Abstract
The electric dipoles of proteins in a biolayer determine their dielectric properties through the polarization density P. Hence, its reproducibility is crucial for applications, particularly in bioelectronics. Biolayers encompassing capturing antibodies covalently bound at a biosensing interface are generally preferred for their assumed higher stability. However, surface physisorption is shown to offer advantages like easily scalable fabrication processes and high stability. The present study investigates the effects of electric-field (EF)-cycling of anti-Immunoglobulin M (anti-IgM) biolayers physisorbed on Au. The impact of EF-cycling on the dielectric, optical, and mechanical properties of anti-IgM biolayer is investigated. A reduction of the dispersion (standard deviation over a set of 31 samples) of the measured P values is observed, while the set median stays almost constant. Hence, physisorption combined with EF cycling, results in a biolayer with highly reproducible bioelectronic properties. Additionally, the study provides important insights into the mechanisms of dielectric rearrangement of dipole moments in capturing biolayers after EF-cycling. Notably, EF-cycling acts as an annealing process, driving the proteins in the biolayer into a statistically more probable and stable conformational state. Understanding these phenomena enhances the knowledge of the properties of physisorbed biolayers and can inform design strategies for bioelectronic devices.
| Original language | English |
|---|---|
| Journal | Advanced Science |
| DOIs | |
| Publication status | Published - 2024 |
| Externally published | Yes |
| MoE publication type | A1 Journal article-refereed |
Funding
C.D.F. and E.M. contributed equally to this work. Centro di Innovazione Regionale Digital Assay, Regione PUGLIA Delibera Regionale n 702 del 08/11/2022 CUP B93C22000840001; NoOne-A binary sensor with a single-molecule digit to discriminate biofluids enclosing zero or at least one biomarker, ERC Stg2021, GA:101040383; PRIN project prot.2017RHX2E4 ″At the forefront of Analytical ChemisTry: disrUptive detection technoLogies to improve; Italian network of excellence for advanced diagnosis (INNOVA), Ministero della Salutecode PNC-E3-2022-23683266 PNC-HLS-DA, CUP: C43C22001630001; Italian Complementary National Plan PNC-I.1 “Research initiatives for innovative technologies and pathways in the health and welfare sector” D.D. 931 of 06/06/2022, DARE – DigitAl lifelong pRevEntion initiative, code PNC0000002, CUP: B53C22006420001; Tecnologie portatili e protocolli innovativi per la diagnosi ultrasensibile di Xylella fastidiosa direttamente in piante e vettori (1LIVEXYLELLA) Ministero dell'agricoltura, della sovranità alimentare e delle foreste- MIPAAF D.M. n.419161 del 13/09/2022; Research actions for reducing the impact on agricultural and natural ecosystems of the harmful plant pathogen Xylella fastidiosa (REACH-XY) – CUP B93C22001920001. PNRR MUR project PE0000023-NQSTI- National Quantum Science and Technolgy Institute; POR Puglia 2014/2020- Asse X- Azione 10.4. Research for Innovation (REFIN). ID: E3C61580. “Nuove Metodologie Di Analisi Di Superfici Nano Strutturate E Funzionalizzate Per Innovazione Nell'industria Biomedicale”; MUR – Dipartimenti di Eccellenza 2023–2027 – Quantum Sensing and Modelling for One-Health (QuaSiModO) were acknowledged for partial financial support.
Keywords
- anti-IgM
- antibody-capturing-layers
- electric-field-cycling
- electrolyte-gated-organic field-effect-transistors(EGOFETs)
- Kelvin-Probe-Force-Microscopy (KPFM)
- protein-physisorption
- Single-Molecule-With-a-Large-Transistor(SiMoT)
- zeta-potentials