Advancements in Throughput, Lifetime, Purification, and Workflow for Integrated Nanoscale Deterministic Lateral Displacement
Published in Advanced Materials Technologies, 2021
Recommended citation: Benjamin Wunsch, Kuan Hsieh, Sung-Cheol Kim, Michael Pereira, Stanislav Lukashov, Chris Scerbo, John Papalia, Elizabeth Duch, Gustavo Stolovitzky, Stacey Gifford, Joshua Smith, "Advancements in Throughput, Lifetime, Purification, and Workflow for Integrated Nanoscale Deterministic Lateral Displacement." Advanced Materials Technologies, 2021. https://onlinelibrary.wiley.com/doi/abs/10.1002/admt.202001083
1) i-nanoDLD technology addresses nanoDLD's previous limitations with high efficiency and performance.
2) The development of an integrated design and increased parallelization results in a higher target colloid concentration and removal of contaminants from samples.
3) Upstream filter bank integration extends operation lifetime and allows for straightforward chip-to-world interfacing, making the technology suitable for research and clinical applications.
Abstract
Nanoscale deterministic lateral displacement (nanoDLD) has emerged as an effective method for separating nanoscopic colloids for applications in molecular biology, yet present limits in throughput, purification, on-chip filtration, and workflow restricting its adoption as a practical separation technology. To overcome these impediments, array scaling and parallelization for integrated nanoDLD (i-nanoDLD) enrichment devices are developed to achieve a density of ≈83 arrays mm−2 with 31 160 parallel arrays, producing an ≈30-fold concentration of the target colloid and a record throughput of 17 mL h−1. Purification using a dual-fluid input embodiment of i-nanoDLD is demonstrated to successfully remove background contaminants from target colloid samples, including urine. Used serially, high-throughput enrichment and purification chips achieve >1700 gain in particle over protein concentration compared to input sample. Additionally, integration of upstream filter banks shows improved operation lifetime > 7× for particles with diameters close to the gap size. Finally, the integrated design and associated flow rates allow a straightforward approach to chip-to-world interfacing as demonstrated using a prototype system for facile, turn-key sample processing. Collectively, these developments advance nanoDLD into the range of sample volumes and process times needed for research and clinical samples.