Development of Conductive Gels for Biomedical Applications
Zusammenfassung
Conductive gels are essential in biomedical applications,
particularly in electroencephalography (EEG), but they often
cause skin irritations and evaluation interruptions as they dry
out. This research explores the formulation of conductive
gels using Hydroxyethyl Cellulose (HEC), a polymer derived
from natural plant cell walls. This natural polymer aids in
developing a less irritating alternative with comparable
efficiency to commercially available electrode gels like
Signagel®. The gels were formulated using varying
Hydroxyethyl Cellulose (HEC) concentrations, sodium
chloride as an ionic solute, propylene glycol as a humectant,
and water as a solvent. Key parameters such as viscosity,
pH, and conductivity were measured. The results indicate
that HEC-based gels, particularly the 2.5% HEC formulation,
exhibit properties matching those of Signagel®, with a pH of
6.42, viscosity of 11,530 cP, and conductivity of 120.3 mS.
This study demonstrates that HEC is a viable option for
creating conductive gels that minimize skin irritation and
maintain the physiochemical properties required for EEG
tests.