Herein we report the fabrication, optimization, and characterization of inkjet-printed thin film silicon anodes for lithium-ion batteries using commercial silicon nanoparticles. By comparing four different polymer binders, we demonstrate the critical role of binder on achieving good electrochemical performance of inkjet-printed silicon electrodes. Inkjet-printed silicon nanoparticle electrodes with conductive polymer PEDOT:PSS binder exhibit superior performance and durablity, with a capacity retention of over 1000 cycles at a depth-of-discharge of 1000mAhg−1. The working mechanism of the impact of the binders on inkjet-printed silicon electrodes is investigated and explained in detail via various characterization techniques, including scanning electron microscopy, Raman and infrared spectroscopy.