This research fabricated high-gain avalanche rushing amorphous photoconductors (HARP) for medical x-ray detector applications, using amorphous selenium (a-Se) as the photoconductor material because of its high photoconversion efficiency. Under a strong electrical field, photogenerated holes travel in the photoconductor layer with a high velocity and collide with atoms on the drift path, resulting in more photogenerated carriers. The successive impact ionization process induces the so-called “avalanche multiplication” of the electrical signal. For medical x-ray imagers of low irradiation exposure, HARP devices should have a high photoconversion gain with a very small noise so that a high image contrast can be obtained. The injection of holes and electrons into the a-Se layer via the top and bottom contact electrodes is the primary noise source. We used thermal evaporation to deposit a-Se thin films with a thickness up to 25 um at temperatures below 40oC. The CeO2 hole blocking and Sb2S3 electron blocking layers, which sandwiched the a-Se layer, were prepared by sputter deposition to minimize the dark current induced by the noise so that the ratio of the light current to the dark current can be enhanced. In addition, we also deposited a distributed resistive layer on the Sb2S3 layer to successfully improve the electrical breakdown voltage for the HARP structure. HARP devices fabricated in the study had a bright/dark current ratio as high as 70 at a bias field of 70 V/m.