Project Summary/Abstract Most long-read DNA sequencing methods depend on library size selection techniques to control and/or improve read lengths. In Oxford Nanopore and PacBio sequencing protocols, sample loading is dependent on diffusion of library molecules to the reader surface (waveguide surface for PacBio, or membrane for Oxford). Since small molecules have a higher rate of diffusion than larger molecules, size selection to eliminate small library fragments can greatly improve library read lengths. Popular methods for elimination of small library elements (generally <6-10kb) in long read sequencing are preparative agarose gel electrophoresis (BluePippin, SageELF, PippinHT from Sage Science, Inc.), and PEG precipitation (Short Read Eliminator Kit, Circulomics, as well as home brew PEG methods). Of these methods, preparative gel electrophoresis is superior in rejecting small DNA molecules, but requires specialized instruments, consumable gel cassettes with bulky gel columns (6-10cm long) and low per- cassette sample throughputs, and long run times. In many long-read sequencing workflows, size selection is the most time-intensive step of the workflow. As long-read sequencing methods are rapidly becoming essential clinical research tools -- and increasingly attracting attention of medical testing labs -- it is important to develop size selection equipment and methods that have improved size range, improved resolution at large fragment sizes (10kb-200kb), faster run times, and higher sample throughput per run cycle. The goal of the present application is develop new preparative gel electrophoresis systems that utilize the nonlinear response of large DNAs: 1) while reorienting in response to certain pulsed field conditions, or 2) when subjected to forward and reverse voltage pulses of different strength. In both cases, we envision size selection processes in which targeted size fractions move very little and are recovered within (or near) the sample loading position. If successful, gel sizes and run times can be decreased dramatically, thereby relieving a bottleneck in long-read workflows that benefit from stringent size selection. Our ultimate goal is a family of size selection products that utilize SBS-format, automation-friendly gel cassettes with 48 or 96 well sample capacity.