Optical catapulting of microspheres in mucus models—toward overcoming the mucus biobarrier

Bunea, Ada‐Ioana; Chouliara, Manto; Rønholt, Stine; Bañas, Andrew Rafael; Engay, Einstom; Glückstad, Jesper

doi:10.1117/1.jbo.24.3.035001

Cited by 5 publications

(4 citation statements)

References 66 publications

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“…Hence, such beam splitters have been used in numerous applications, e . g ., laser inscription, film perforation, parallel optical computing, facial recognition, motion sensing, and cell trapping. − Since the 1970s, Dammann gratings (DGs) were introduced to generate array illumination in the far field using only binary surface relief profiles and have remained of continuous interest. − As a popular beam splitter design, a family of DGs with various new designs have been proposed, such as circular DGs for measuring angular rotation of mirrors, super-resolution imaging, and generating disk-shaped distributed lasers, − and three-dimensional (3D) DGs for multifocal fluorescence microscopy, 3D simultaneously noninvasive manipulation of biological cells and nanoparticles, and 3D optical data storage. , …”

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confidence: 99%

Toward Near-Perfect Diffractive Optical Elements via Nanoscale 3D Printing

Wang

Zhang

et al. 2020

ACS Nano

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Diffractive optical elements (DOEs) are widely applied as compact solutions to generate desired optical patterns in the far field by wavefront shaping. They consist of microscopic structures of varying heights to control the phase of either reflected or transmitted light. However, traditional methods to achieve varying thicknesses of structures for DOEs are tedious, requiring multiple aligned lithographic steps each followed by an etching process. Additionally, the reliance on photomasks precludes rapid prototyping and customization in manufacturing complex and multifunctional surface profiles. To achieve this, we turn to nanoscale 3D printing based on two-photon polymerization lithography (TPL). However, TPL systems lack the precision to pattern diffractive components where subwavelength variations in height and position could lead to observable loss in diffraction efficiency. Here, we employed a lumped TPL parametric model and a workaround patterning strategy to achieve precise 3D printing of DOEs using optimized parameters for laser power, beam scan speed, hatching distance, and slicing distance. In our case study, millimeter scale near-perfect Dammann gratings were fabricated with measured diffraction efficiencies near theoretical limits, laser spot array nonuniformity as low as 1.4%, and power ratio of the zero-order spot as low as 0.4%. Leveraging on the advantages of additive manufacturing inherent to TPL, the 3D-printed optical devices can be applied for precise wavefront shaping, with great potential in all-optical machine learning, virtual reality, motion sensing, and medical imaging.

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confidence: 99%

Toward Near-Perfect Diffractive Optical Elements via Nanoscale 3D Printing

Wang

Zhang

et al. 2020

ACS Nano

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“…For example, optical catapulting of polystyrene microspheres in mucus models shows a behavior that can be attributed to chemical interactions between the object and the medium. [ 176 ] It is expected that such interactions would play a role in the motion of microrobots in complex media with different compositions. Tailoring the chemistry of the microrobots has been shown to confer stealth, nonimmunogenic or antifouling properties.…”

Section: Challenges In the Fabrication And Optical Actuation Of Polymeric Microrobotsmentioning

confidence: 99%

Light‐Powered Microrobots: Challenges and Opportunities for Hard and Soft Responsive Microswimmers

Bunea

Martella

Nocentini

et al. 2021

Advanced Intelligent Systems

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30 ms, the helical chiral structure is reverted. Reproduced with permission. [127] Copyright 2017, The Authors, published by Wiley-VCH GmbH. C) Directional movement of an oscillating helix hydrogel-based microstructure confined between two glass surfaces. Reproduced with permission. [127] Copyright 2017, The Authors, published by Wiley-VCH GmbH. D) (Left) Superimposed images of a spiral rotor under irradiation for 0.5 s and relaxation for 0.5 s and (right) superimposition of the thresholded outline of the rotor at different times. Reproduced under the terms of the CC-BY license. [128] Copyright 2019, The Authors, published by Wiley-VCH GmbH. E) LCN-based swimmer microrobots. (Left) Schematic illustration of the bioinspired wormlike travelling wave deformation shape change occurring during homogeneous phase transition or illumination with a patterned light. (Middle, right) Optical images of a microtube displacement under travelling patterned irradiation. (Middle) Green overlays, direction according to green arrows, yellow dashed line is the reference position. (Right) Optical microscopy images of a microdisk locomotion along a square path-the travelling wave direction is indicated by the green arrows, and the disk's direction of travel to the next waypoint by the white arrows. Reproduced with permission. [134] Copyright 2016, Springer Nature.

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“…For example, optical catapulting of polystyrene microspheres in mucus models shows a behavior that can be attributed to chemical interactions between the object and the medium. [176] It is expected that such interactions would play a role in the motion of microrobots in complex media with different Reproduced with permission. [208] Copyright 2018, Society of Photo-Optical Instrumentation Engineers.…”

Section: Actuationmentioning

confidence: 99%

Light‐Powered Microrobots: Challenges and Opportunities for Hard and Soft Responsive Microswimmers

Bunea

Martella

Nocentini

et al. 2021

Advanced Intelligent Systems

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Microrobots In article number http://doi.wiley.com/10.1002/aisy.202000256, Ada‐Ioana Bunea and co‐workers provide a critical overview of how microrobots can be manufactured and manipulated using light. The cover image shows blue structures printed in hard polymer and precisely manipulated by optical trapping with focused near‐infrared light, together with orange structures printed using soft, light‐responsive materials, which change shape in response to green light. Cover image drawn by Alexandre Wetzel.

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Optical catapulting of microspheres in mucus models—toward overcoming the mucus biobarrier

Cited by 5 publications

References 66 publications

Toward Near-Perfect Diffractive Optical Elements via Nanoscale 3D Printing

Toward Near-Perfect Diffractive Optical Elements via Nanoscale 3D Printing

Light‐Powered Microrobots: Challenges and Opportunities for Hard and Soft Responsive Microswimmers

Light‐Powered Microrobots: Challenges and Opportunities for Hard and Soft Responsive Microswimmers

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