Machine Learning to Predict the Adsorption Capacity of Microplastics

Astray, Gonzalo; Soria-López, Anton; Barreiro, Enrique Wulff; Mejuto, J. C.; Cid‐Samamed, Antonio

doi:10.3390/nano13061061

Cited by 15 publications

(7 citation statements)

References 62 publications

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“…Generally, the photo-oxidation of MNPs may enhance the adsorption of hydrophobic OPs and reduce the adsorption of hydrophilic OPs due to enhanced O-containing functional groups. , However, in some cases, it is complex and depends on many factors including polymer types of MNPs, oxidation degree, and physicochemical properties of OPs. ,, There is a lack of knowledge to evaluate the effects of the photo-oxidation degree and the physicochemical properties of OPs on their adsorption processes on MNPs. Integrating experimental data with advanced analytical methods, such as molecular dynamic simulations and machine learning, , offers a comprehensive approach for understanding the adsorption mechanism of MNPs after photo-oxidation, and establish the multidimensional relationship between the adsorption capacity of MNPs, the photo-oxidation degree (e.g., the carbonyl index and hydroxyl index, and the physicochemical properties of pollutants (e.g., molecular weight, log K OW , zeta potential, type, and number of functional groups).…”

Section: Future Perspectivesmentioning

confidence: 99%

“…69,73,80 There is a lack of knowledge to evaluate the effects of the photo-oxidation degree and the physicochemical properties of OPs on their adsorption processes on MNPs. Integrating experimental data with advanced analytical methods, such as molecular dynamic simulations 229 and machine learning, 230,231 offers a comprehensive approach for understanding the adsorption mechanism of MNPs after photo-oxidation, and establish the multidimensional relationship between the adsorption capacity of MNPs, the photo-oxidation degree (e.g., the carbonyl index and hydroxyl index, and the physicochemical properties of pollutants (e.g., molecular weight, log K OW , zeta potential, type, and number of functional groups). coexisting natural colloids.…”

Section: Relate the Adsorption Capacity Of Mnps To Thementioning

confidence: 99%

See 1 more Smart Citation

Photo-oxidation of Micro- and Nanoplastics: Physical, Chemical, and Biological Effects in Environments

Xu,

Ou,

van der Hoek

et al. 2024

Environ. Sci. Technol.

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Micro-and nanoplastics (MNPs) are attracting increasing attention due to their persistence and potential ecological risks. This review critically summarizes the effects of photo-oxidation on the physical, chemical, and biological behaviors of MNPs in aquatic and terrestrial environments. The core of this paper explores how photo-oxidation-induced surface property changes in MNPs affect their adsorption toward contaminants, the stability and mobility of MNPs in water and porous media, as well as the transport of pollutants such as organic pollutants (OPs) and heavy metals (HMs). It then reviews the photochemical processes of MNPs with coexisting constituents, highlighting critical factors affecting the photo-oxidation of MNPs, and the contribution of MNPs to the phototransformation of other contaminants. The distinct biological effects and mechanism of aged MNPs are pointed out, in terms of the toxicity to aquatic organisms, biofilm formation, planktonic microbial growth, and soil and sediment microbial community and function. Furthermore, the research gaps and perspectives are put forward, regarding the underlying interaction mechanisms of MNPs with coexisting natural constituents and pollutants under photo-oxidation conditions, the combined effects of photo-oxidation and natural constituents on the fate of MNPs, and the microbiological effect of photoaged MNPs, especially the biotransformation of pollutants.

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Section: Future Perspectivesmentioning

confidence: 99%

Section: Relate the Adsorption Capacity Of Mnps To Thementioning

confidence: 99%

Photo-oxidation of Micro- and Nanoplastics: Physical, Chemical, and Biological Effects in Environments

Xu,

Ou,

van der Hoek

et al. 2024

Environ. Sci. Technol.

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“…Microplastic pollution may be one of the most widespread and persistent anthropogenic changes to Earth’s surface [ 22 ]. MPs are emerging pollutants that may play roles as mediators in the environment [ 23 , 24 ]. MPs can be carriers of other toxic pollutants, including both organic and inorganic pollutants [ 25 ], bacteria, and deadly viruses [ 23 ], and can quickly disperse toxic substances into the environment, thus affecting organisms.…”

Section: Introductionmentioning

confidence: 99%

“…Astray et al used random forests, support vector machines, and artificial neural networks to study the adsorption capacities of different MPs to organic pollutants, and the correlation coefficient of the best selected machine learning model was greater than 0.92, indicating that these types of models could be used to quickly estimate the adsorption of organic pollutants by MPs [ 26 ]. Cid-Samamed et al believed that the addition of mono- and bivalent salt surfactants via polymer modification could assist in trapping microplastics and achieve the aggregation of microplastics in aquatic systems [ 24 ]. At present, the methods used for the analysis and identification of MPs can be divided into the three following categories: (1) physical morphology characterization analysis methods (i.e., microscopic imaging analysis), including scanning electron microscopy (SEM), scanning electron microscopy–energy dispersive spectrometry (SEM-EDS), atomic force microscopy (AFM), and fluorescence microscopic imaging (FMI); (2) chemical component spectral analysis, including near-infrared (NIR) spectrometry, Fourier transform infrared (FTIR) spectrometry, and Raman spectroscopy; and (3) thermal analysis techniques, such as differential scanning calorimetry (DSC), pyrolytic gas chromatography–mass spectrometry (Pyr-GC/MS), and thermogravimetric analysis (TGA).…”

