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61,005 resultsShowing papers similar to Sorption of Pharmaceuticals on Microplastics
ClearSorption of selected pharmaceutical compounds on polyethylene microplastics: Roles of pH, aging, and competitive sorption
Researchers found that polyethylene microplastics adsorb pharmaceutical compounds including an antibiotic, a beta-blocker, and an antidepressant, with sorption capacity influenced by pH, aging of the plastic, and competition between compounds — raising concern about microplastics as carriers of pharmaceuticals in aquatic environments.
Sorption of pharmaceuticals on the surface of microplastics
Researchers tested the ability of four common microplastic types to adsorb nine pharmaceutical compounds frequently found as water pollutants. They found that sorption involved both hydrophobic and electrostatic interactions, but under natural environmental conditions the binding was relatively weak. The study suggests that while microplastics can interact with pharmaceutical residues, their role as carriers of these contaminants in real aquatic environments may be more limited than previously assumed.
Pharmaceuticals and micro(nano)plastics in the environment: Sorption and analytical challenges
This review examines how pharmaceutical residues and micro- and nanoplastics interact in water environments, finding that microplastics can adsorb medications and alter their environmental behavior. Factors like plastic type, surface area, and biological film growth all influence these interactions, but very few studies have been conducted under real-world conditions. The authors highlight persistent analytical challenges and the need for field-based research to understand actual risks.
Aging dominated effects of environmental microplastics on the sorption and toxic potential of typical pharmaceutical
This study examined how aging alters microplastic surface properties and their sorption of pharmaceuticals (including naproxen) and effects on aquatic toxicity. Aged MPs showed different sorption behavior and toxicity compared to pristine MPs, with aging-dominated effects shifting the risk profile of pharmaceutical-MP co-exposure.
Sorption of pharmaceuticals over microplastics’ surfaces: interaction mechanisms and governing factors
Researchers reviewed the sorption mechanisms by which pharmaceuticals interact with microplastic surfaces in the environment. The study found that electrostatic interactions, hydrogen bonding, and hydrophobic forces are the primary mechanisms governing pharmaceutical adsorption onto microplastics, suggesting that microplastics can serve as vectors for transporting pharmaceutical contaminants through ecosystems.
Mini Review on Recent Advances of the Adsorption Mechanism Between Microplastics and Emerging Contaminants for Conservation of Water
This mini-review examines the adsorption mechanisms between microplastics and emerging contaminants such as pharmaceuticals, highlighting how physicochemical properties like hydrophobicity and pH influence pollutant uptake onto different polymer types. The review synthesizes recent advances relevant to understanding how microplastics act as vectors for pharmaceutical contaminants in aquatic environments.
Sorption and desorption of selected pharmaceuticals by polyethylene microplastics
Researchers tested the sorption and desorption of three pharmaceuticals — sulfamethoxazole, propranolol, and sertraline — onto polyethylene microplastics in water, finding that all three compounds sorbed to the plastic surface and were only partially released over time. The results suggest microplastics can act as vectors for pharmaceutical compounds in aquatic environments, potentially affecting their bioavailability.
Adsorption of a diverse range of pharmaceuticals to polyethylene microplastics in wastewater and their desorption in environmental matrices
Researchers investigated how polyethylene microplastics adsorb pharmaceuticals in municipal wastewater and release them in environmental and biological fluids. They found that drug adsorption depended heavily on the compound's charge and hydrophobicity, with cationic and hydrophobic drugs adsorbing most readily. The study suggests that microplastics could act as vectors for certain pharmaceuticals, potentially transporting them through waterways and into organisms.
Interaction between Microplastics and Pharmaceuticals Depending on the Composition of Aquatic Environment
This review examines how aquatic environmental conditions — including dissolved organic matter, salinity, pH, and temperature — influence the adsorption and desorption of pharmaceuticals onto microplastic surfaces, showing that water composition significantly affects the extent to which microplastics act as vectors for drug contaminants.
Sorption of three common nonsteroidal anti-inflammatory drugs (NSAIDs) to microplastics
This study investigated the adsorption of three common nonsteroidal anti-inflammatory drugs (NSAIDs) onto microplastics, finding that polymer type, drug properties, and environmental conditions all influenced sorption capacity. The results suggest microplastics can act as vectors for pharmaceutical contaminants in aquatic environments.
Sorption of diclofenac by polystyrene microplastics: Kinetics, isotherms and particle size effects
Researchers investigated the sorption of the pharmaceutical diclofenac onto polystyrene microplastics of different sizes, finding that sorption capacity increased with particle size and was influenced by environmental factors such as pH, ionic strength, and dissolved organic matter.
Effect of Aging on Physicochemical Properties and Size Distribution of PET Microplastic: Influence on Adsorption of Diclofenac and Toxicity Assessment
Researchers studied how environmental aging changes the physical and chemical properties of PET microplastics and their ability to absorb pharmaceutical pollutants. They found that aged microplastics had rougher surfaces and greater capacity to adsorb diclofenac, a common pain medication found in waterways. The study suggests that weathered microplastics may act as more effective carriers of pharmaceutical contaminants in the environment compared to fresh plastics.
