Atomic force microscopy (AFM) is a consolidated technique for the study of biological systems, usually ex vivo or in culture, under different experimental conditions. Yet, the diffusion of the technique in the scientific context of histology is still rather slow and limited. In the present work, we demonstrate the potential of AFM, in terms of morphological and nanomechanical imaging, to study the effects of nano- and micro-sized metallic pollutants in living biological systems. As a model, we investigated marine molluscs (Mytilus galloprovincialis) grown in the Adriatic Sea. We characterized histological sections from two organs (gonads and digestive glands) of molluscs collected during several surveys at different growth time and distance from gas extraction platforms. We evaluated the effects of nano-pollutants mostly on the local tissue structure by combining AFM microscopy with scanning electron microscopy (SEM). Furthermore, the AFM images allowed evidencing the presence of nano- or micro-sized structures that exhibit different nanomechanical properties compared to the rest of the tissue. The results demonstrate how coupling AFM and SEM analysis can provide an effective procedure to evaluate the morphological alterations produced by the exposure to exogenous nano-pollutants in tissue and constitute a promising way to reveal basic mechanisms mediating the cytotoxicity of specific exogenous pollutants ingested by edible organisms.

Dinarelli, S., Longo, G., Cannata, S., Bernardini, S., Gomiero, A., Fabi, G., et al. (2020). Metal-based micro and nanosized pollutant in marine organisms: what can we learn from a combined atomic force microscopy-scanning electron microscopy study. JOURNAL OF MOLECULAR RECOGNITION, 33(12) [10.1002/jmr.2851].

Metal-based micro and nanosized pollutant in marine organisms: what can we learn from a combined atomic force microscopy-scanning electron microscopy study

Cannata, Stefano;Bernardini, Sergio;
2020-01-01

Abstract

Atomic force microscopy (AFM) is a consolidated technique for the study of biological systems, usually ex vivo or in culture, under different experimental conditions. Yet, the diffusion of the technique in the scientific context of histology is still rather slow and limited. In the present work, we demonstrate the potential of AFM, in terms of morphological and nanomechanical imaging, to study the effects of nano- and micro-sized metallic pollutants in living biological systems. As a model, we investigated marine molluscs (Mytilus galloprovincialis) grown in the Adriatic Sea. We characterized histological sections from two organs (gonads and digestive glands) of molluscs collected during several surveys at different growth time and distance from gas extraction platforms. We evaluated the effects of nano-pollutants mostly on the local tissue structure by combining AFM microscopy with scanning electron microscopy (SEM). Furthermore, the AFM images allowed evidencing the presence of nano- or micro-sized structures that exhibit different nanomechanical properties compared to the rest of the tissue. The results demonstrate how coupling AFM and SEM analysis can provide an effective procedure to evaluate the morphological alterations produced by the exposure to exogenous nano-pollutants in tissue and constitute a promising way to reveal basic mechanisms mediating the cytotoxicity of specific exogenous pollutants ingested by edible organisms.
2020
Pubblicato
Rilevanza internazionale
Articolo
Esperti anonimi
Settore BIO/06 - ANATOMIA COMPARATA E CITOLOGIA
English
AFM; SEM; metal nanoparticles; molluscs; mussels; nanosized pollutants
Dinarelli, S., Longo, G., Cannata, S., Bernardini, S., Gomiero, A., Fabi, G., et al. (2020). Metal-based micro and nanosized pollutant in marine organisms: what can we learn from a combined atomic force microscopy-scanning electron microscopy study. JOURNAL OF MOLECULAR RECOGNITION, 33(12) [10.1002/jmr.2851].
Dinarelli, S; Longo, G; Cannata, S; Bernardini, S; Gomiero, A; Fabi, G; Marco Girasole, N
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2108/244137
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