8:45am - 9:15amInvitedID: 473
/ TOM4 S6: 1
TOM 4 BioPhotonics and Biosensors
Invited - Graphene Energy Transfer (GET) and DNA Nanotechnology for single-molecule biosensing and biophysics
Izabela Kamińska1,2, Alan Szalai1, Giovanni Ferrari1, Lars Richter1, Karolina Zielonka2, Chenyuan Yan1, Merve-Zeynep Kesici1, Bosong Ji1, Jakob Hartmann1, Ewa Czechowska2, Andrés M. Vera Gómez1, Philip Tinnefeld1
1Ludwig Maximilians-Universität München, Germany; 2Institute of Physical Chemistry of the Polish Academy of Sciences, Poland
Graphene constitutes a broadband energy acceptor, avoiding labeling, photobleaching and complicated photophysics. Graphene quenches fluorescence of fluorophores in a range of 0-40 nm, following a d-4 distance dependence. Due to Graphane Energy Transfer (GET) a single dye molecule shows a reduced fluorescence intensity and a shortened fluorescence lifetime as a function of its distance to graphene. This information can be used to determine the position of the dye molecule to graphene and to sensitively report on distance changes in real-time. In our first realization, we used DNA origami nanopositioners to place a fluorophore and other molecular components at a defined distance from graphene. With this approach, using single-molecule fluorescence microscopy techniques and several different assays we demonstrated among others: switching dynamics of a DNA pointer between two binding sites with high time resolution, dynamics of a flexible DNA tether influenced by viscosity or target binding, 3D superresolution imaging with isotropic nanoscale resolution, a biosensing assay with single DNA molecule detection in a novel unquenching assay format. Our recently developed tools to connect DNA and graphene enable single base-pair resolution. We use this approach to visualize structural properties of DNA which precede direct interactions with biomolecules and DNA-protein interactions.
9:15am - 9:30amID: 431
/ TOM4 S6: 2
TOM 4 BioPhotonics and Biosensors
Molecular beacon as molecular switch for miRNA/mRNA detection in novel SERS-based biosensors
Ambra Giannetti1, Martina Banchelli1, Sara Tombelli1, Marella de Angelis1, Cristiano D'Andrea1, Simone Berneschi1, Gualtiero Nunzi Conti1, Cosimo Trono1, Stefano Pelli1, Francesco Baldini1, Daniele Farnesi1, Davide Janner2, Nadia G. Boetti3, Paolo Matteini1
1CNR-IFAC, Italy; 2Politecnico di Torino, Italy; 3Fondazione LINKS, Italy
Molecular beacons (MBs) represent a powered tool for the detection of RNAs, such as micro-RNA (miRNA) and messenger RNA (mRNA), which play an important role as indicators of the progress of different pathologies in the human body, from the chronic ones to cancer. Two examples are provided here of how the combination of molecular beacons with detection platforms based on surface enhanced Raman scattering (SERS) can lead to the realization of more performing and reliable biosensors. The first case concerns the use of a MB, engineered for specific detection of a miRNA associated with chronic obstructive pulmonary disease. Silver nanowires were used as SERS substrate on which the MBs are immobilized. A femtomolar detection limit has been reached. The second approach is based on soda-lime glass microrods on which silver nanoparticles were grown using the ion-exchange technique followed by an appropriate thermal annealing post-process. Production parameters were optimized aiming at exposing the embedded silver nanoparticles on the surface of the microrods. By functionalizing these nanoparticles with a MB specific for the mRNA for survivin, the microrods were successfully tested for SERS and fluorescence effects, allowing the detection of the complementary sequence.
