Could nanoplastics in the environment turn E. coli into a bigger villain?

University of Illinois College of Agricultural, Consumer and Environmental Sciences

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Clusters of nanoplastics (red arrows) bind to E. coli O157:H7. Award winning image by Jayashree Nath, first author of the University of Illinois Urbana-Champaign study.

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Credit: Jayashree Nath

URBANA, Ill. -- Nanoplastics are everywhere. These fragments are so tiny they can accumulate on bacteria and be taken up by plant roots; they’re in our food, our water, and our bodies. Scientists don’t know the full extent of their impacts on our health, but new research from University of Illinois Urbana-Champaign food scientists suggests certain nanoplastics may make foodborne pathogens more virulent. 

“Other studies have evaluated the interaction of nanoplastics and bacteria, but so far, ours is the first to look at the impacts of microplastics and nanoplastics on human pathogenic bacteria. We focused on one of the key pathogens implicated in outbreaks of foodborne illness — E. coli O157:H7,” said senior study author Pratik Banerjee, associate professor in the Department of Food Science and Human Nutrition and an Illinois Extension Specialist; both units are part of the College of Agricultural, Consumer and Environmental Sciences at Illinois.

Banerjee’s team found that nanoplastics with positively charged surfaces were more likely to cause physiological stress in E. coli O157:H7. Just as a stressed dog is more likely to bite, the stressed bacteria became more virulent, pumping out more Shiga-like toxin, the chemical that causes illness in humans. 

The researchers expected positively charged nanoplastics to impact E. coli because the bacteria’s surface carries a negative charge. To test their opposites-attract hypothesis, they created nanoplastics from polystyrene — the material in those ubiquitous white clamshell-style takeout boxes — and applied positive, neutral, or negative charges before introducing the particles to E. coli either free-floating in solution or in biofilms.

“We started with the surface charge. Plastics have an enormous ability to adsorb chemicals. Each chemical has a different effect on surface charge, based on how much chemical is adsorbed and on what kind of plastic,” Banerjee said. “We didn’t look at the effects of the chemicals themselves in this paper — that’s our next study — but this is the first step in understanding how the surface charge of plastics impacts pathogenic E. coli response.”

The bacteria exposed to positively charged nanoplastics showed stress in multiple ways, not just by producing more Shiga-like toxin. They also took longer to multiply when free-floating and congregated into biofilms more slowly. However, growth eventually rebounded.

Biofilms give bacterial cells a measure of protection thanks to an extracellular coating they develop. To test whether this coating protected against nanoplastic-induced stress, the team dunked comparatively large microplastic particles into the bacterial soup and gave E. coli a week or two to colonize. Then, they introduced the same charged nanoplastics. 

The positively charged particles still caused stress — and enhanced Shiga-like toxin production — in biofilm-bound E. coli.

“Biofilms are a very robust bacterial structure and are hard to eradicate. They’re a big problem in the medical industry, forming on inserts like catheters or implants, and in the food industry,” Banerjee said. “One of our goals was to see what happens when this human pathogen, which is commonly transmitted via food, encounters these nanoplastics from the vantage point of a biofilm.”

Interactions with plastic particles may be doing more than increasing E. coli’s toxicity; other studies have shown biofilms on microplastics may serve as hotspots for the transfer of antibiotic resistance genes, making the bacteria harder to manage. Banerjee’s group has studies underway to look at resistance gene transfer and changes in virulence and transmission patterns of major foodborne pathogens in food products and other environments such as soil.

The study, “Nanoplastics-mediated physiologic and genomic responses in pathogenic Escherichia coli O157:H7,” is published in the Journal of Nanobiotechnology [DOI: 10.1186/s12951-025-03369-z]. The research was supported in part by a USDA National Institute of Food and Agriculture grant [# ILLU-698-981]. 

Banerjee is also affiliated with the Carl R. Woese Institute for Genomic Biology and the Center for South Asian and Middle Eastern Studies at U. of I.

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Journal

Journal of Nanobiotechnology

DOI

10.1186/s12951-025-03369-z 

 

New research highlights health benefits of using heritage art practices in art therapy

Drexel University

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Examples of a participant completing the puzzle-making task (left) and the heritage artmaking task (right).

