2019
DOI: 10.1002/smll.201903857
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Cell Mechanical and Physiological Behavior in the Regime of Rapid Mechanical Compressions that Lead to Cell Volume Change

Abstract: Cells respond to mechanical forces by deforming in accordance with viscoelastic solid behavior. Studies of microscale cell deformation observed by high speed video microscopy have elucidated a new cell behavior in which sufficiently rapid mechanical compression of cells can lead to transient cell volume loss and then recovery. This work has discovered that the resulting volume exchange between the cell interior and the surrounding fluid can be utilized for efficient, convective delivery of large macromolecules… Show more

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Cited by 30 publications
(36 citation statements)
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“…In the MDR-HDR cells undergo high mechanical compression that can enlarge and enrich pores. At the same time volume exchange under fast deformation 23,24 (<0.7 ms) can be favoured through the opened pores (Fig. 1b).…”
Section: Device Operation By a Pressure And Flow Microfluidic Controllermentioning
confidence: 87%
See 3 more Smart Citations
“…In the MDR-HDR cells undergo high mechanical compression that can enlarge and enrich pores. At the same time volume exchange under fast deformation 23,24 (<0.7 ms) can be favoured through the opened pores (Fig. 1b).…”
Section: Device Operation By a Pressure And Flow Microfluidic Controllermentioning
confidence: 87%
“…Methods based on shearinduced or contact-mediated cell deformation, employing different materials, device geometry and flow or pressure controller, have been developed in recent years to widen the applicability to different cell and cargo types. 1,[8][9][10][11][12][13][14][15][16][17][18][19][20][21][23][24][25][26][27]38 In previous mechanoporation methods, the flow inside the microfluidic chip has been controlled by either pressuredriven 10 (constant pressure) or a syringe-driven 21 (constant flow) system. Pressure-driven flow provides faster response and stabilization.…”
Section: Discussionmentioning
confidence: 99%
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“…The simplicity, controllability, versatility, and biocompatibility of the newly described technology make it highly suitable for multiple applications. These include important applications in physics (e.g., studying complex fluids and soft materials [5][6][7] and generation of droplets [58,59] ), chemistry (e.g., synthesis of various molecules and compounds [11,12] ), and biology (e.g., manipulation of cells, [60,61] performing multistep assays, [13] diagnostics, [62] and developing organ-on-a-chip platforms [63] for studying the mechanobiology of cells [64,65] and the human circulatory system [17,19,66] ). Notably, both customized harmonic and disturbed flow patterns can be created and studied using the newly described technology.…”
Section: Resultsmentioning
confidence: 99%