91˰涶

Dr Lorenzo Travaglini

Dr Lorenzo Travaglini

Postdoctoral Fellow
Science
School of Biotech & Biomolecular Science

Dr. Travaglini completed his B. Sc. in physics and M. Sc. in applied physics (cum Laude, 2016) at the University of Bologna (UNIBO). After his Ph.D. program at the School of Materials Science and Engineering at the University of New South Wales (UNSW) he started as postdoctoral researcher in the PRinT groupat UNSW. He is currently postdoc at the School of Biotechnology and Biomolecular Sciences at UNSW.

Location
301D, Biological Sciences North (D26)
  • Journal articles | 2024
    Fidanovski K; Gu M; Travaglini L; Lauto A; Mawad D, 2024, 'Self-Doping and Self-Acid-Doping of Conjugated Polymer Bioelectronics: The Case for Accuracy in Nomenclature', Advanced Healthcare Materials, 13,
    Journal articles | 2024
    Gu M; Travaglini L; Ta D; Hopkins J; Lauto A; Wagner P; Wagner K; Officer DL; Mawad D, 2024, 'A PEDOT based graft copolymer with enhanced electronic stability', Materials Horizons, 11, pp. 4809 - 4818,
    Journal articles | 2024
    Travaglini L; Lam NT; Sawicki A; Cha H; Xu D; Micolich AP; Clark DS; Glover DJ, 2024, 'Fabrication of Electronically Conductive Protein‐Heme Nanowires for Power Harvesting (Small 29/2024)', Small, 20,
    Journal articles | 2024
    Travaglini L; Lam NT; Sawicki A; Cha HJ; Xu D; Micolich AP; Clark DS; Glover DJ, 2024, 'Fabrication of Electronically Conductive Protein-Heme Nanowires for Power Harvesting', Small, 20,
    Journal articles | 2024
    Wu J; Gu M; Travaglini L; Lauto A; Ta D; Wagner P; Wagner K; Zeglio E; Savva A; Officer D; Mawad D, 2024, 'Organic Mixed Ionic-Electronic Conductors Based on Tunable and Functional Poly(3,4-ethylenedioxythiophene) Copolymers', ACS Applied Materials and Interfaces, 16, pp. 28969 - 28979,
    Journal articles | 2023
    Hopkins J; Fidanovski K; Travaglini L; Ta D; Hook J; Wagner P; Wagner K; Lauto A; Cazorla C; Officer D; Mawad D, 2023, 'Erratum: A Phosphonated Poly(ethylenedioxythiophene) Derivative with Low Oxidation Potential for Energy-Efficient Bioelectronic Devices (Chemistry of Materials (2022) 34:1 (140-151) DOI: 10.1021/acs.chemmater.1c02936)', Chemistry of Materials, 35, pp. 4882,
    Journal articles | 2023
    Lee WK; Bazargan G; Gunlycke D; Lam NT; Travaglini L; Glover DJ; Mulvaney SP, 2023, 'Protonic conductivity in metalloprotein nanowires', Journal of Materials Chemistry C, 11, pp. 3626 - 3633,
    Journal articles | 2022
    Gu M; Travaglini L; Hopkins J; Ta D; Lauto A; Wagner P; Wagner K; Zeglio E; Jephcott L; Officer DL; Mawad D, 2022, 'Molecular design of an electropolymerized copolymer with carboxylic and sulfonic acid functionalities', Synthetic Metals, 285,
    Journal articles | 2022
    Hopkins J; Fidanovski K; Travaglini L; Ta D; Hook J; Wagner P; Wagner K; Lauto A; Cazorla C; Officer D; Mawad D, 2022, 'A Phosphonated Poly(ethylenedioxythiophene) Derivative with Low Oxidation Potential for Energy-Efficient Bioelectronic Devices', Chemistry of Materials, 34, pp. 140 - 151,
    Journal articles | 2021
    Jephcott L; Eslami M; Travaglini L; Lauto A; Mawad D, 2021, 'A conjugated polymer-liposome complex: A contiguous water-stable, electronic, and optical interface', VIEW, 2,
    Journal articles | 2021
    Jephcott L; Eslami M; Travaglini L; Lauto A; Mawad D, 2021, 'Frontispiece: A conjugated polymer‐liposome complex: A contiguous water‐stable, electronic, and optical interface (View 1/2021)', VIEW, 2,
    Journal articles | 2021
