Litcius/Paper detail

Precision acoustofluidics for high-throughput mechanobiology in suspension cells

Kaichun Yang, Ruoyu Zhong, Ke Li, John Mai, P Liu, Ye He, Joseph Rich, Ying Chen, Janna Wang, Zhiteng Ma, XU Xianchen, Qian Wu, Tony Jun Huang

2026Science Advances6 citationsDOIOpen Access PDF

Abstract

Mechanomodulation, the process of altering cellular behavior through applied mechanical forces, plays a critical role in physiological processes and has substantial implications for cancer therapy, immunology, and drug development. However, precise and efficient stimulation of nonadherent cells remains a major challenge, limiting the investigation of mechanotransduction pathways and the development of targeted therapeutics. Here, we developed an acoustofluidic platform named Suspension-cell Targeted Response to Excitation via Acoustofluidic Mechanomodulation (STREAM) to enable precise, high-throughput stimulation of suspension cells. STREAM accomplishes this using 101.14-megahertz high-frequency surface acoustic waves to deliver controlled mechanical stimulation at a throughput of 500,000 cells per minute. STREAM modulates intracellular calcium ion (Ca 2+ ) signaling by activating mechanosensitive ion channels, triggering mitochondrial membrane disruption and tunable K562 leukemia cell apoptosis rates from 5.15 to 47.1%. STREAM provides a scalable, precise tool for studying mechanotransduction in suspension cells, with broad applications in cancer research, immunotherapy, and high-throughput drug screening.

Topics & Concepts

MechanotransductionMechanosensitive channelsMechanobiologyIntracellularStimulationNanotechnologyCancer cellMaterials scienceCell biologyMicrofluidicsChemistryIon channelBiophysicsCellCell cultureProcess (computing)MechanosensationSuspension (topology)LimitingCell membraneK562 cellsGlycocalyxTetheringCalcium signalingApoptosisCell signalingPolydimethylsiloxaneMicrofluidic and Bio-sensing TechnologiesAcoustic Wave Resonator TechnologiesAcoustic Wave Phenomena Research