Mode
Text Size
Log in / Sign up

Microplastic properties significantly influence ammonium removal while environmental factors dominate total nitrogen control in NBSIsMicroplastics Impact Nitrogen Removal in Nature-Based Stormwater Systems

AI-generated summary of the cited source, checked by automated accuracy review. How we work

Key Takeaway
Note that while microplastics influence ammonium removal, environmental factors like pH and C/N ratio dominate total nitrogen control.

This meta-analysis synthesized 19 published studies to evaluate how microplastic (MP) properties, such as particle size, concentration, and polymer type, affect nitrogen removal performance in nature-based stormwater infrastructures (NBSIs). The analysis focused on three primary components: ammonium (NH4-N), nitrate (NO3-N), and total nitrogen (TN).

The findings indicate that NH4-N removal is significantly influenced by MP physical and chemical properties. In contrast, NO3-N removal is co-regulated by environmental conditions like pH and C/N ratio alongside biotic components. For TN removal, environmental factors such as C/N ratio and pH are the predominant controls, with these factors contributing over 60% of the variance. Additionally, machine learning models were evaluated, where XGBoost achieved the highest predictive accuracy with an R > 0.86.

The study provides a theoretical basis for optimizing NBSI design by identifying stage-specific mechanisms of microplastic interference. While the analysis highlights distinct drivers for nitrification and denitrification stages, it is important to note that these results reflect associations between MP properties and nitrogen removal rather than direct clinical or environmental outcomes. The findings may assist in engineering more resilient stormwater systems.

Researchers analyzed 19 studies to understand how microplastics (MPs) affect the way nature-based stormwater infrastructures (NBSIs) remove nitrogen. These systems are vital for cleaning water before it enters our environment. The study looked at how different factors, like the size and concentration of plastic particles, influence these natural cleaning processes.

The findings show that while environmental factors like pH levels and carbon-to-nitrogen ratios are the main drivers for total nitrogen removal, microplastic properties specifically interfere with ammonium removal. This means that the physical characteristics of the plastic—such as its polymer type and size—play a significant role in how well these systems function during specific stages.

These results provide a roadmap for engineers to better design and manage stormwater systems. By understanding exactly how microplastics disrupt nitrogen removal, experts can create more resilient infrastructure. While this study focuses on the mechanics of water treatment rather than direct human health, it offers important data for improving environmental safety.

What this means for you:
Microplastic size and type impact specific stages of nitrogen removal in natural stormwater systems.

Common questions

How do microplastics affect the way water is cleaned?

Microplastics can interfere with the removal of ammonium (NH4-N) from water. The study found that this interference is significantly influenced by the size of the particles, their concentration, and the specific type of polymer used in the plastic.

What are the main factors that control nitrogen removal?

While microplastics affect specific stages, environmental factors like pH levels and the carbon-to-nitrogen (C/N) ratio are the primary controls for total nitrogen removal. These environmental factors account for more than 60% of the control over the process.

How can this information be used to improve infrastructure?

By identifying exactly how and when microplastics interfere with nitrogen stages, engineers can use this data as a theoretical basis to optimize the design and operation of nature-based stormwater systems for better water quality.

Study Details

Study typeMeta analysis
EvidenceLevel 1
PublishedJul 2026
View Original Abstract ↓
Microplastics (MPs) pose a significant threat to ecosystem functions, yet their systematic impact on nitrogen removal in nature-based stormwater infrastructures (NBSIs, e.g., bioretention systems, constructed wetlands) remains poorly understood. This study integrates meta-analysis and machine learning to systematically elucidate how MP properties, system characteristics, and environmental conditions influence nitrogen removal performance in NBSIs. Data from 19 published studies, were used to train and evaluate five machine learning models: extreme gradient boosting (XGBoost), random forest (RF), light gradient boosting (LightGBM), multilayer perceptron (MLP), and Kolmogorov-Arnold network (KAN) models. Results show that MPs most significantly interfere with NH -N removal, primarily influenced by particle size, particle concentration, and polymer type. In contrast, NO-N removal is co-regulated by environmental conditions (pH, C/N ratio) and biotic components (e.g., Typha, Ophiopogon japonicus). Total nitrogen (TN) removal is predominantly controlled by C/N ratio and pH, with SHapley Additive exPlanations (SHAP) analysis showing their cumulative contribution exceeds 60%, indicating that environmental regulation exerts a stronger influence than MP-related variables. Mechanistically, MPs mainly impede the nitrification stage, with comparatively minor effects on denitrification. Among the models tested, XGBoost achieved the highest predictive accuracy (R > 0.86). These findings reveal stage‑specific mechanisms of MP interference and offer a theoretical basis for optimizing the design and operation of NBSIs.
Free Newsletter

Clinical research that matters. Delivered to your inbox.

Join thousands of clinicians and researchers. No spam, unsubscribe anytime.