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- Bioremediation of Bacteria, Histamine and Animal DNA by Black Soldier Fly Larvae for Safe Food Waste ValorisationPublication . Oliveira, Joana; Ligeiro, Carolina; Carvalho, Carina; Souza, Clarice; Grilo, Miguel L.; Fantatto, Rafaela; Trindade, Alexandre; Murta, Daniel; Assunção, RicardoBy 2050, the global population is expected to reach 9.8 billion, increasing pressure on agri-food systems and worsening food waste. In the European Union (EU), around 59 million tonnes of food are wasted annually, enough to feed 1.26 hungry billion people per year. This waste has major public health impacts. Tackling it through safe, sustainable strategies is, therefore, essential. Black soldier fly larvae (BSFL; Hermetia illucens) offer a promising solution by converting food waste into high-value products like protein, fat, and organic fertiliser. However, EU legislation currently prohibits using food waste as insect feed due to possible contamination with prions, and other foodborne hazards such as bacteria and histamine. This study evaluates the food safety potential of BSFL by assessing their ability to reduce pathogenic bacteria and histamine, and to determine whether they bioaccumulate animal DNA (pork, beef, chicken). To test this, 2 tonnes of heterogeneous food waste were transformed into BSFL substrate and used in a bioconversion assay. Larvae in the test group showed improved performance, with higher bioconversion and growth rates and a lower feed conversion ratio compared to the control group. Analyses were conducted on food waste substrate, larvae, BSFL meal, and frass, including controls. Bacterial enumeration followed ISO protocols; histamine was quantified using an ELISA kit; DNA was extracted and then analysed via PCR and agarose gel electrophoresis.BSFL significantly reduced Salmonella spp. and Vibrio spp. in the test group (p = 0.002), and Bacillus cereus and Vibrio spp. in the control (p = 0.015). Histamine levels decreased significantly (p = 0.029). No animal DNA was detected in larvae (p = 0.029), though traces persisted in frass, indicating excretion rather than bioaccumulation. These findings support the safe use of BSFL in food waste valorisation and their integration into circular, One Health food systems focused on safety and sustainability.
- Harnessing Black Soldier Fly Larvae for Sustainable Food Waste Valorisation and Pathogen BioremediationPublication . Oliveira, Joana; Ligeiro, Carolina; Fantatto, Rafaela; Souza, Clarice; Grilo, Miguel L.; Carvalho, Carina; Trindade, Alexandre; Murta, Daniel; Assunção, RicardoFood waste is a pressing challenge for public health and environmental sustainability, with an estimated 59 million tonnes generated annually in the European Union. This substantial waste compromises the resilience of agrifood systems, intensifies food insecurity, and hampers efforts toward achieving a circular economy [2]. The insect Black soldier fly larvae (BSFL) present a promising and innovative approach to addressing these issues by efficiently converting organic waste into valuable outputs, such as high-protein animal feed and fertilisers. Despite the industrial valorisation of agricultural by-products, BSFL’s potential to fully utilise food waste remains subject to some legal restrictions. This study, conducted in collaboration with Ingredient Odyssey SA – EntoGreen, investigated the suitability of food waste as a substrate for BSFL production and assessed the larvae's bioremediation potential for reducing foodborne pathogens. An industrial-scale trial was performed over 14 days, using 114 test units with food waste-based substrates and 144 control units with Gainesville Diet, a standard insect feed. Two tonnes of food waste sourced from restaurants in Santarém, Portugal, were collected and prepared by removing physical contaminants such as plastic, cutlery, and cans. The food waste was then mixed with wheat bran, and its moisture was adjusted to 70% to create an optimal substrate. Measurements, including larval weight and substrate temperature, were taken every other day, while microbiological analyses followed ISO standards to detect pathogens and enumerate microorganisms. Results showed that food waste substrate significantly enhanced larval growth and bioconversion rates while bioremediating pathogens, including Bacillus cereus, Vibrio spp., and Salmonella spp. These results highlight the potential of BSFL to transform food waste into valuable resources while mitigating microbial risks, demonstrating a scalable and sustainable solution for food waste valorisation and contributing to a circular economy.