There are several studies on electrical coupling between colloidal PbSe nanocrystals. The ability to tune electrical properties of devices has received large attention. Here we present a study of the electrical coupling between quasi one-dimensional Pb1-xMnxSe nanoarrays. These nanoarrays are 80 nm in width and 500 nm-1 μm in length. We use standard electron-beam lithography to fabricate two Ti/Au electrodes with a gap of 250-350 nm. The ac electric fields, inducing movement of polarizable nanoarrays, are applied to deposit the nanoarrays into the nanoscale gap. We have prepared devices with various different parallel 1D nanoarrays for electrical characterizations. All the devices are thermally treated or chemically treated (with hydrazine) to reduce the contact resistances. The temperature dependent resistances have been obtained at temperatures from 300 K to 100 K. We found that our devices could be categorized into two types, according to their resistance-temperature behaviors. The first type of devices exhibits a transition temperature below which the resistance is independent of temperature. The second type of devices maintains negative temperature dependence in the whole temperature range. Comparing the different electrical properties of the two types, we concluded that the interchain coupling between quasi 1D nanoarrays results in a variation of resistance-temperature behavior. Moreover, the data can be analyzed in line with the fluctuation-induced tunneling model.