Daphnia as a model organism to probe biological responses to nanomaterials-from individual to population effects via adverse outcome pathways

Toxicological assessment of cigarette filter-derived microplastics in Daphnia magna

Cigarette filters are the most common form of litter worldwide and pose significant ecological risks because they degrade into microfibers and microplastics in aquatic environments. While previous studies have focused on the acute toxicity of cigarette leachate, the long-term ecological consequences of microplastic release from cigarette filters remain largely unexplored. This study evaluated the toxicity of cigarette filter-derived microplastics, including non-smoked cellulose acetate filters (CAF), smoked cigarette filters (GSF), on Daphnia magna, as well as leachate from smoked filter (LSF) for comparison. Imaging analysis confirmed that D. magna ingested cigarette filter-derived microplastics, which acted as carriers, gradually releasing harmful substances within organisms, a phenomenon consistent with the Trojan horse effect. Acute toxicity tests revealed similar 48-hour EC50 values (∼50 mg/L) for both GSF and LSF; however, GSF induced more pronounced long-term toxic effects. Chronic exposure to GSF significantly impairs reproduction, delays the timing of the first brood, reduces offspring size, and disrupts ecdysteroid-regulated genes. These findings indicate that cigarette filters are a persistent source of chemical pollution, threatening aquatic ecosystems. Specifically, microplastics from discarded cigarette filters act as Trojan horses, continuously releasing toxic chemicals and transporting hydrophobic contaminants, amplifying their environmental impact.

Lithium with environmentally relevant concentrations interferes with mitochondrial function, antioxidant response, and autophagy processes in Daphnia magna, leading to changes in life-history traits and behavior

With the increasing production and use of lithium-based products, concerns over lithium pollution in aquatic ecosystems are increasing, whereas research on its toxicity mechanisms in aquatic organisms remains limited. The main objective of the present study was to explore the effects of environmentally relevant concentrations of lithium exposure on the life-history strategy, behavior, antioxidant system, and autophagy process of Daphnia magna. Acute (24-96 h) and chronic (21 days) exposure experiments under three lithium treatments (low: 8.34 μg/L, medium: 83.44 μg/L, and high: 834.41 μg/L) were conducted. The results indicated that exposure to medium and high lithium concentrations led to eye and tail deformities in D. magna. Furthermore, developmental and reproductive parameters such as body length, total neonates per female, and average neonates per time were negatively influenced. Lithium also interfered with energy metabolism to cause the decreasing swimming speed and the reduction in the swimming range. In addition, lithium exposure affected the expression of gsk-3β, further disrupting the dynamic balance of mitochondrial fission, fusion, and regeneration, which caused ROS accumulation and induced oxidative stress. D. magna attenuated the stress by activating the FoxO/SESN and Nrf2/Keap1 pathways, synergistically enhancing downstream antioxidant enzymes expression. Concurrently, D. magna also mitigated oxidative stress and mitochondrial damage by promoting autophagy and inhibiting apoptosis. In summary, lithium harmed the physiological and biochemical functions of D. magna through multiple mechanisms, suggesting that environmental lithium pollution may pose a potential threat to aquatic organisms.

Acute toxicity of natural and synthetic clothing fibers towards Daphnia magna: Influence of fiber type and morphology

Environmental consequences of plastic pollution have come under scrutiny over the past 20 years as stewardship of the biosphere has risen in popularity. Microplastic research has focused on fragmented particles from hard plastics with limited research focused on microfibers released from textiles, which constitute a significant portion of microplastics in aquatic environments. The present study investigated hazards associated with two natural microfibers (cotton and silk) and four synthetic microfibers (acrylonitrile, Kevlar, nylon, and polyester) towards Daphnia magna. Results demonstrated that toxicity is dependent on the polymer type and morphology. Natural microfibers had no significant effects on D. magna whereas nylon microfibers were acutely toxic. While the total number of microfibers in exposure chambers contributed to microfiber ingestion and toxicity, suspended microfibers were weakly correlated to microfiber ingestion and toxicity. Microfibers with smoother surfaces were more toxic than microfibers that were frayed. Toxicity was more strongly related to microfiber ingestion than exposure concentration, suggesting that microfiber uptake is an important measurement endpoint for characterizing effects. Research with longer exposure times and emphasis on endpoints other than survival, such as uptake and retention of microfibers, feeding rates, growth and development, and reproduction are needed to understand the ecotoxicity of microfibers.