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Credit: Photo from The Arts in Psychotherapy

Heritage art practices include indigenous and traditional arts practices — such as fiber arts, clay work, distinct painting styles etc. — handed down in families or communities across generations. The fact that they have been sustained for generations, and helped to serve the expressive and psychosocial needs of communities, suggest that they could be ideal approaches to support mental health and emotional well-being. To better understand their potential therapeutic benefits, researchers from Drexel University’s College of Nursing and Health Professions examined the impact of these practices on mental and physical health. 

Led by Girija Kaimal, EdD, professor in the College of Nursing and Health Professions, the study showed that heritage artforms can improve mood and reduce anxiety. Results were recently published in The Arts in Psychotherapy.

“When we engage in preferred heritage artforms, they can help us manage our moods including reducing negativity, improving positive feelings and reducing feelings of anxiety,” said Kaimal. “Most heritage artforms are typically simple in basic techniques, making them easy to learn, but then allow for refinement, artistic exploration and complexity. We don't need advanced skills or supplies. Simple creative practices can serve as preventive mental health resources.”

Kaimal explained that in previous studies they have highlighted how to distinguish between indigenous and traditional arts practices. Indigenous art practices relate to a specific community in geographical region. They include sacred belief systems, spirituality and community history that tend to be more specific in their applications. In undertaking these practices, individuals need to be respectful of the community’s guidance around using imagery, including being mindful about harmful appropriation. Traditional creative practices are those that are handed down across generations and are more open to adaptation and interpretation.

In this current study, the research team collected data from sites in the United States, Japan and India. Fifty-four participants completed two sessions: one where they engaged in a preferred heritage art practice for 45 minutes and one where they put together jigsaw puzzles for 45 minutes.

In the U.S., participants could practice activities like creating temporary body art with natural henna; or cross-stitch, the embroidering of patterns. In Japan, participants engaged in creating works using approaches like mizuhiki, tying decorative knots with thin paper strings, or calligraphy. In India, participants engaged in pookalam, creating artworks using natural media, like plants, flowers and clay, as well as using a range of heritage arts practices, such as madhubani, a style of painting.

All participants completed standardized questionnaires before and after both sessions to measure anxiety, mood and affect, perceived stress, self-efficacy and creative agency. Participants reported more positive feelings and less negative feelings after the heritage art task compared to the puzzle task, showing that practicing heritage artforms can have significant mental health benefits.

“The findings highlight the value of tapping into tools we have right in our homes,” said Kaimal. “There is a reason these practices have survived over time. The acts of using our hands and eyes to create something is rewarding and calming on multiple levels both physiological and emotional.”

Kaimal and the research team are planning to build on this study by examining a wide range of heritage practices at sites around the world. Further analysis of qualitative data from all of the sites is also underway. Additionally, the researchers are developing an open-access book as a resource for psychosocial support specialists and art therapists.

“We see tremendous potential for indigenous arts practices to be a public health approach for mental health and well-being,” said Kaimal. “Heritage arts practices are often ignored or treated as artifacts alone. They can, however, be integrated into our lives as we were meant to use them in our evolutionary history: as a creative resource for self-regulation and well-being.”

Read the full study here: https://www.sciencedirect.com/science/article/pii/S0197455625000243.

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Journal

The Arts in Psychotherapy

DOI

10.1016/j.aip.2025.102271 

Article Title

Psychosocial benefits of engaging in heritage arts practices in art therapy

Artwork Example from the US: Henna.

Artwork Example from Japan: Mizuhiki.

Artwork Example from India: Pookalam.

 

Artwork Example from the US: Cross-Stitch.

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Photo from The Arts in Psychotherapy.

 

UTA-based TMAC wins award for pioneering pollution tech

Real-time sensor data helps Texas manufacturers reduce costs and lower reduce emissions

University of Texas at Arlington

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The University of Texas at Arlington-based Texas Manufacturing Assistance Center, known as TMAC, is helping the state's manufacturers reduce pollution with real-time sensors that track their environmental impact. The innovative effort is producing results that could transform how companies protect air and water quality.

The program recently earned TMAC an Environmental Excellence award from the Texas Commission on Environmental Quality issued by Governor Greg Abbott for technical innovation.

“Our mission at TMAC is to help Texas businesses be more efficient and accelerate their growth, and that’s exactly what we did with this environmental program,” said TMAC Executive Director Rodney Reddic. “This also serves as a scalable model for manufacturers to help promote environmental leadership while improving manufacturing efficiency and reducing costs.”

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Credit: UTA

The University of Texas at Arlington-based Texas Manufacturing Assistance Center, known as TMAC, is helping the state's manufacturers reduce pollution with real-time sensors that track their environmental impact. The innovative effort is producing results that could transform how companies protect air and water quality.

