A Novel Antibacterial Membrane Electrode Based on Bacterial Cellulose/Polyaniline/AgNO₃ Composite for Bio-Potential Signal Monitoring

Abstract: We propose a flexible, dry, and antibacterial electrode with a low and stable skin electrode contact impedance for bio-potential signal monitoring. We fabricated a bacterial cellulose/polyaniline/AgNO3 nanocomposite membrane (BC/PANI/AgNO3) and used it for bio-potential signal monitoring. The bacterial cellulose (BC) provides a 3-D nanoporous network structure, and it was used as a substrate material in the BC/PANI/AgNO3 nanocomposite membrane. Polyaniline (PANI) and AgNO3, acting as conductive and antibacteri… Show more

“…Thanks to the proper combination of electrochemical, electromechanical, electrical, and biocompatibility properties, CPs have been already proposed as bioelectrode materials to detect and record electrical signals from biosystems. − However, to the best of our knowledge 3D printed PEGDA-PANI composites have not been tested for biopotential monitoring applications yet. Therefore they can be considered an added value for this research since PEGDA shows a very high compatibility with the most common commercial MSLA printers while PANI has been extensively considered a valid candidate for realizing biosignal sensing systems, also for detecting electrical activity directly on skin. − …”

Three-Dimensional-Printed Polyethylene Glycol Diacrylate-Polyaniline Composites by In Situ Aniline Photopolymerization: An Innovative Biomaterial for Electrocardiogram Monitoring Systems

“…Thanks to the proper combination of electrochemical, electromechanical, electrical, and biocompatibility properties, CPs have been already proposed as bioelectrode materials to detect and record electrical signals from biosystems. − However, to the best of our knowledge 3D printed PEGDA-PANI composites have not been tested for biopotential monitoring applications yet. Therefore they can be considered an added value for this research since PEGDA shows a very high compatibility with the most common commercial MSLA printers while PANI has been extensively considered a valid candidate for realizing biosignal sensing systems, also for detecting electrical activity directly on skin. − …”

Three-Dimensional-Printed Polyethylene Glycol Diacrylate-Polyaniline Composites by In Situ Aniline Photopolymerization: An Innovative Biomaterial for Electrocardiogram Monitoring Systems

“…Hence, the impedance of biosurface electrodes is the main source of noise, hindering the recorded signals toward better SNR. The conventional approach usually involves minimizing the contact resistance via ionic electrodes 117,156–158 —to maintain moisture and ion permeability on biosurface–electrode interfaces. However, the improvements in the SNR from such wet electrodes are not sufficient owing to the limited ionic concentrations and their naturally poor conductivity.…”

Challenges and emerging opportunities in transistor-based ultrathin electronics: design and fabrication for healthcare applications

“…15 The conductive fabrics are often fabricated by coating a thin layer of highly conductive materials like silver over non conducting polymeric fabric materials. [16][17][18] These materials are susceptible to erosion caused by the corrosive reaction of gas, vapours and liquids they are exposed to. Since the conductive surface is in close contact with the body surface, the effect of perspiration on the structural stability of the conductive layer has to be thoroughly studied because it can directly affect the conductivity of the electrode and the quality of the acquired signal.…”

Development of fabric electrode for bio-potential signal acquisition in wearable health monitoring and effect of perspiration on signal acquisition