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<title>Polímeros (POLYMERS)</title>
<link>https://hdl.handle.net/10259/4313</link>
<description/>
<pubDate>Wed, 01 Jul 2026 13:21:17 GMT</pubDate>
<dc:date>2026-07-01T13:21:17Z</dc:date>
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<title>Dual-range colorimetric protein quantification in whey and WPC using a smart polymeric film and RGB imaging</title>
<link>https://hdl.handle.net/10259/11890</link>
<description>Dual-range colorimetric protein quantification in whey and WPC using a smart polymeric film and RGB imaging
Vallejo García, Jorge Lucas; Trigo López, Miriam; Ibeas Cortes, Saturnino; Torija López, Alba; Busto Núñez, Mª Dolores; Pilar Izquierdo, María Concepción; López, Gloria; Sánchez, Carlos; Vallejos Calzada, Saúl
Whey is an important dairy by-product whose protein content must be accurately determined for quality control and fraud detection. Conventional nitrogen-based methods (e.g., Kjeldahl) require laboratory equipment and overestimate protein in the presence of non-protein nitrogen compounds. Here, we report a rapid analytical approach based on a smart polymeric film (FRGB) prepared by diazotisation–azo coupling chemistry. The film reacts with aromatic residues of whey proteins, producing a colour change quantifiable from a smartphone image. The sensor displays a dual-range response: the blue channel provides high sensitivity at low concentrations, whereas the green channel remains linear at high concentrations, enabling direct analysis of whey protein concentrate without dilution. The method showed excellent linearity (R2 = 0.99) in whey and commercial WPC over 0–120 mg·mL−1, with a detection limit of 0.284 mg·mL−1 and recovery rate of 94 ± 1.46%. Non-protein nitrogen compounds did not interfere, allowing rapid screening and preliminary authenticity assessment of whey-derived products.
</description>
<pubDate>Mon, 01 Jun 2026 00:00:00 GMT</pubDate>
<guid isPermaLink="false">https://hdl.handle.net/10259/11890</guid>
<dc:date>2026-06-01T00:00:00Z</dc:date>
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<item>
<title>Dataset of the work "UBU-Polymers Research Group 27052026"</title>
<link>https://hdl.handle.net/10259/11889</link>
<description>Dataset of the work "UBU-Polymers Research Group 27052026"
Torija López, Alba; Núñez-Carrero, Karina C.; Sedano Labrador, Carlos; Rodríguez Pérez, Miguel Ángel .; Vallejos Calzada, Saúl; Trigo López, Miriam
The transition towards circular food packaging requires not only regulatory compliance but also material and structural harmonization. This study analyzes 163 multilayer films from commercial food packaging available on the European market to quantify structural diversity and assess implications for recyclability. Forty-two distinct multilayer configurations and twenty-seven polymer combinations were identified, with no systematic relationship to food category, film thickness, or functional requirements. Functionally similar packages frequently relied on materially incompatible or over-engineered polymer combinations, revealing a fragmented and non-standardized packaging landscape.&#13;
Although all analyzed structures comply with current European food-contact regulations (EC 1935/2004 and EU 10/2011), their diversity and incompatibility hinder mechanical and chemical recycling, challenging the objectives of the forthcoming Packaging and Packaging Waste Regulation (PPWR). Overall, the results provide quantitative, market-level evidence of structural redundancy and demonstrate how fragmented design practices undermine design-for-recycling principles and the implementation of circular economy strategies in food packaging.
</description>
<pubDate>Mon, 25 May 2026 00:00:00 GMT</pubDate>
<guid isPermaLink="false">https://hdl.handle.net/10259/11889</guid>
<dc:date>2026-05-25T00:00:00Z</dc:date>
</item>
<item>
<title>Too many structures for the same function: Market evidence of circularity barriers in food packaging</title>
<link>https://hdl.handle.net/10259/11888</link>
<description>Too many structures for the same function: Market evidence of circularity barriers in food packaging
Torija López, Alba; Núñez-Carrero, Karina C.; Sedano Labrador, Carlos; Rodríguez Pérez, Miguel Ángel .; Vallejos Calzada, Saúl; Trigo López, Miriam
The transition towards circular food packaging requires not only regulatory compliance but also material and structural harmonization. This study analyzes 163 multilayer films from commercial food packaging available on the European market to quantify structural diversity and assess implications for recyclability. Forty-two distinct multilayer configurations and twenty-seven polymer combinations were identified, with no systematic relationship to food category, film thickness, or functional requirements. Functionally similar packages frequently relied on materially incompatible or over-engineered polymer combinations, revealing a fragmented and non-standardized packaging landscape.&#13;
Although all analyzed structures comply with current European food-contact regulations (EC 1935/2004 and EU 10/2011), their diversity and incompatibility hinder mechanical and chemical recycling, challenging the objectives of the forthcoming Packaging and Packaging Waste Regulation (PPWR). Overall, the results provide quantitative, market-level evidence of structural redundancy and demonstrate how fragmented design practices undermine design-for-recycling principles and the implementation of circular economy strategies in food packaging.
</description>
<pubDate>Mon, 01 Jun 2026 00:00:00 GMT</pubDate>
<guid isPermaLink="false">https://hdl.handle.net/10259/11888</guid>
<dc:date>2026-06-01T00:00:00Z</dc:date>
</item>
<item>
<title>Coumarin-inspired light-responsive thermoplastic adhesives for recyclable multilayer packaging</title>
<link>https://hdl.handle.net/10259/11488</link>
<description>Coumarin-inspired light-responsive thermoplastic adhesives for recyclable multilayer packaging
Sedano Labrador, Carlos; Herrero, Manuel; Trigo López, Miriam; Rodríguez Pérez, Miguel Ángel .; Merino, Juan Carlos; García Pérez, José Miguel; Vallejos Calzada, Saúl; Núñez-Carrero, Karina C.
Multilayer plastic packaging offers essential barrier and mechanical properties for food preservation, but its complex structure prevents effective recycling. Here, we report a light-responsive thermoplastic adhesive designed to enable on-demand separation of polymer layers in multilayer packaging. The adhesive adopts a triblock architecture with terminal blocks compatible with polyethylene (PE) and polyamide (PA), and a central segment functionalised with coumarin-based photoremovable groups. Upon ultraviolet (UV) exposure, the adhesive undergoes complete molecular breakdown, triggering clean delamination without solvents or mechanical force. Fabricated PE – photosensitive adhesive – PA films demonstrated superior adhesion performance compared to a commercial benchmark during service life, and efficient separation upon irradiation, as confirmed by Fourier transform infrared (FTIR) spectroscopy, microscopy, and T-peel testing. Life cycle assessment revealed that, while the laboratory-scale synthesis has higher environmental costs, the impact is offset after a single reuse cycle in projected industrial conditions, reaching up to 80% reduction after six cycles. This approach provides a scalable strategy to reconcile performance and recyclability in multilayer packaging.
</description>
<pubDate>Thu, 01 Jan 2026 00:00:00 GMT</pubDate>
<guid isPermaLink="false">https://hdl.handle.net/10259/11488</guid>
<dc:date>2026-01-01T00:00:00Z</dc:date>
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