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Sheathless Elasto‐Inertial Focusing of Sub‐25 Nm Particles in Straight Microchannels

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Selim Tanriverdi, Martim Costa, Selim Tanriverdi, Martim Costa, Martim Costa, Martim Costa, Javier Cruz, Luca Brandt, Javier Cruz, Shahriar Habibi, Luca Brandt, Aman Russom Shahriar Habibi, Martim Costa, Selim Tanriverdi, Selim Tanriverdi, Taras Sych, Luca Brandt, Luca Brandt, Luca Brandt, Martim Costa, Selim Tanriverdi, Luca Brandt, Gustaf Mårtensson, André Görgens, Aman Russom Aman Russom Aman Russom Aman Russom Samir EL Andaloussi, Luca Brandt, Outi Tammisola, Erdinç Sezgin, Aman Russom

Summary

Scientists developed a new method to focus and separate nanoparticles as small as 25 nanometers using microchannels and special fluid properties, without needing any external equipment like electric fields. They successfully focused biological particles including lipoproteins and extracellular vesicles, which are important for medical diagnostics. While the technology was designed for biomedical applications, it could also be applied to detecting and separating nanoplastics from environmental samples.

Body Systems

Cardiovascular

Nanoscale biological particles, such as lipoproteins (10-80 nm) or extracellular vesicles (30-200 nm), play pivotal roles in health and disease, including conditions like cardiovascular disorders and cancer. Their effective analysis is crucial for applications in diagnostics, quality control, and nanomedicine development. While elasto-inertial focusing offers a powerful method to manipulate particles without external fields, achieving consistent focusing of nanoparticles (<500 nm) has remained a challenge. In this study, elasto-inertial focusing of nanoparticles as small as 25 nm is experimentally demonstrated using straight high-aspect-ratio microchannels in a sheathless flow. Systematic investigations reveal the influence of channel width, particle size, viscoelastic concentration, and flow rate on focusing behavior. Additionally, through numerical simulations and experimental validation, insights are provided into particle migration dynamics and viscoelastic forces governing nanoparticle focusing. Finally, biological particles, including liposomes (90-140 nm), extracellular vesicles (100 nm), and lipoproteins (10-25 nm) is successfully focused, under optimized conditions, showcasing potential applications in medical diagnostics and targeted drug delivery. These findings mark a significant advancement toward size-based high-resolution particle separation, with implications for biomedicine and environmental sciences.

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