The innovation doesn’t involve producing a completely organic polymer, but rather to use materials that would otherwise be wasted. “This is the third generation of bioplastics,” says Mario Malinconico, research director of the Italian National Research Council (CNR) and scientific coordinator of the association Assobioplastiche. “We are talking about a kind of production that has not yet become an industrial reality, but for which we already have a lot of prototypes. Wherever there is an agri-food chain with a large amount of process waste, the production of polymers could possibly be introduced.” But how can these materials become competitive? “To analyse this, it is necessary to evaluate the whole lifecycle, from raw material flows to management costs, taking into account the additional recycling and decontamination issues associated with traditional plastics,” continues Malinconico. Although bioplastic still costs 50% more to produce, two main factors will narrow the gap with traditional plastic: firstly, economies of scale once large plants for organic polymeric packaging and the associated logistics chains are set up; and secondly, regulations on non-degradable plastics will be increasingly stringent at a time when oil extraction costs go up year-on-year. According to Malinconico, “the cost differential will ultimately be cancelled out, and biodegradable polymers could overtake traditional plastic in a few years, probably in the early 2020s”. But which features do these 100% bioplastic prototypes have? Observing closely, one first notices their delicate smell, which is the perfume of the plant from which the material has been obtained. “The process we have implemented at IIT is completely water-based,” explains Perotto, “And it takes up to half a day. After optimising the process, it will take just a few hours from waste organic material to obtain the bioplastic.” One of the added values of this process is the sustainability of the production, which is not always taken for granted when dealing with organic materials. The durability of these plastics can be extended to a few months or even years if they are put in a drawer. However, they degrade in a few weeks in the soil or in the sea. The first and most simple application remains non-food packaging, since a little more research needs to be done to verify food safety. At present, regulations are less stringent when food is not involved. Moreover, these bioplastics are edible and can be cooked, but they cannot be used at high temperatures, for example as baking paper or for hot beverages. In this context, at the 2017 global food innovation summit Seeds & Chips, held in Milan, the Italian company Metalvuoto (SAES group) presented an active packaging able to extend shelf lifeand avoid the use of preservatives. A water-based layer, applied on the plastic surfaces of fresh food packaging, is capable of absorbing gases and substances that can quickly deteriorate foods. “New packaging must above all be safe and environmentally friendly,” claims managing director Stefano Tominetti, “But it must also have high performance and be lightweight in order to reduce logistical costs. It is thus possible to pass on significant benefits to consumers, distributors and even to the environment”.
With the high standards required by the food packaging industry, the most likely scenario will be the coexistence of different types of plastics in the next years. In particular, traditional plastics will still be more suitable in those cases where compostability is not a fundamental feature, such as packaging for reuse or recycle, and in high-temperature environments.