Despite recent efforts to apply next-generation sequencing for genetic disease diagnosis, detection rates of causal variants are still limited to 50-75%. This is assumingly attributed to the current lack of a practical schema to predict pathogenic non-coding variants. Here, we propose a diagnostic schema for deep-intronic splicing-associated variants (SAVs), using a splicing predictor, SpliceAI. We comprehensively collected pathogenic deep-intronic SAVs (n=370) to measure the SpliceAI sensitivity. Subsequently, we evaluate its clinical utility by analyzing 2,504 whole-genome sequencing (WGS) samples from 1000 Genomes Project, and validating a subset of SAV candidates (n=10,801) in immortalized B cells. These approaches revealed that a 0.20 score threshold of SpliceAI detected 90% of pathogenic deep-intronic SAVs. This threshold is clinically applicable because it predicted about 37 SAV candidates per individual, whose number is small enough for clinicians to perform manual reviews for causal variants. A 0.76 threshold (40% sensitivity) is also recommended because of its high precision of 58 %. Lastly, we applied our approach to a patient previously diagnosed as beta-propeller protein-associated neurodegeneration and successfully detected the causal deep-intronic SAV in WDR45 gene. In conclusion, this diagnostic schema will shed a light on previously overlooked deep-intronic SAVs in genetic diseases. The study was approved by the institutional review boards. After written consent was obtained, peripheral blood samples were collected from each subject and the parents.