The program recently earned TMAC an Environmental Excellence award from the Texas Commission on Environmental Quality issued by Governor Greg Abbott for technical innovation.

“Our mission at TMAC is to help Texas businesses be more efficient and accelerate their growth, and that’s exactly what we did with this environmental program,” said TMAC Executive Director Rodney Reddic. “This also serves as a scalable model for manufacturers to help promote environmental leadership while improving manufacturing efficiency and reducing costs.”

Related: TMAC project aims to strengthen defense department supply chain

This is the first large-scale effort in Texas to use sensors for real-time pollution prevention. Building on its work with video systems to improve operations, TMAC tested a range of sensors that could measure energy use, water consumption, air quality, temperature and humidity. The goal was straightforward: measure current environmental conditions, recommend changes, then use sensors to track the results and document the improvements.

With one client, a fulfillment packager of snack protects, TMAC installed six sensors on packaging equipment. Data from a sensor measuring electricity use on an air compressor revealed significant energy waste—421,200 kWh a year—caused by air leaks, costing the client $39,171 annually. Fixing those leaks helped prevent 228 metric tons of carbon dioxide from being released. Encouraged by these savings, the client plans to expand the sensor technology to other Texas facilities, expecting to save $195,000 more.

Related: TMAC helping businesses prevent pollution

Working with an automobile parts supplier, TMAC used a flow sensor to monitor water use in the company’s automated washing chambers. The team detected excess water consumption and offered recommendations to reduce waste. Initial results are promising, with potential savings of nearly 3.5 million gallons of water annually.

TMAC also used an electric particulate sensor with a military parts manufacturer to detect air leaks that risked equipment failure and compromised product quality. Identifying these leaks could help the company save nearly $450,000 a year in operating costs.

“The success of any operational improvement and pollution prevention effort is only as good as the organization's ability to implement change and specific action steps to generate positive impacts,” said Kurt Middelkoop, TMAC sustainability advisor.

Middelkoop is the principal investigator on a grant from the U.S. Environmental Protection Agency that provided startup funds for the project.

“The accuracy of sensor data minimizes human error, offering leadership precise insights to evaluate the return on investment and environmental improvements,” Middelkoop added. “TMAC's sensor technology deployment not only helps companies reduce their environmental footprint, but it also ensures that Texas remains a leader in manufacturing and environmental stewardship, safeguarding our natural resources for future generations.”

The University of Texas at Arlington-based Texas Manufacturing Assistance Center, known as TMAC, is helping the state's manufacturers reduce pollution with real-time sensors that track their environmental impact. The innovative effort is producing results that could transform how companies protect air and water quality.

The program recently earned TMAC an Environmental Excellence award from the Texas Commission on Environmental Quality issued by Governor Greg Abbott for technical innovation.

Credit

UTA

About The University of Texas at Arlington (UTA)

Celebrating its 130th anniversary in 2025, The University of Texas at Arlington is a growing public research university in the heart of the thriving Dallas-Fort Worth metroplex. With a student body of over 41,000, UTA is the second-largest institution in the University of Texas System, offering more than 180 undergraduate and graduate degree programs. Recognized as a Carnegie R-1 university, UTA stands among the nation’s top 5% of institutions for research activity. UTA and its 280,000 alumni generate an annual economic impact of $28.8 billion for the state. The University has received the Innovation and Economic Prosperity designation from the Association of Public and Land Grant Universities and has earned recognition for its focus on student access and success, considered key drivers to economic growth and social progress for North Texas and beyond.

 

Can nano-encapsulation make pesticides safer for aquatic ecosystems?

Chinese Society for Environmental Sciences

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This schematic illustrates the life cycle of conventional imidacloprid (IMI) and its nano-encapsulated form (nano-IMI), from production and field application to environmental emissions. While both enter agricultural soils, nano-IMI exhibits lower freshwater release due to processes such as aggregation and attachment in the soil, as well as rapid sedimentation in freshwater—highlighting its potential to reduce aquatic ecological risks.

