studied Materials Science and Engineering and received her PhD in 2023 from the School of Molecular Science and Engineering, Vidyasirimedhi Institute of Science and Technology (VISTEC) in Rayong, Thailand under supervision of Assoc. Prof. Daniel Crespy working on the generation of fibrous membranes and modification thereof. In 2021, she joined Empa (Swiss Federal laboratories for Materials Research and Technology), Switzerland, as visiting PhD. Her research focuses on the functionalization of electrospun fiber membranes with catalysts or diverse payloads, or with on-demand membrane healing properties for air or water purification, agricultural applications, and biomedical applications.

conducted his doctoral research on 3D-printable biodegradable polymers at the University of Warwick, UK. After receiving his PhD in 2019, he joined Empa St.Gallen, Switzerland, under supervision of Prof. Dr. René M. Rossi, where he leads industrial research projects and feasability studies on functional textiles in biomedical, filtration, agricultural, acoustic and general domestic applications. His research focus lies on controlled release incorporating or stimuli responsive nanofiber membranes produced by pilot-scale needleless electrospinning, using innovative combinations of biocompatible materials, sustainable solvents and functional additives, as well as scalable post-processing and characterization strategies.

studied Microbiology and Biotechnology and obtained her PhD at ETH Zurich, Switzerland. She is a sensor scientist and group leader at Empa, with research focus on studying the interactions of bacteria and materials, and investigating antimicrobial resistance of biofilms. Dr. Ren has been working intensively together with academic, clinical and industrial partners to develop antimicrobial materials and solutions, including biosensors for rapid detection of bacterial pathogens. She is particularly interested in understanding the underlying mechanism of the interactions between bacteria and materials surfaces, aiming at improved monitoring and treatment of infections.

studied Applied Physics at the University of Neuchâtel, Switzerland, and obtained his PhD at ETH Zurich. Since 2003, he has been leading the Laboratory for Biomimetic Membranes and Textiles at Empa, a group of around 40 researchers developing novel smart fibers, textiles and membranes for body monitoring, drug delivery and tissue engineering applications. A special focus is to develop physical and numerical skin/body models for the analysis of the interactions between materials and the human skin to optimize the protection and ergonomics of systems. René Rossi is adjunct professor at the Department of Health Sciences and Technology at ETH Zurich and invited professor at the University of Haute-Alsace in Mulhouse/France.

studied chemistry at the University of Strasbourg and completed his PhD under the supervision of Prof. Katharina Landfester at the University of Ulm (Germany). In 2006, he became a project leader at Empa (Swiss Federal laboratories for Materials Research and Technology) under the supervision of Prof. Dr. René Rossi. He joined the department of Prof. K. Landfester at the Max Planck Institute for Polymer Research (Mainz, Germany) in July 2009 as group leader. Daniel Crespy is now associate professor at the Vidyasirimedhi Institute of Science and Technology (VISTEC) in Rayong, Thailand. His current work is focused on responsive polymer materials for biomedicine, self-healing, and anticorrosion applications.

studied Nanoscience at the University of Basel, Switzerland, and obtained his PhD in 2015. From 2016–2018, he did a postdoctoral stay at the interdisciplinary nanoscience institute (iNANO) at the University of Aarhus, Denmark, and then joined Empa St.Gallen, Switzerland, in 2019 with a Marie Skłodowska-Curie Cofund scholarship under supervision of Prof. Dr. René Rossi. As scientist, he is leading industrial projects employing electrohydrodynamic methods to encapsulate senstive molecules for drug delivery and sensory applications. His research interests include the generation of functional hybrid hydrogel/electrospun fiber scaffolds for applications in tissue engineering, materials with controlled release properties and development of sensors for the detection of bacteria.