On-chip light sheet illumination enables diagnostic size and concentration measurements of membrane vesicles in biofluids

Deschout, Hendrik; Raemdonck, Koen; Stremersch, Stephan; Maoddi, Pietro; Mernier, Guillaume; Renaud, Philippe; Jiguet, Sébastien; Hendrix, An; Bracke, Marc; Broecke, Rudy Van den; Röding, Magnus; Rudemo, Mats; Demeester, Jo; Smedt, Stefaan C. De; Strubbe, Filip; Neyts, Kristiaan; Braeckmans, Kevin

doi:10.1039/c3nr04432g

Cited by 52 publications

(38 citation statements)

References 30 publications

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“…Light sheet microscopy can thus achieve optical sectioning, similar to confocal microscopy, but with less photobleaching and faster acquisition rates. A number of recent papers report improved signal-to-noise ratio, and good spatial and temporal resolution, using light sheet microscopy-based particle tracking [148, 152, 153]. …”

Section: Advanced Topics In Particle Trackingmentioning

confidence: 99%

Particle tracking in drug and gene delivery research: State-of-the-art applications and methods

Schuster

Ensign

Allan

et al. 2015

Advanced Drug Delivery Reviews

120

139

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Particle tracking is a powerful microscopy technique to quantify the motion of individual particles at high spatial and temporal resolution in complex fluids and biological specimens. Particle tracking's applications and impact in drug and gene delivery research have greatly increased during the last decade. Thanks to advances in hardware and software, this technique is now more accessible than ever, and can be reliably automated to enable rapid processing of large data sets, thereby further enhancing the role that particle tracking will play in drug and gene delivery studies in the future. We begin this review by discussing particle tracking-based advances in characterizing extracellular and cellular barriers to therapeutic nanoparticles and in characterizing nanoparticle size and stability. To facilitate wider adoption of the technique, we then present a user-friendly review of state-of-the-art automated particle tracking algorithms and methods of analysis. We conclude by reviewing technological developments for next-generation particle tracking methods, and we survey future research directions in drug and gene delivery where particle tracking may be useful.

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Section: Advanced Topics In Particle Trackingmentioning

confidence: 99%

Particle tracking in drug and gene delivery research: State-of-the-art applications and methods

Schuster

Ensign

Allan

et al. 2015

Advanced Drug Delivery Reviews

120

139

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“…One promising approach combines on-chip microfiltration and miniaturized nuclear magnetic resonance to enable quantitative detection of exosomes labeled with target-specific magnetic nanoparticles [38]. We developed a low-cost disposable microfluidic chip with integrated light sheet illumination for high-throughput exosome staging in cancer patients [39]. Light sheet illumination enables on-chip detection of exosomes that are fluorescently labeled directly in biofluids without pre-processing steps.…”

Section: Clinical Assessment Of Experimentally Validated Pro-invasmentioning

confidence: 99%

Rab27 GTPases Distribute Extracellular Nanomaps for Invasive Growth and Metastasis: Implications for Prognosis and Treatment

Hendrix

Wever

2013

IJMS

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The Rab27 family of small GTPases regulates exocytosis of distinct vesicle types including multivesicular endosomes, which results in the release of exosomes. Exosomes are nanometer-sized membrane vesicles that enclose soluble factors such as proteins and nucleic acids within a lipid bilayer and can travel toward distant tissues to influence multiple aspects of cell behavior. In our view that tumors are endocrine organs producing exosomes, Rab27 GTPases and their effector proteins are critical determinants for invasive growth and metastasis. Rab27 proteins and their effectors may serve as prognostic biomarkers or as targets for patient-tailored therapy.

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“…The diverging light fields between the waveguide gap can also combine waveguide trapping with on-chip fluorescence imaging [21]. Lifting particles away from the surface of the waveguide might improve the signal-to-noise ratio when analyzing biological samples.…”

Section: Discussionmentioning

confidence: 99%

Optical transport, lifting and trapping of micro-particles by planar waveguides

Helle¹,

Ahluwalia²,

Hellesø³

2015

Opt. Express

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Optical waveguides can be used to trap and transport microparticles. The particles are held close to the waveguide surface by the evanescent field and propelled forward. We propose a new technique to lift and trap particles above the surface of the waveguides. This is made possible by a gap between two opposing, planar waveguides. The field emitted from each of the waveguide ends diverge fast, away from the substrate and into the cover-medium. By combining two fields propagating at an angle upwards and coming from opposite sides of a gap, particles can be stably lifted and trapped at the crossing of the two fields. Thus, particles are transported by waveguides leading to a gap, where they are lifted away from the substrate and trapped. The experiments are supported by numerical simulations of the forces on the micro-particles. Fluorescence imaging is used to track the particles in 3D with a precision of 50 nm.

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On-chip light sheet illumination enables diagnostic size and concentration measurements of membrane vesicles in biofluids

Cited by 52 publications

References 30 publications

Particle tracking in drug and gene delivery research: State-of-the-art applications and methods

Particle tracking in drug and gene delivery research: State-of-the-art applications and methods

Rab27 GTPases Distribute Extracellular Nanomaps for Invasive Growth and Metastasis: Implications for Prognosis and Treatment

Optical transport, lifting and trapping of micro-particles by planar waveguides

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