Your search keyword '"Mannelli I"' showing total 3 results

1. Protein nanopatterns for improved immunodetection sensitivity

Author

Valsesia, A., Mannelli, I., Colpo, P., Bretagnol, F., and Rossi, F.

Subjects

Nanotechnology -- Research, Biosensors -- Research, Proteins -- Properties, Chemistry

Abstract

In this work, we clearly demonstrate the capability of protein nanopatterns of improving the quality factors of immunosensing devices, such as lowering of the limit of detection and increase of sensitivity. This beneficial effect is obtained by the formation on the sensor's surface of bioadhesive domains of nanometric dimensions in a nonadhesive matrix by means of colloidal lithography.

Published

2008

2. Use of nanopatterned surfaces to enhance immunoreaction efficiency

Author

Valsesia, A., Colpo, P., Mannelli, I., Mornet, S., Bretagnol, F., Ceccone, G., and Rossi, F.

Subjects

Nanotechnology -- Research, Antigen-antibody reactions -- Research, Immune response -- Research, Chemistry

Abstract

In this work, we compare the immunoreaction efficiency between uniformly functionalized surface and chemically nanopatterned surfaces when applied as platforms for antigen/antibody interactions with and without the use of protein A as orienting protein. On the nanopatterned platform, the immunoreaction efficiency is higher than all the other cases with no protein A pretreatment of the surface, providing evidence of the capability of the adhesive/antiadhesive nanopatterned surface to immobilize the molecules in a reactive state, increasing their possibility to form complexes.

Published

2008

3. Direct and Fast Assessment of Antimicrobial Surface Activity Using Molecular Dynamics Simulation and Time-Lapse Imaging.

Author

Sibilo R, Mannelli I, Reigada R, Manzo C, Noyan MA, Mazumder P, and Pruneri V

Subjects

Anti-Bacterial Agents pharmacology, Escherichia coli drug effects, Escherichia coli isolation & purification, Microbial Sensitivity Tests, Microscopy, Fluorescence, Surface Properties, Anti-Bacterial Agents analysis, Molecular Dynamics Simulation, Time-Lapse Imaging

Abstract

With the alarming rise of antimicrobial resistance, studies on bacteria-surface interactions are both relevant and timely. Scanning electron microscopy and colony forming unit counting are commonly used techniques but require sophisticated sample preparation and long incubation time. Here, we present a direct method based on molecular dynamics simulation of nanostructured surfaces providing in silico predictions, complemented with time-lapse fluorescence imaging to study live interactions of bacteria at the membrane-substrate level. We evaluate its effectiveness in predicting and statistically analyzing the temporal evolution and spatial distribution of prototypical bacteria with costained nucleoids and membranes ( E. coli ) on surfaces with nanopillars. We observed cell reorientation, clustering, membrane damage, growth inhibition, and in the extreme case of hydrocarbon-coated nanopillars, this was followed by cell disappearance, validating the obtained simulation results. Contrary to commonly used experimental methods, microscopy data are fast processed, in less than 1 h. In particular, the bactericidal effects can be straightforwardly detected and correlated with surface morphology and/or wettability.

Published

2020