Descripción del proyecto
Larvas de moscas que comen desperdicios alimentarios al rescate
La gestión de los desperdicios alimentarios y la contaminación por plásticos derivados del petróleo es una preocupación mundial creciente. Una solución es valorizar los flujos de residuos mediante biopolímeros y productos bioplásticos de valor añadido derivados de los desperdicios alimentarios de baja calidad. En la actualidad, los elevados costes de producción de los bioplásticos impiden su inserción en el mercado. Para superar este reto, el equipo del proyecto BioLaMer, financiado con fondos europeos, demostrará una prueba de principio innovadora de una biorrefinería de larvas de mosca mediante el establecimiento de larvas de mosca soldado negra («Hermetia illucens») como materia prima de alto impacto para la producción rentable de polihidroxialcanoatos y biopolímeros de quitosano. La solución de las larvas es renovable y barata, presenta menos complejidad ya que las larvas tienen una composición química invariable, mitiga el problema de los desperdicios alimentarios, reduce los insumos de materias primas, es respetuosa con la biodiversidad y evita/reduce los costes de pretratamiento para la producción de biopolímeros.
Objetivo
Management of food waste (FW) and petroleum plastics pollution are two significant global challenges. Developing biopolymers and added-value bioplastic products from low-grade FW is, thus, a key enabler to tackle both issues. Despite extensive R&D efforts to valorise waste streams including FW to bioplastics, the widespread market penetration of bioplastics is hindered due to their high production cost.
BioLaMer aims to demonstrate a novel proof of principle fly larvae biorefinery by establishing food eating black soldier fly larvae (Hermetia illucens) as a high impact feedstock for cost-effective production of two biopolymers, polyhydroxyalkanoates (PHA) and chitosan. The advantages of the larvae route are that it: i) is renewable and inexpensive; ii) provides less complexity as the larvae has invariable chemical composition; iii) can be used to mitigate the FW problem; iv) can reduce raw material inputs, thus minimizing energy utilization; v) doesn’t disturb the biodiversity; and vi) can avoid/reduce pre-treatment costs associated with the waste-streams to produce the platform chemicals for biopolymer production.
The innovative BioLaMer biorefinery will improve the bioreactor process efficiency and cut down the PHA production cost significantly compared to existing technologies. BioLaMer will combine its conceptual innovations, complementary interdisciplinary expertise and bioreactor process expertise to develop cost-effective PHA and chitosan production technologies, supported by life cycle thinking/analysis and hybrid models developed using machine learning platform. Further, the significant environmental, economic, and societal impacts (that supports the EU Circular Economy, Green Deal, Food Waste, and Plastic strategies/initiatives) of BioLaMer will be demonstrated through the involvement of SSH, communication and circularity demonstration partners.
Ámbito científico
- engineering and technologyenvironmental biotechnologybioremediationbioreactors
- engineering and technologyenvironmental engineeringenergy and fuelsfossil energypetroleum
- social scienceseconomics and businesseconomicssustainable economy
- engineering and technologyindustrial biotechnologybiomaterialsbioplasticspolyhydroxyalkanoates
- natural sciencescomputer and information sciencesartificial intelligencemachine learning
Palabras clave
Programa(s)
- HORIZON.3.1 - The European Innovation Council (EIC) Main Programme
Convocatoria de propuestas
HORIZON-EIC-2022-PATHFINDEROPEN-01
Consulte otros proyectos de esta convocatoriaRégimen de financiación
HORIZON-EIC - HORIZON EIC GrantsCoordinador
D02 CX56 DUBLIN 2
Irlanda