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Credit: Environmental Science and Ecotechnology

Nanotechnology is transforming pesticide design with the promise of precision targeting and prolonged effectiveness. But how environmentally friendly are these innovations? A new study offers the first comprehensive life-cycle comparison between conventional imidacloprid (IMI) and its nano-encapsulated version (nano-IMI), tracking their environmental impacts from production through freshwater emissions. While nano-IMI incurs higher ecological costs during manufacturing, its environmental risks at the end-of-life stage are dramatically lower. Using an integrated assessment approach, researchers found that nano-IMI reduced freshwater ecotoxicity impact scores by up to five orders of magnitude compared to IMI. These findings highlight the importance of evaluating agrochemicals through a full lifecycle lens when developing safer alternatives.

As global demand for food continues to rise, pesticide usage is intensifying—bringing unintended ecological consequences. Nanopesticides, which allow for controlled release and targeted action, are positioned as a more efficient and less environmentally disruptive solution. However, uncertainties persist, particularly regarding their fate in ecosystems post-application. Traditional risk assessment methods often neglect early-stage emissions and fail to capture the complex behaviors of engineered nanomaterials in natural environments. The lack of robust ecotoxicity data and the absence of life-cycle-based regulatory guidelines further limit our understanding. These challenges underscore the urgent need to examine nanopesticide risks from synthesis to environmental degradation.

To address these concerns, researchers from Jinan University and the University of Wisconsin–Madison published a study (DOI: 10.1016/j.ese.2025.100565) in Environmental Science and Ecotechnology on April 25, 2025. The team evaluated nano-encapsulated version (nano-IMI) and conventional imidacloprid (IMI) using a novel framework that integrates life cycle assessment (LCA), the USEtox ecotoxicity model, and the SimpleBox4Nano/SimpleBox fate model. This approach enabled the researchers to assess both production-stage environmental burdens and freshwater ecotoxicity, offering one of the most complete comparisons of nano- versus conventional pesticide formulations to date. The researchers chose imidacloprid, a widely used neonicotinoid insecticide, as a representative case. Their analysis showed that producing nano-IMI resulted in approximately four times greater ecotoxicity than conventional IMI, mainly due to the energy-intensive encapsulation process. However, once released into the environment, nano-IMI behaved differently. Modeling across various rainfall conditions revealed that nano-IMI had significantly lower freshwater emissions, thanks to its high soil retention and aggregation tendencies in water. Even when accounting for the eventual release of the active ingredient from nano-IMI, the overall ecological impact remained far below that of conventional IMI. These results suggest that although nano-formulations may increase production-related impacts, they can drastically reduce environmental harm during use and disposal.

“By combining traditional life cycle analysis with nano-specific fate modeling, we’ve introduced a robust tool for assessing the total environmental impact of nano-agrochemicals,” said Dr. Fan Wu, senior author of the study. “Our findings suggest that while nano-pesticides may require more resources to produce, their environmental behavior post-application can be far more favorable. This research lays the groundwork for smarter pesticide regulation and highlights the need to consider environmental risks across the entire product life cycle—not just at the point of use.”

This study marks an important step toward regulatory frameworks that reflect the unique behaviors of nanopesticides. The integrated modeling approach allows decision-makers to weigh the environmental trade-offs of production against long-term ecological risks. With the global nanopesticide market expected to grow from $735 million in 2024 to over $2 billion by 2032, such insights are both timely and essential. The research also highlights opportunities to improve manufacturing through green chemistry and sustainable nanocarrier design. Ultimately, full life-cycle assessments can help steer innovation toward agrochemical solutions that protect crops without compromising the health of aquatic ecosystems.

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References

DOI

10.1016/j.ese.2025.100565

Original Source URL

https://doi.org/10.1016/j.ese.2025.100565

Funding information

This work is supported by the National Natural Science Foundation of China (42107286), the Natural Science Foundation of Guangdong Province (2023A1515011215), Guangzhou Basic and Applied Basic Research Foundation (2024A04J9882), the Fundamental Research Funds for the Central Universities (21623214), and the Department of Education of Guangdong Province (2020KCXTD005).

About Environmental Science and Ecotechnology

Environmental Science and Ecotechnology (ISSN 2666-4984) is an international, peer-reviewed, and open-access journal published by Elsevier. The journal publishes significant views and research across the full spectrum of ecology and environmental sciences, such as climate change, sustainability, biodiversity conservation, environment & health, green catalysis/processing for pollution control, and AI-driven environmental engineering. The latest impact factor of ESE is 14, according to the Journal Citation ReportTM 2024.

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Journal

Environmental Science and Ecotechnology

DOI

10.1016/j.ese.2025.100565 

Subject of Research

Not applicable

Article Title

A life cycle risk assessment of nanopesticides in freshwater