The phenomenon of chirality induced spin selectivity (CISS) has triggered important exercise lately, though many points of it stay to be understood. For instance, most investigations are centered on spin polarizations collinear to the cost present, and therefore longitudinal magnetoconductance (MC) is usually studied in two-terminal transport experiments. Little or no is thought in regards to the transverse spin elements and transverse MC – their existence, in addition to any dependence of this element on chirality. Additional, measurement of the CISS impact through two-terminal MC experiments stays a controversial subject. Detection of this impact within the linear response regime is debated, with contradicting reviews within the literature. Lastly, potential affect of the well-known electrical magnetochiral impact on CISS stays unclear. To make clear these points, on this work we now have investigated the bias dependence of the CISS impact utilizing planar carbon nanotube networks functionalized with chiral molecules. We discover that (a) transverse MC exists and reveals tell-tale indicators of the CISS impact, (b) transverse CISS MC vanishes within the linear response regime establishing the validity of Onsager’s relation in two-terminal CISS techniques, and at last (c) CISS sign stays current even within the absence of electrical magneto chiral results, suggesting existence of an alternate bodily origin of CISS MC.