About IIM

The Institute of Marine Research (IIM-CSIC) is one of the main marine research centers in the Iberian Peninsula. Looking at the Atlantic from Vigo, a city with a strong connection with the sea, the IIM-CSIC faces the challenge of increasing our knowledge about the ocean, from its physical characteristics to the food we take from it and the processes that bind the whole system together.

See more
Research

Research is at the core of the Institute of Marine Research's work. Working along 3 Core Research Themes, which intertwine and connect to each other, the researchers and technicians at the IIM-CSIC look for answers within 9 different research lines.

See more
Innovation

While our research provides us with new knowledge about our sea and shores, at the Institute of Marine Research we are committed to go a step further, creating new collaborations with the industry and other economic activities, be they already 'established' industries, such as fisheries or aquaculture, or 'emerging' ones, such as ocean observation.

See more
Society

Science is not complete until it is shared with society. As a public research institution, the IIM understands that its commitment is with society, fostering a two-way relationship with its surrounding community and an open perspective on science.

See more
Work & Study

Marine scientists, lab technicians, biologists, chemists and engineers, but also economists, lawyers or communicators (both working and in training) contribute to the interdisciplinary nature of our center. With more than 200 employees, the IIM-CSIC is a large community of people who work together for the sake of science, knowledge and sustainability.

See more
News & Events

Do you want to be aware of the latest at the IIM? The Institute has a whole team involved in communication & outreach, sharing all news that arise and organizing events to reach all sectors of society: from other peers working in science to children in schools or our neighbors from Vigo.

See more
Biological Systems and Process

Food industry 4.0

Traditional methods of food processing are quickly evolving to integrate the latest advances in information technology, automation and control along entire supply chains and factories, which is known as the Food Industry 4.0 . The idea behind it is to create synergies among all elements along a processing chain, from primary producers to final consumers, based on data and machine learning to drive improvements in productivity, quality and sustainability.

The Institute of Marine Research is contributing to this revolution with its innovative technologies and approaches. Our researchers and technicians currently work on improved sensors & models for production & traceability. By providing real-time data on the status of a process or product, we allow for greater and more flexible control over production. We also add value to these food products and increase their shelf-life. 

Furthermore, the IIM works on the development of new environmentally-friendly packaging and smart interactive labeling to better inform all the agents along the food chain. Finally, exploring new technologies and methods for the valorization of waste products fosters a circular economy, which, once again, brings our society closer to fully sustainable development.

A common example of integration along the value chain is traceability. Traceability of raw materials can increase the added value of food products and prevent food fraud. Moreover, traceability of contamination and quality also ensures food safety and increases shelf life for many products. Sensing technologies and modeling contribute greatly to this effort by providing real-time data on the status of a process or product, thus allowing for greater control and flexibility to optimize the production dynamically.

Food industry is also demanding environmentally friendly conservation and packaging systems, with smart and interactive labeling to increase shelf life and respond to consumers demands. Consumers also demand a more responsible and circular food industry. Valorization of by-products from the food processing industry also helps to minimize its environmental impact, as well as to create new value chains.

As you can see, the institute has been accompanying the food industry during this fourth revolution in many different aspects; you can read about all our capabilities and associated services below.

 

Research groups

Capabilities

  • Software | Fish-T-TaB Simulator: Temperature simulator for fish stored in tubs and boxes
    Food industry 4.0 Nutrition and Human Health

    This model was developed and applied by members of the EFSA Working Group on the transport/storage of fresh fishery products during the preparatory work on the BIOHAZ Scientific Opinion on the use of "tubs" for transporting and storing fresh fishery products (EFSA-Q-2019-00053). Heat transfer modeling was applied to estimate surface temperature of fish during the temperature-related processes of cooling and subsequently maintaining the chill temperature of the fish (‘cooling’ process) and/or maintaining the chill temperature (‘keeping’ process) for fish kept in ice (in boxes) versus in water and ice (in tubs) under similar transport/storage conditions.

    More information here.

    Related research groups

    Biosystem & Bioprocesses Engineering
  • Software | Kinetics of E. coli inactivation by benzalkonium chloride v1.0
    Food industry 4.0 Biotechnology

    This model and associated code was developed to optimize disinfection protocols and minimize bacterial resistance. This model was applied in the following journal article: Optimization of E. coli Inactivation by Benzalkonium Chloride Reveals the Importance of Quantifying the Inoculum Effect on Chemical Disinfection. Front. Microbiol., 26 June 2018. https://doi.org/10.3389/fmicb.2018.01259

    More information and access to the code here.

    Related research groups

    Biosystem & Bioprocesses Engineering
  • Software | saCeSS: a parallel global optimization library
    Biotechnology Food industry 4.0

    The saCeSS library allows solving non-linear programming (NLP) and mixed-integer non-linear programming (MINLP) problems. It also offers efficient local solvers for nonlinear parameter estimation problems associated with complex models (e.g. those described by differential equations).

    More information here.

     

    Related research groups

    Biosystem & Bioprocesses Engineering
  • Software | AMIGO2: Advanced Modelling and Identification using Global Optimization, version 2
    Food industry 4.0 Biotechnology

    AMIGO2 is a MATLAB-based multiplatform toolbox designed to solve mathematical optimization problems at the core of systems biology, within the context of parametric model identification, the underlying hypothesis for model development and the optimal control of biological systems to synthetically achieve the desired behavior.

    More information here.

    Related research groups

    Biosystem & Bioprocesses Engineering

Services

Active projects