The thesis consists of two parts; the first part their application in PTT1-B1 dispersant prepared to form highly conductive copper power and nanohybrid films by chemical methods. The second part is the immobilization of silver nanoparticles in POEM dispersant prepared to form highly conductive nanohybrid films for wearable electronic devices. A family of home-made polymeric dispersant synthesized by different molar ratio. Besides, the products contain structure features including ester linking and molecular structure in branched shape. The structures of the polymeric dispersant were characterized by using acid value (AV), Fourier-Transformed Infrared Spectrometry (FT-IR) and gel permeation chromatography (GPC). High electrical conductivity copper power and films prepared with a PTT1-B1 dispersant. Also they were prepared on a 1-µm-thick film with a low sheet resistance of 6.92×10-2 Ω/sq, achieved through the surface migration of silver nanoparticles and prepared by sintering at 300◦C with NaBH4 as a reductant to form an interconnected network. Eventually, transmission electron microscopy shows that the production of silver nanoparticles and copper nanoparticles were synthesized by the in situ chemical reduction. Our POEM dispersant approach results high electrical conductivity after they were easily prepared from organic/inorganic nanohybrid solutions containing an organic polymeric dispersant and exfoliated clay which shows the performance to silver nanoparticles (AgNPs) etched on Clay substrates. During sintering, the color of the hybrid film changed from gold to milky white, suggesting the migration of silver nanoparticles and the formation of an interconnected network. The results show promise for the fabrication of novel silver-based electrocardiogram electrodes and a flexible wireless electrocardiogram measurement system for wearable electronics. Thin films of silver nanoparticles were prepared on a 1-µm-thick film with a low sheet resistance of 8.24×10−4 Ω/sq.