9:30am - 9:45amID: 406
/ TOM4 S6: 3
TOM 4 BioPhotonics and Biosensors
Porous Silicon modified by Molecularly Imprinted Polymers for Interleukin-6 (IL-6) detection
Luca De Stefano1, Valeria Nocerino1, Giulia Siciliano2, Ilaria Rea1, Principia Dardano1, Elisabetta Primiceri2
1ISASI-CNR, Italy; 2Nanotec-CNR, Italy
In this study, we present an innovative optical biosensor designed for the precise detection of
Interleukin-6 (IL-6), a crucial cytokine associated with various pathological conditions. Our biosensor is
based on silicon porous material meticulously modified with a molecularly imprinted polymer (MIP),
ensuring specific and sensitive recognition of IL-6 molecules. Fabrication process involves the
electrochemical etching of silicon porous chips followed by the electrodeposition of MIP, tailored to
selectively bind IL-6 targets. Through rigorous testing across a range of IL-6 concentrations, our sensor
exhibits remarkable sensitivity, showcasing discernible optical responses proportional to the varying analyte
concentrations. Furthermore, we assessed the sensor's performance using bovine serum, a complex biological
matrix, to simulate real-world sample conditions. Encouragingly, the sensor maintains its selectivity and
optical response in the presence of serum components, affirming its robustness and applicability in practical
diagnostic settings.
9:45am - 10:00amID: 371
/ TOM4 S6: 4
TOM 4 BioPhotonics and Biosensors
Highly sensitive detection of a neurodegenerative protein biomarker by using the pyro-electrohydrodynamic jet
Simonetta Grilli1, Concetta Di Natale2,1, Sara Coppola1,2, Veronica Vespini1, Volodymyr Tkachenko1, Simone Russo2, Stefania Carbone2,1, Giuseppina Luciani2, Giuseppe Vitiello2,3, Francesca Ferranti4, Silvia Mari4, Pietro Ferraro1, Pier Luca Maffettone2
1CNR-ISASI, Pozzuoli, Italy; 2Dipartimento di Ingegneria Chimica, Dei Materiali e Della Produzione Industriale (DICMaPI), Università Degli Studi di Napoli Federico II, Naples, Italy; 3Center for Colloid and Surface Science (CSGI), Sesto Fiorentino, Italy; 4Agenzia Spaziale Italiana, Rome, Italy
A set of protein biomarkers are largely recognized as responsible of neurodegeneration mechanisms and hence as potential targets to be detected in low abundant concentrations in body fluids for performing early diagnosis. As an example, the Tau protein experiences a transition phase from a native disorder conformation into a preaggregation state, which leads to fibrillization processes. Here we show the possibility to detect Tau in urine samples at sub-picogram level, through the concentration effect of the pyro-electrohydrodynamic (p-jet) technique. An immunofluorescence protocol is applied to concentrated p-jet spots able to reduce drastically the diffusion effects in the antibody-antigen reaction. A set of diluted samples were prepared, and the fluorescence signal was detected by a confocal scanner. We achieved an excellent linear response with a significant signal-to-noise ratio down to 0.25 pg/mL. In perspective, the technique could be integrated into a compact device to be used for monitoring the early stage associated to neurodegenerative syndromes in different scenarios such as for example in long-term human space exploration missions.
10:00am - 10:15amID: 352
/ TOM4 S6: 5
TOM 4 BioPhotonics and Biosensors
Polarization-resolved surface-enhanced sensing of single-stranded DNA with Bloch surface waves
Erika Mogni1, Giovanni Pellegrini2, Jorge Gil-Rostra3, Francisco Yubero3, Michele Celebrano1, Marco Finazzi1, Katharina Schmidt4, Stefan Fossati5, Paolo Biagioni1, Jakub Dostálek4,5
1Politecnico di Milano, Italy; 2Università degli studi di Pavia, Italy; 3CSIC-Universidad de Sevilla, Spain; 4Danube Private University, Austria; 5Czech Academy of Sciences, Czech Republic
We describe a novel one-dimensional photonic crystal design allowing for the concurrent excitation of transverse-electric and transverse-magnetic Bloch surface waves, thus paving the way for polarization-resolved sensing experiments. We discuss its application for the surface-enhanced sensing of oriented DNA molecules through nanoscale birefringence measurements.
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