    Travaglini L; Micolich AP; Cazorla C; Zeglio E; Lauto A; Mawad D, 2021, 'Single-Material OECT-Based Flexible Complementary Circuits Featuring Polyaniline in Both Conducting Channels', Advanced Functional Materials, 31,
    Journal articles | 2021
    Yan Y; Travaglini L; Lau K; Rnjak-Kovacina J; Ta D; Eslami M; Yang S; Lauto A; Officer DL; Mawad D, 2021, 'Impact of Sterilization on a Conjugated Polymer-Based Bioelectronic Patch', ACS Applied Polymer Materials, 3, pp. 2541 - 2552,
    Journal articles | 2019
    Hopkins J; Travaglini L; Lauto A; Cramer T; Fraboni B; Seidel J; Mawad D, 2019, 'Photoactive Organic Substrates for Cell Stimulation: Progress and Perspectives', Advanced Materials Technologies, 4,
    Journal articles | 2018
    Cui C; Faraji N; Lauto A; Travaglini L; Tonkin J; Mahns D; Humphrey E; Terracciano C; Gooding JJ; Seidel J; Mawad D, 2018, 'A flexible polyaniline-based bioelectronic patch', Biomaterials Science, 6, pp. 493 - 500,
    Journal articles | 2016
    Cramer T; Travaglini L; Lai S; Patruno L; De Miranda S; Bonfiglio A; Cosseddu P; Fraboni B, 2016, 'Direct imaging of defect formation in strained organic flexible electronics by Scanning Kelvin Probe Microscopy', Scientific Reports, 6,
  • Preprints | 2023
    Travaglini L; Lam NT; Sawicki A; Cha H-J; Xu D; Micolich AP; Clark DS; Glover DJ, 2023, Fabrication of electronically conductive protein-heme nanowires for power harvesting,
    Conference Papers | 2022
    Zeglio E; Herland A; Wang Y; Travaglini L; Patsaki V; Ireland J; Micolich A; Lauto A; Kilian C; Mawadd D; Yue W, 2022, 'Bio-functionalized organic electrochemical transistors for in vitro recording of electrogenic cells', in Proceedings of the Organic Bioelectronics Conference 2022, Fundació Scito, presented at Organic Bioelectronics Conference 2022, 08 February 2022 - 09 February 2022,
    Preprints | 2021
    Yan Y; Travaglini L; Lau K; Rnjak-Kovacina J; Eslami M; Yang S; Lauto A; Officer D; Mawad D, 2021, Impact of sterilization on a conjugated polymer based bioelectronic patch,
    Preprints | 2020
    Travaglini L; Micolich A; Cazorla C; Zeglio E; Lauto A; Mawad D, 2020, Flexible complementary logic circuit built from two identical organic electrochemical transistors, ,

- 2020 UNSWScience StudentEquity, Diversity, and Inclusion (EDI) awards

Lorenzo's research focuses on the development of a novel class of flexible electronic devices for future biomedical applications. His research focused on developing of flexible biocompatible devices based on organic materials that can be integrated directly into electroresponsive tissues and is capable of sense and process the bioelectric signal. He used a novel approach to build a complementary circuit using OECTs and he demonstrates that a single material complementary circuit can be built from two identical Polyaniline-based OECTs, eliminating the need for an n-type conjugated polymer. He transfers the technology on a chitosan substrate to build a flexible logic circuit with demonstrated functionality in aqueous electrolytes. He also tested the materialsbiocompatibility, mechanical stress response and other potential properties such as optical charge generation under visible light illumination.

His current research aim to embed engineered conductive proteins based nanowires in functional biomaterials and bioelectronics. The ability to design conductive proteins nanowires with tunable conductive properties enable e wide range of applications ranging from passive electrodes to active devices able to detect and elaborate the electronic signal.