We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Degradation of food-contact plastics in use: Effect of temperature and chemical composition
Summary
Researchers examined how common food-contact plastics (polypropylene, polyethylene, PET, and polycarbonate) degrade under conditions that mimic everyday use, including varying temperatures and chemical environments. The study found that elevated temperatures promoted oxidation and hydrolysis of these plastics, while both acidic and alkaline solutions enhanced surface degradation, potentially increasing microplastic release into food and beverages.
Microplastics (MPs) have gained global attention due to their pervasive presence and potential risks to human health. Plastic food containers have been found to release MPs into food or liquids during everyday use, serving as a direct source of human exposure. Understanding the mechanisms and influencing factors of MPs release from plastic containers is therefore of vital importance. In the present work, four types of commonly used plastics, namely polypropylene (PP), polyethylene (PE), polyethylene terephthalate (PET), and polycarbonate (PC) were collected from commercial cups and subjected to conditions mimicking daily use. The surface zeta potential, crystallinity, and functional groups of the plastic sheets were analyzed to investigate the surface degradation of these plastics. Results indicate that elevated temperatures promote the oxidation and hydrolysis of these plastics, leading to a significant increase in surface positive charges and crystallinity. Both acidic and alkaline pH levels of the contacting solution were found to enhance the surface degradation of these plastics, potentially exacerbating the release of MPs. The addition of salt in an alkaline solution notably increases the negative charges on the PP surface. Glucose was observed to accelerate the accumulation of negative charges on PP surfaces across all studied pH conditions.
Sign in to start a discussion.
More Papers Like This
Polyethylene Packaging as a Source of Microplastics: Current Knowledge and Future Directions on Food Contamination
This review summarizes what is known about how polyethylene, the world's most-produced plastic and the most common food packaging material, breaks down into microplastics. Factors like temperature, acidity, and exposure time all accelerate the release of microplastic particles from packaging into food. The review highlights that polyethylene microplastics can also carry other environmental pollutants into our food, but more research is needed on the actual health effects of consuming them.
Evaluating microplastic emission from takeaway containers: A Micro-Raman approach across diverse exposure scenarios
Researchers tested how many microplastics are released from common takeaway food containers made of polypropylene, polystyrene, and PET when exposed to different temperatures and acidic conditions. PET and polystyrene containers released microplastics under all conditions, with significantly more released at high temperatures (100 degrees Celsius). Notably, polypropylene containers released no detectable microplastics, suggesting they may be a safer choice for hot food and beverages.
Generation of microplastic particles during degradation of polycarbonate films in various aqueous media and their characterization
Researchers degraded polycarbonate films in three environmentally relevant aqueous media over 250 days and characterized the microplastic particles produced, finding that hydrolysis in alkaline conditions generated the most particles and that particle morphology and chemical composition differed by degradation medium.
Influence of different food matrices on the abundance, characterization, migration kinetics and hazards of microplastics released from plastic packaging (PP and PET)
Scientists found that plastic food packaging (PP and PET) releases microplastics into food, with acidic and oily foods causing the most release -- over 1,300 particles per piece of packaging. The study showed that aging and oxidation of the plastic accelerate this process, and hazard assessments confirmed these released particles pose risks to human health.
Plastic materials used in the food industry, their influence on health, and potential solutions
This review examines how plastics used in food packaging gradually degrade into microplastics that leach into food and beverages, posing potential health risks to consumers. It surveys the main plastic types used in the food industry, the health concerns associated with microplastic and additive exposure, and proposed solutions including biodegradable alternatives. The findings underscore that everyday food packaging is a significant and underappreciated source of microplastic exposure for the general public.