Facilitating microplastic ingestion in aquatic models: A verified protocol for daphnia magna as a trojan horse vector

Microplastic pollution poses a significant environmental threat due to its persistence, widespread distribution, and inherent toxic potential. Despite the increasing number of publications in this field, a standardized protocol for the laboratory intake of microplastics by Daphnia magna has yet to be established. In this study, we introduce a verified protocol designed to facilitate the ingestion of microplastic particles (MPs) by D. magna, ranging in size from 5-55 µm. This protocol can be further applied to evaluate the toxicity of MPs on D. magna, a crucial organism model in ecotoxicology. Furthermore, this protocol can be used to assess toxicity of MPs in other aquatic species, such as fish, by using daphnids as a vehicle for ensuring the ingestion of these particles. Consequently, this protocol can be applied to study also one of the most pressing concerns regarding exposure to MPs, the transfer of MPs through different trophic levels, which has a great potential for ecotoxicological studies.•The influence of MPs concentration, duration and exposure dynamics and D. magna age/size in MPs intake were tested.•We have determined the optimal conditions for promoting microplastic ingestion by D. magna.

NanoBioAccumulate: Modelling the uptake and bioaccumulation of nanomaterials in soil and aquatic invertebrates via the Enalos DIAGONAL Cloud Platform

NanoBioAccumulate is a free-to-use web-based tool hosted on the Enalos DIAGONAL Cloud Platform (https://www.enaloscloud.novamechanics.com/diagonal/pbpk/) that provides users with the capability to model and predict the uptake and bioaccumulation of nanomaterials (NMs) by soil and aquatic invertebrates using two common first-order one-compartment biokinetic models. NanoBioAccumulate offers an approach for comprehensively analyzing the kinetics of different forms of NMs via a nonlinear fitting feature, integrating them with environmental fate models, and considering important physiological processes. NanoBioAccumulate overcomes the constraint of requiring prior knowledge of kinetic rate constants associated with the biokinetic models and eliminates the need for external statistical analysis software as it quantifies the kinetic rate constants and other constants through the application of nonlinear regression, using user-provided experimental data. Furthermore, NanoBioAccumulate incorporates statistical analysis measures like the adjusted R-squared and the bias-corrected Akaike information criterion, allowing for assessment of the goodness-of-fit of the two different biokinetic models, assisting in the identification of the best-performing model for a specific nanoform and its uptake kinetics by a specific invertebrate. The tool also includes model scenarios, retrieved from literature, which involve examining the exposure of soil and aquatic invertebrates to various types of NMs such as TiO2, SiO2, C60, graphene, graphene oxide (GO), Au, Ag and its ionic control AgNO3. These model scenarios aim to enhance understanding of the uptake and elimination rates exhibited by different NM-species. NanoBioAccumulate features advanced integration capabilities, enabled by an extensive Application Programming Interface (API). This functionality promotes efficient data exchange and interoperability with other software and web applications, significantly expanding its utility in research, regulatory risk assessment and environmental surveillance and monitoring contexts. The inclusion of a user-friendly Graphical User Interface (GUI) in NanoBioAccumulate greatly improves the overall user experience by simplifying complex tasks and eliminating the need for programming proficiency, thereby expanding the tool's applicability to a diverse range of users across various fields such as environmental research, monitoring, and regulation.

Staining and resin embedding of whole Daphnia magna samples for micro-CT imaging enabling 3D visualization of cells, tissues, and organs

Micro-CT imaging is a powerful tool for generating high-resolution, isotropic, three-dimensional datasets of whole, centimeter-scale model organisms. At histological resolutions, micro-CT can be used for whole-animal qualitative and quantitative characterization of tissue and organismal structure in health and disease. The small size, global freshwater distribution, wide range of cell size and structures of micron scale, and common use of Daphnia magna in toxicological and environmental studies make it an ideal model for demonstrating the potential power of micro-CT-enabled whole-organism phenotyping. This protocol details the steps involved in D. magna samples preparation for micro-CT, including euthanasia, fixation, staining, and resin embedding. Micro-CT reconstructions of samples imaged using synchrotron micro-CT reveal histological (microanatomic) features of organ systems, tissues, and cells in the context of the entire organism at sub-micron resolution and in 3D. The enabled "3D histology" and 3D renderings can be used for morphometric analyses across cells, tissues, and organ systems.

Miniaturizing Nanotoxicity Assays in Daphnids

The rapid progress of the modern world has resulted in new materials and products created at an accelerating pace. As such, nanoparticles have widespread applications and often find their way into the aquatic ecosystem. In the case of freshwater ecosystems, one of the commonly used bioindicators species used for pollution assessment is Daphnid magna. The Organization for Economic Co-operation and Development (OECD), and other organizations such as the European Chemicals Agency (ECHA) and Environmental Protection Agency (EPA), have set guidelines for acute toxicity testing in daphnids that are severely lacking in terms of information on the characteristics of the exposure vessel when studying the adverse effects of nanoparticles (NPs). Understanding the toxicity mechanisms of nanomaterials is imperative given the scarcity of information on their adverse effects. Furthermore, miniaturization of nanotoxicity assays can reduce the number of daphnids used, as well as the cost and nanomaterial waste, and provide results even at the individual animal level with enhanced reproducibility of testing. In this study, the impact of the exposure vessel on the observed physiological changes of daphnids was investigated for a silver nano ink. Exposures in eleven commercially available vessels; nine made of plastic and two made of glass were compared for 24 h. The effect of surface to volume ratio of the exposure vessel and the animal number or "crowding" during exposure was investigated in the context of miniaturizing biomarker assays as alternatives to traditional experimental setups in Daphnid magna. Toxicity curves showed differences depending on the vessel used, while a novel feeding rate assay and the activity of key enzymes were assessed as physiology endpoints.