Section: Introductionmentioning

confidence: 99%

Traceability of Microplastic Fragments from Waste Plastic Express Packages Using Near-Infrared Spectroscopy Combined with Chemometrics

Fu,

Pan,

Chen

et al. 2024

Molecules

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The pollution from waste plastic express packages (WPEPs), especially microplastic (MP) fragments, caused by the blowout development of the express delivery industry has attracted widespread attention. On account of the variety of additives, strong complexity, and high diversity of plastic express packages (PEPs), the multi-class classification of WPEPs is a typical large-class-number classification (LCNC). The traceability and identification of microplastic fragments from WPEPs is very challenging. An effective chemometric method for large-class-number classification would be very beneficial for the comprehensive treatment of WPEP pollution through the recycling and reuse of waste plastic express packages, including microplastic fragments and plastic debris. Rather than using the traditional one-against-one (OAO) and one-against-all (OAA) dichotomies, an exhaustive and parallel half-against-half (EPHAH) decomposition, which overcomes the defects of the OAO’s classifier learning limitations and the OAA’s data proportion imbalance, is proposed for feature selection. EPHAH analysis, combined with partial least squares discriminant analysis (PLS-DA) for large-class-number classification, was performed on 750 microplastic fragments of polyethylene WPEPs from 10 major courier companies using near-infrared (NIR) spectroscopy. After the removal of abnormal samples through robust principal component analysis (RPCA), the root mean square error of cross-validation (RMSECV) value for the model was reduced to 0.01, which was 21.5% lower than that including the abnormal samples. The best models of PLS-DA were obtained using SNV combined with SG-17 smoothing and 2D (SNV+SG-17+2D); the latent variables (LVs), the error rates of Monte Carlo cross-validation (ERMCCVs), and the final classification accuracies were 6.35, 0.155, and 88.67% for OAO-PLSDA; 5.37, 0.103, and 87.33% for OAA-PLSDA; and 3.12, 0.054, and 96.00% for EPHAH-PLSDA. The results showed that the EPHAH strategy can completely learn the complex LCNC decision boundaries for 10 classes, effectively break the tie problem, and greatly improve the voting resolution, thereby demonstrating significant superiority to both the OAO and OAA strategies in terms of classification accuracy. Meanwhile, PLS-DA further maximized the covariance and data interpretation abilities between the potential variables and categories of microplastic debris, thereby establishing an ideal performance identification model with a recognition rate of 96.00%.

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“…Measuring the adsorption and evaluating the magnitude of these impacts for every combination of compound, polymer composition, and environmental condition are daunting tasks. With the advent of machine learning (ML), the adsorption capacities of microplastics for unstudied chemicals can be predicted with a high degree of accuracy. , In this study, we obtained the adsorption capacity and affinity of 16 polymer compositions for over 40 xenobiotics under environmental conditions. Using these data, we trained two ML models, Random Forest (RF) and Artificial Neural Network (ANN), which were used to predict Linear, Freundlich, and Langmuir isotherms for a set of xenobiotics and polymer compositions.…”

Section: Introductionmentioning

confidence: 99%

Machine Learning Prediction of Adsorption Behavior of Xenobiotics on Microplastics under Different Environmental Conditions

Bryant

2023

ACS EST Water

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There have been mounting concerns over microplastics as a vector of environmental xenobiotics recently. Adsorption plays a pivotal role in this process, which varies with the properties of xenobiotics, the characteristics of microplastics, and environmental conditions. The vast number of xenobiotics and the diversity of microplastics, as well as the continuous weathering of microplastics in the environment, make it unrealistic to measure the adsorption capacity and affinity of each combination of xenobiotics, microplastics, and environmental conditions in laboratory studies. Random Forest (RF) and Artificial Neural Network (ANN) algorithms were used to predict the adsorption affinity of xenobiotics on microplastics and elucidate the impact of environmental parameters. pH is responsible for a large variation in the results through its effect on the dissociation of ionizable xenobiotics and the surface charge of microplastics. The aging status of microplastics had a smaller but still significant impact on adsorption affinity, with pristine particles generally having a higher affinity. The results shed light on the potential alteration of the fate and impact of xenobiotics by microplastics. As more data become available in the future, the precision of machine learning (ML) models can be further improved. Overall, our study demonstrated the potential of ML in predicting the adsorption of a wide range of xenobiotics on microplastics.

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Machine Learning to Predict the Adsorption Capacity of Microplastics

Cited by 15 publications

References 62 publications

Photo-oxidation of Micro- and Nanoplastics: Physical, Chemical, and Biological Effects in Environments

Photo-oxidation of Micro- and Nanoplastics: Physical, Chemical, and Biological Effects in Environments

Traceability of Microplastic Fragments from Waste Plastic Express Packages Using Near-Infrared Spectroscopy Combined with Chemometrics

Machine Learning Prediction of Adsorption Behavior of Xenobiotics on Microplastics under Different Environmental Conditions

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