-pasta ratios, as well as their optimum cooking time (OCT), cooking energy consumption, and carbon footprint, by using a novel eco-sustainable pasta cooker. RESULTS: Once the effect of TC on OCT had been modeled in accordance with the Bigelow model, it was possible to estimate that the energy saved to heat the cooking water from ambient temperature to a lower temperature than TBW was smaller than the extra energy needed to complete the pasta cooking phase. After several cooking trials, the water uptake, cooking loss, textural properties, and thickness of the central nerve (as observed with a scanning electronic microscope) of cooked pasta were found to be independent of TC in the range of 85-98 °C. CONCLUSIONS: By using smaller amounts of water (~3 L kg-1 ) and cooking at 85 °C with the eco-sustainable pasta cooker, the energy consumption reduced from the default value of 2.8 kWh kg-1 to ~0.45 kWh kg-1 and GHG emissions to about one sixth of those resulting from the use of the average European home appliances. © 2021 Society of Chemical Industry.

Cradle-to-grave carbon footprint of dried organic pasta: assessment and potential mitigation measures.

BACKGROUND: In several Environmental Product Declarations, the business-to-business carbon footprint (CFCDC ) of durum wheat semolina dried pasta ranged from 0.57 to 1.72 kg carbon dioxide equivalent (CO2e ) kg-1 . In this work, the business-to-consumer carbon footprint (CFCG ) of 1 kg of dry decorticated organic durum wheat semolina pasta, as packed in 0.5 kg polypropylene bags by a South Italian medium-sized pasta factory in the years 2016 and 2017, was assessed in compliance with the Publicly Available Specification 2050 standard method. RESULTS: Whereas CFCDC was mostly conditioned by the greenhouse gases emitted throughout durum wheat cultivation (0.67 vs 1.12 kg CO2e kg-1 ), CFCG was mainly dependent on the use and post-consume phases (0.68 vs 1.81 kg CO2e kg-1 ). CFCG was more or less affected by the pasta types and packing formats used, since it varied from +0.3 to +14.8% with respect to the minimum score estimated (1.74 kg CO2e kg-1 ), which corresponded to long goods packed in 3 kg bags for catering service. Once the main hotspots had been identified, CFCG was stepwise reduced by resorting to a series of mitigation actions. CONCLUSION: Use of more eco-sustainable cooking practices, organic durum wheat kernels resulting from less impacting cultivation techniques, and renewable resources to generate the thermal and electric energy needs reduced CFCG by about 58% with respect to the above reference case. Finally, by shifting from road to rail freight transport and shortening the supply logistics of dry pasta and grains, a further 5% reduction in CFCG was achieved. © 2019 Society of Chemical Industry.

Reducing the cooking water-to-dried pasta ratio and environmental impact of pasta cooking.

BACKGROUND: During daily pasta cooking, the general consumer pays little attention to water and energy issues. The present study aimed to measure the cooking quality and environmental impact of a standard format of dry pasta by varying the water-to-dried pasta ratio (WPR) from 12 to 2 L kg-1 . RESULTS: In the above WPR range, the cooked pasta water uptake (1.3 ± 0.1 g g-1 ), cooking loss (0.037 ± 0.009 g g-1 ) and degree of starch gelatinization (11.2 ± 0.8%) were approximately constant, whereas the main Texture Analysis parameters (eg, cooked pasta hardness at 30% and 90% deformation, and resilience) showed no statistically significant difference. As the WPR was reduced from 12 to 2 L kg-1 , the specific electric energy consumption linearly decreased from 1.93 to 0.39 Wh g-1 and the carbon footprint and eutrophication potential of pasta cooking lessened by approximately 80% and 50%, respectively. CONCLUSION: Cooking dry pasta in a large excess of water (ie, 10 L kg-1 ), as commonly suggested by the great majority of pasta manufacturers, might be pointless. Such a great mitigation with respect to the environmental impact of pasta cooking should be checked further for other commercial pasta formats and would highlight the need for novel and more suitable pasta cookers than those currently in use. © 2018 Society of Chemical Industry.