Heavy metals are persistent environmental pollutants with well-documented toxic, genotoxic, and bioaccumulative effects across ecosystems. This study evaluates blood cell morphology as a potential biomarker of environmental pollution in Miniopterus schreibersii (Kuhl, 1819), a migratory bat species. Individuals were captured from a contaminated site (Dardagani underground quarry) and a reference site (Mokra Megara Cave) in Bosnia and Herzegovina. Environmental sampling included guano, soil, and water. Guano was analyzed for nine heavy metals (Cr, Cu, Mn, Fe, Co, Ni, Cd, Pb, Zn) to assess site-specific contamination. Distinct spatial differences in metal accumulation were observed. Elevated Cu and Mn concentrations in guano from the contaminated site indicated anthropogenic input, whereas higher Fe, Ni, and Pb at the reference site reflected natural lithogenic enrichment. Hematological and cytological examinations revealed morphological alterations in blood cells of bats from the contaminated site, including neutrophil hypersegmentation, polychromatophilia, atypical granulation, and nuclear abnormalities in lymphocytes. The total lymphocyte count differed significantly, and these qualitative changes suggest early physiological adjustments or potential indicators of sublethal toxic exposure. By integrating environmental (soil and guano) and biological (blood morphology) parameters, this study demonstrates a non-lethal and ecologically relevant approach to biomonitoring. Blood cell alterations, combined with metal analyses in guano, provide a sensitive tool for detecting potential chronic environmental stress. M. schreibersii is reaffirmed as a valuable sentinel species for ecological monitoring in karst and other vulnerable habitats; however, the limited number of high-quality blood smears obtainable under field conditions still remains a constraint to broader generalization of the findings.

ABSTRACT This study demonstrates the usage of primarily discarded waste – pomegranate peel as secondary raw material – biosorbent for broader applications. The focus was on the optimisation of key cationic dye methylene blue (MB) – pomegranate peel (PP) adsorption process parameters, as well as cost analysis assessing the possibility of scaling up. The optimal values of the key parameters were pH 6, biosorbent mass 100 mg, contact time of 50 min, and initial analyte concentration 100 mg/L for MB removal from aqueous solutions providing high removal efficiency values > 88%. Fourier-transform infrared spectroscopy (FTIR) showed that MB adsorption on PP was presumably via hydrogen bonds with the OH groups present in PP. Changes noted via elemental composition analysis given by electron dispersive spectroscopy (EDS) confirmed the sorption of MB. Biosorption occurred mainly as a pseudo-second-order kinetic reaction combined with phase III of the intraparticle diffusion model (both R2 ≥ 0.92). Through a simple and fast batch MB sorption process with many advantages compared to literature data, a maximum sorption capacity of 384.61 mg/g could be achieved. Pomegranate peel was identified as a low-cost adsorbent with excellent potential for MB removal, economically viable (0.74 $/mol), demonstrating great possibilities for industrial application. Highlights Biosorption of phenothiazine dye on novel waste material from pomegranate peel in its native form. A univariate general procedure was performed, FTIR, SEM, and EDS characterisation of biosorbents. An optimal pH value was determined to be 6, while the optimal mass was 100 mg. A maximum biosorption capacity of 384.61 mg/g could be achieved. The mechanism of adsorption is best obeyed by the Langmuir and Freundlich models. The total analysis expenses for the entire procedure were just 0.74 $/mol. GRAPHICAL ABSTRACT

The environmental fragmentation of plastics generates a mixture of plastic particles of various sizes, which frequently co-occur with other mobile and persistent environmental pollutants. Despite the prevalence of such scenarios, the interaction between micro- and nanoplastics (MNPs) and their combined effects with environmental pollutants, such as highly toxic hexavalent chromium (Cr(VI)), remain almost entirely unexplored in mammalian species. This study demonstrated that nanoplastic and microplastic particles co-aggregate and together influence Cr bioaccumulation patterns and related physiological alterations in rats. Following a four-week repeated intragastric exposure of Wistar rats to MNPs and Cr(VI), either alone or in combination, MNPs significantly enhanced Cr bioaccumulation in the liver, heart, brain, and skin. Under co-exposure conditions, Cr(VI) was the primary driver of cellular effects observed in the blood, including shifts in immune cell subpopulations (e.g., neutrophils, lymphocytes) and alterations in red blood cell indices, while serum biochemistry reflected limited physiological stress. MNPs per se decreased creatine kinase activity and increased cholesterol levels. In summary, polystyrene MNPs increase Cr(VI) distribution and bioavailability, but co-exposure does not uniformly exacerbate toxicity. Instead, their interaction may selectively alter physiological responses, emphasizing the need for a deeper understanding of their combined effects and potential health risks.

The presence of microplastics (MPs) is increasing at a dramatic rate globally, posing risks for exposure and subsequent potential adverse effects on human health. Apart from being physical objects, MP particles contain thousands of plastic-associated chemicals (i.e., monomers, chemical additives, and non-intentionally added substances) captured within the polymer matrix. These chemicals are often migrating from MPs and can be found in various environmental matrices and human food chains; increasing the risks for exposure and health effects. In addition to the physical and chemical attributes of MPs, plastic surfaces effectively bind exogenous chemicals, including environmental pollutants (e.g., heavy metals, persistent organic pollutants). Therefore, MPs can act as vectors of environmental pollution across air, drinking water, and food, further amplifying health risks posed by MP exposure. Critically, fragmentation of plastics in the environment increases the risk for interactions with cells, increases the presence of available surfaces to leach plastic-associated chemicals, and adsorb and transfer environmental pollutants. Hence, this review proposes the so-called triple exposure nexus approach to comprehensively map existing knowledge on interconnected health effects of MP particles, plastic-associated chemicals, and environmental pollutants. Based on the available data, there is a large knowledge gap in regard to the interactions and cumulative health effects of the triple exposure nexus. Each component of the triple nexus is known to induce genotoxicity, inflammation, and endocrine disruption, but knowledge about long-term and inter-individual health effects is lacking. Furthermore, MPs are not readily excreted from organisms after ingestion and they have been found accumulated in human blood, cardiac tissue, placenta, etc. Even though the number of studies on MPs-associated health impacts is increasing rapidly, this review underscores that there is a pressing necessity to achieve an integrated assessment of MPs' effects on human health in order to address existing and future knowledge gaps.