Effects of microplastics on key reproductive and biochemical endpoints of the freshwater microcrustacean Daphnia magna

Human activities have directly impacted the environment, causing significant ecological imbalances. From the different contaminants resulting from human activities, plastics are of major environmental concern. Due to their high use and consequent discharge, plastics tend to accumulate in aquatic environments. There, plastics can form smaller particles (microplastics, MPs), due to fragmentation and weathering, which are more prone to interact with aquatic organisms and cause deleterious effects, including at the basis of different food webs. This study assessed the effects of two microplastics (polyethylene terephthalate, PET; and polypropylene, PP; both of common domestic use) in the freshwater cladoceran species Daphnia magna. Toxic effects were assessed by measuring reproductive traits (first brood and total number of offspring), and activities of biomarkers involved in xenobiotic metabolism (phase I: cytochrome P-450 isoenzymes CYP1A1, 1A2 and 3A4; phase II/conjugation: glutathione S-transferases; and antioxidant defense (catalase)). Both MPs showed a potential to significantly reduce reproductive parameters in D. magna. Furthermore, PET caused a significant increase in some isoenzymes of CYP450 in acutely exposed organisms, but this effect was not observed in chronically exposed animals. Similarly, the activity of the antioxidant defense (CAT) was significantly increased in acutely exposed animals, but not in chronically exposed organisms. This pattern of effects suggests a possible mechanism of long-term adaptation to the presence of the tested MPs. In conclusion, the herein tested MPs have shown the potential to induce deleterious effects on D. magna mainly observed in terms of the reproductive outcomes. Changes at the biochemical level seems transient and are not likely to occur in long term, environmentally exposed crustaceans.

A free and user-friendly software protocol for the quantification of microfauna swimming behavior

Characterizing swimming behavior can provide a holistic assessment of the health, physiology and ecology of microfaunal species when done in conjunction with measuring other biological parameters. However, tracking and quantifying microfauna swimming behavior using existing automated tools is often difficult due to the animals' small size or transparency, or because of the high cost, expertise, or labor needed for the analysis. To address these issues, we created a cost-effective, user-friendly protocol for behavior analysis that employs the free software packages HitFilm and ToxTrac along with the R package 'trajr' and used the method to quantify the behavior of rotifers. This protocol can be used for other microfaunal species for which investigators may face similar issues in obtaining measurements of swimming behavior.

Eco-corona-mediated transformation of nano-sized Y2O3 in simulated freshwater: A short-term study

The use of metal and metal oxide nanomaterials (NMs) is experiencing a significant surge in popularity due to their distinctive structures and properties, making them highly attractive for a wide range of applications. This increases the risks of their potential negative impact on organisms if dispersed into the environment. Information about their behavior and transformation upon environmental interactions in aquatic settings is limited. In this study, the influence of naturally excreted biomolecules from the zooplankton Daphnia magna on nanosized Y2O3 of different concentrations was systematically examined in synthetic freshwater in terms of adsorption and eco-corona formation, colloidal stability, transformation, dissolution, and ecotoxicity towards D. magna. The formation of an eco-corona on the surface of the Y2O3 NMs leads to improved colloidal stability and a reduced extent of dissolution. Exposure to the Y2O3 NMs lowered the survival probability of D. magna considerably. The ecotoxic potency was slightly reduced by the formation of the eco-corona, though shown to be particle concentration-specific. Overall, the results highlight the importance of systematic mechanistic and fundamental studies of factors that can affect the environmental fate and ecotoxic potency of NMs.

Daphnia's phototaxis as an indicator in ecotoxicological studies: A review

Animal-based sensors have been increasingly applied to many water monitoring systems and ecological studies. One of the staple organisms used as living sensors for such systems is Daphnia. This organism has been extensively studied and, with time, used in many toxicological and pharmaceutical bioassays, often used for exploring the ecology of freshwater communities. One of its behaviours used for evaluating the state of the aquatic environment is phototaxis. A disruption in the predicted behaviour is interpreted as a sign of stress and forms the basis for further investigation. However, phototaxis is a result of complex processes counteracting and interacting with each other. Predator presence, food quality, body pigmentation and other factors can greatly affect the predicted phototactic response, hampering its reliability as a bioindicator. Therefore, a holistic approach and meticulous documentation of the methods are needed for the correct interpretation of this behavioural indicator. In this review, we present the current methods used for studying phototaxis, the factors affecting it and proposed ways to optimise the reliability of the results.