With contributions from over 30 international legal scholars, this topical Research Handbook on International Food Law provides a reflective and crucial examination of the rules, power dynamics, legal doctrines, societal norms, and frameworks that govern the modern global food system. The Research Handbook analyses the interlinkages between producers and consumers of food, as well as the environmental effects of the global food network and the repercussions on human health. Chapters explore the development of food law and governance strategies, the regulation of novel foods, including insects, and the application of technology and science in food production, such as genetically engineered food. The insightful contributions examine the legal challenges facing the global food system and suggest practical recommendations for future research and reform. Providing a comprehensive and interdisciplinary perspective on the complex legal landscape of food production and consumption, this Research Handbook will be essential reading for students and scholars of food law, consumer law, public international law, and regulation and governance, as well as food system advocates, international lawyers, and policymakers.
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Black soldier fly [BSF; Hermetia illucens L. (Diptera: Stratiomyidae)] larvae are very effective in transforming low-grade food waste into valuable high-end proteins and fat, in intensive production facilities. The production output of this species is growing quickly, but upscaling brings risks to the health status of the reared insects. Until now, not a single major case of disease outbreak caused by a pathogen in a BSF production unit has been reported. This contrasts with data on other species of mass-produced insects, which have experienced various disease outbreaks, indicating that BSFs are comparatively resistant to insect diseases. Further, there are no records of natural infections caused by entomopathogens in BSF. In this review, the known entomopathogens of Diptera, especially BSF, and their potential risks for causing disease in these insects are summarized.
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Flying insects like dragonflies, flies, bumblebees are able to couple hovering ability with the ability for a quick transition to forward flight. Therefore, they inspire us to investigate the application of swarms of flapping-wing mini-drones in horticulture. The production and trading of agricultural/horticultural goods account for the 9% of the Dutch gross domestic product. A significant part of the horticultural products are grown in greenhouses whose extension is becoming larger year by year. Swarms of bio-inspired mini-drones can be used in applications such as monitoring and control: the analysis of the data collected enables the greenhouse growers to achieve the optimal conditions for the plants health and thus a high productivity. Moreover, the bio-inspired mini-drones can detect eventual pest onset at plant level that leads to a strong reduction of chemicals utilization and an improvement of the food quality. The realization of these mini-drones is a multidisciplinary challenge as it requires a cross-domain collaboration between biologists, entomologists and engineers with expertise in robotics, mechanics, aerodynamics, electronics, etc. Moreover a co-creation based collaboration will be established with all the stakeholders involved. With this approach we can integrate technical and social-economic aspects and facilitate the adoption of this new technology that will make the Dutch horticulture industry more resilient and sustainable.
Lipids, proteins and biological active compounds that are present in insects can serve as nutrient source for poultry production. Because of the potential benefit effects of using insects as feed additives, we must consider the effects of gut microbiome on the insect affects itself, and the expected effect on the microbiome of the broilers that consume these insects. This is specifically important in the situation where live insects are fed to poultry, without prior processing. In this proposal we describe to study whether larvae fed to broilers will affect their microbiome in a positive way for practical applications in poultry industry. Hence, a pilot proof-of-concept study will be carried out as basis for a follow-up proposal for a larger project in the future, that we also like to set-up within this project. In that follow-up proposal, focus will be on the effect of different substrates for insects, on the insect microbiome, to spike insects with specific bacteria and to track their microbiome dynamics over time, and the effect of these insects used as a feed additive on the broiler gut microbiome. This study will provide results on if live Black Soldier Fly larvae (BSFL) can affect the broiler gut microbiome in a positive way, and relevant outcomes will be exploited in a follow-up research proposal in which these effects will be unraveled in detail for adoption by the industry. The project is a collaboration between cooperative insect company RavenFeed and NGN Pro-active both with knowledge on BSFL rearing, Wageningen Bioveterinary Research (WBVR) with knowledge on insect diseases and microbiome analysis, Schothorst Feed Research (SFR) highly experienced in poultry nutrition research and having unique poultry facilities, and Aeres University of Applied Sciences Dronten (AHD) with research facilities for BSFL rearing under experimental conditions.
Human kind has a major impact on the state of life on Earth, mainly caused by habitat destruction, fragmentation and pollution related to agricultural land use and industrialization. Biodiversity is dominated by insects (~50%). Insects are vital for ecosystems through ecosystem engineering and controlling properties, such as soil formation and nutrient cycling, pollination, and in food webs as prey or controlling predator or parasite. Reducing insect diversity reduces resilience of ecosystems and increases risks of non-performance in soil fertility, pollination and pest suppression. Insects are under threat. Worldwide 41 % of insect species are in decline, 33% species threatened with extinction, and a co-occurring insect biomass loss of 2.5% per year. In Germany, insect biomass in natural areas surrounded by agriculture was reduced by 76% in 27 years. Nature inclusive agriculture and agri-environmental schemes aim to mitigate these kinds of effects. Protection measures need success indicators. Insects are excellent for biodiversity assessments, even with small landscape adaptations. Measuring insect biodiversity however is not easy. We aim to use new automated recognition techniques by machine learning with neural networks, to produce algorithms for fast and insightful insect diversity indexes. Biodiversity can be measured by indicative species (groups). We use three groups: 1) Carabid beetles (are top predators); 2) Moths (relation with host plants); 3) Flying insects (multiple functions in ecosystems, e.g. parasitism). The project wants to design user-friendly farmer/citizen science biodiversity measurements with machine learning, and use these in comparative research in 3 real life cases as proof of concept: 1) effects of agriculture on insects in hedgerows, 2) effects of different commercial crop production systems on insects, 3) effects of flower richness in crops and grassland on insects, all measured with natural reference situations
