Emerging Microfluidic Approaches for Platelet Mechanobiology and Interplay With Circulatory Systems

Zhang, Yingqi; Ramasundara, Savindi De Zoysa; Preketes-Tardiani, Renee E.; Cheng, Vivian; Lu, Hongxu; Ju, Lining Arnold

doi:10.3389/fcvm.2021.766513

Cited by 14 publications

(11 citation statements)

References 110 publications

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“…Such an assay system would not only complement the in vivo needle injury model but would be readily ‘humanized’ to allow the analysis of human neutrophil–platelet interactions in a tunable 3D hydrodynamic environment. 15 In this context, parallel-plate flow chambers and capillary microslides are the conventional methods employed to characterize adhesion dynamics between blood cells with cultured endothelial cells, subendothelial matrix proteins or platelet monolayers. 11,16–18 In the context of neutrophil–platelet interactions, platelets are usually pre-coated to form a 2D monolayer followed by neutrophil perfusion, 19,20 as the platelet thrombi that form on collagen substrates are heterogeneous and difficult to standardize.…”

Section: Introductionmentioning

confidence: 99%

Microfluidic post method for 3-dimensional modeling of platelet–leukocyte interactions

Kossmann

Zhao

et al. 2022

Analyst

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Section: Introductionmentioning

confidence: 99%

Microfluidic post method for 3-dimensional modeling of platelet–leukocyte interactions

Kossmann

Zhao

et al. 2022

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“…Equally important, the pulsed injection and rapid mixing of cell suspensions facilitate performing multistep assays, involving injection, dilution, drug stimulation, labeling, washing, and imaging of cells in a highly programmable manner. Furthermore, the versatility of our system provides opportunities for studying the response of mechanosensitive cells to vortical flows , and various shear levels , using microfluidic vessel models. , …”

Section: Discussionmentioning

confidence: 99%

Dynamic Vortex Generation, Pulsed Injection, and Rapid Mixing of Blood Samples in Microfluidics Using the Tube Oscillation Mechanism

Thurgood

Needham²,

Pirogova

et al. 2023

Anal. Chem.

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Here, we describe the generation of dynamic vortices in micro-scale cavities at low flow rates. The system utilizes a computer-controlled audio speaker to axially oscillate the inlet tube of the microfluidic system at desired frequencies and amplitudes. The oscillation of the tube induces transiently high flow rates in the system, which facilitates the generation of dynamic vortices inside the cavity. The size of the vortices can be modulated by varying the tube oscillation frequency or amplitude. The vortices can be generated in single or serial cavities and in a wide range of cavity sizes. We demonstrate the suitability of the tube oscillation mechanism for the pulsed injection of water-based solutions or whole blood into the cavity. The injection rate can be controlled by the oscillation characteristics of the tube, enabling the injection of liquids at ultralow flow rates. The dynamic vortices facilitate the rapid mixing of the injected liquid with the main flow. The controllability and versatility of this technology allow for the development of programmable inertial microfluidic systems for performing multistep biological assays.

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“…Conventional methods such as PFA-100/200 ® do not capture the geometric characteristics of the vessel, preventing the mimicking of platelet responses to their microenvironment. In contrast, latest soft lithography enables multifaceted, high-fidelity and customized microfluidic designs to imitate various vascular anatomies, such as straight ( Jain et al, 2016b ; Li et al, 2017 ; Zhang and Neelamegham, 2017 ; Albers et al, 2019 ; Dupuy et al, 2021 ), bifurcated ( Tsai et al, 2012 ), stenosed ( Tovar-Lopez et al, 2010 ; Jain et al, 2016b ) and net ( Zilberman-Rudenko et al, 2017 ; Zhang et al, 2021 ) channels. 2) Microfluidics can recapitulate hemodynamic microenvironment.…”

Section: Novel Microfluidic Approaches For Platelet Function Assessment and Anti-platelet Drug Screeningmentioning

confidence: 99%

“…Endothelialized microfluidics are rapidly evolving as humanized screening platforms ( Albers et al, 2019 ; Jenny et al, 2020 ; Dupuy et al, 2021 ). Increasing evidences demonstrate their great potential in simulating the interplays between platelets and circulatory systems ( Zhang et al, 2021 ). 5) Existing platelet function tests are bulky, expensive, and require specialized operators and a large volume of blood samples.…”

Section: Novel Microfluidic Approaches For Platelet Function Assessment and Anti-platelet Drug Screeningmentioning

confidence: 99%

Platelet Mechanobiology Inspired Microdevices: From Hematological Function Tests to Disease and Drug Screening

et al. 2022

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Platelet function tests are essential to profile platelet dysfunction and dysregulation in hemostasis and thrombosis. Clinically they provide critical guidance to the patient management and therapeutic evaluation. Recently, the biomechanical effects induced by hemodynamic and contractile forces on platelet functions attracted increasing attention. Unfortunately, the existing platelet function tests on the market do not sufficiently incorporate the topical platelet mechanobiology at play. Besides, they are often expensive and bulky systems that require large sample volumes and long processing time. To this end, numerous novel microfluidic technologies emerge to mimic vascular anatomies, incorporate hemodynamic parameters and recapitulate platelet mechanobiology. These miniaturized and cost-efficient microfluidic devices shed light on high-throughput, rapid and scalable platelet function testing, hematological disorder profiling and antiplatelet drug screening. Moreover, the existing antiplatelet drugs often have suboptimal efficacy while incurring several adverse bleeding side effects on certain individuals. Encouraged by a few microfluidic systems that are successfully commercialized and applied to clinical practices, the microfluidics that incorporate platelet mechanobiology hold great potential as handy, efficient, and inexpensive point-of-care tools for patient monitoring and therapeutic evaluation. Hereby, we first summarize the conventional and commercially available platelet function tests. Then we highlight the recent advances of platelet mechanobiology inspired microfluidic technologies. Last but not least, we discuss their future potential of microfluidics as point-of-care tools for platelet function test and antiplatelet drug screening.

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Emerging Microfluidic Approaches for Platelet Mechanobiology and Interplay With Circulatory Systems

Cited by 14 publications

References 110 publications

Microfluidic post method for 3-dimensional modeling of platelet–leukocyte interactions

Microfluidic post method for 3-dimensional modeling of platelet–leukocyte interactions

Dynamic Vortex Generation, Pulsed Injection, and Rapid Mixing of Blood Samples in Microfluidics Using the Tube Oscillation Mechanism

Platelet Mechanobiology Inspired Microdevices: From Hematological Function Tests to Disease and Drug Screening

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