Surface functional groups determine adsorption of pharmaceuticals and personal care products on polypropylene microplastics
Researchers found that surface functional groups on aged polypropylene microplastics determined their adsorption capacity for pharmaceuticals and personal care products, with aged plastic showing much higher pollutant uptake than fresh plastic due to weathering-induced surface changes.
Adsorption behavior and interaction mechanism of microplastics with typical hydrophilic pharmaceuticals and personal care products
This study examined how different types of microplastics adsorb hydrophilic pharmaceuticals and personal care products (PPCPs) in aquatic environments, finding that polymer type and surface properties governed the interaction mechanisms. The results indicate that microplastics can act as vectors for these emerging contaminants.
Unravelling the complex interactions between microplastics and PPCPs: The environment and health implications
This review examines how microplastics interact with pharmaceuticals and personal care products (PPCPs), finding that the large hydrophobic surface area of microplastics enhances PPCP adsorption, increasing their persistence, bioavailability, and potential for biomagnification through food webs.
Aging microplastics enhances the adsorption of pharmaceuticals in freshwater
Researchers found that aging microplastics through photo-oxidation significantly increases their ability to adsorb pharmaceutical compounds from freshwater compared to virgin particles. Among the drugs tested, fluoxetine showed the highest adsorption, binding to all aged microplastic types at rates up to 99%. The study highlights that environmentally weathered microplastics may act as more effective carriers of pharmaceutical pollutants in freshwater ecosystems than previously assumed.
Adsorption of antibiotics on microplastics
This study examined the adsorption of antibiotics onto different microplastic types, finding that sorption capacity depended on both the antibiotic's chemical properties and the plastic's surface characteristics, with implications for antibiotic transport in aquatic environments.
Adsorption of a Mixture of Daily Use Pharmaceuticals on Pristine and Aged Polypropylene Microplastics
This study examined polypropylene microplastics as carriers for a mixture of daily-use pharmaceuticals including antibiotics, anti-inflammatories, and other compounds under simulated environmental conditions. Polypropylene microplastics adsorbed all tested pharmaceuticals, with adsorption capacity and kinetics varying by compound, confirming that environmental microplastics can act as vectors concentrating multiple pharmaceutical contaminants simultaneously.
Adsorption behaviour and interaction of organic micropollutants with nano and microplastics – A review
This review analyzed the adsorption behavior of organic micropollutants — including pharmaceuticals, pesticides, and industrial chemicals — onto nano- and microplastics, finding that adsorption is governed by pollutant hydrophobicity, particle surface area, and aging state, and that microplastics can act as vectors delivering co-contaminants to aquatic organisms.
Multi-mechanistic adsorption of pharmaceuticals and personal care products on oxidized microplastics: Oxidation processes, mechanisms, and environmental implications
Researchers reviewed how weathering and oxidation change microplastic surfaces, making them better at absorbing pharmaceuticals and personal care product chemicals from water. The modified surfaces attract these contaminants through multiple chemical forces, meaning aged microplastics in the environment act as enhanced carriers for drug and cosmetic pollutants.
An assessment of the concentration of pharmaceuticals adsorbed on microplastics
This study developed and validated an analytical method to measure pharmaceutical compounds adsorbed onto microplastic particles in marine water samples. Microplastics can concentrate pharmaceuticals from water and carry them through marine food chains, potentially delivering drug compounds to fish and other organisms at elevated concentrations.
Mechanisms of microplastics sorption of antibiotics and impacts on aquatic ecosystems for sustainable development goals
This review examines how microplastics serve as carriers for antibiotics in aquatic ecosystems through sorption mechanisms including hydrophobic interactions, electrostatic forces, and chemical bonding. The study found that environmental factors like pH, salinity, and organic matter affect how antibiotics bind to microplastics, while weathering processes can transform microplastics into nanoplastics that potentially increase pollutant mobility.
Microplastics physicochemical properties, specific adsorption modeling and their interaction with pharmaceuticals and other emerging contaminants
This review examines how microplastics interact with pharmaceutical residues in aquatic environments, covering adsorption mechanisms, degradation pathways, and combined toxicity effects. Researchers analyzed mathematical modeling approaches for predicting how microplastics and pharmaceuticals associate under different environmental conditions. The study highlights that microplastics can alter the environmental fate of pharmaceutical contaminants, creating combined pollution risks for ecosystems and public health.
Effects of nanoplastics and microplastics on the availability of pharmaceuticals and personal care products in aqueous environment
Researchers found that nanoplastics and microplastics can sorb pharmaceuticals and personal care products in water, with smaller nanoplastics showing 1-2 orders of magnitude stronger sorption than microplastics, potentially reducing the bioavailability of these contaminants in aquatic environments.