The waves that make the pattern: a review on acoustic manipulation in biomedical research

Guex, Anne Géraldine; Marzio, Nicola Di; Eglin, David; Alini, Mauro; Serra, Tiziano

doi:10.1016/j.mtbio.2021.100110

Cited by 61 publications

(53 citation statements)

References 112 publications

(148 reference statements)

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“…The response speed is fast, and it has great development prospects in the field of medical testing and diagnosis. [129,144] Optical drive: use the light pressure of the optical trap where the laser is focused to control the motion of micro-nano-scale objects, which can be modulated into complex patterns in time and space, with greater degrees of freedom. It has a large application space in the field of eye treatment.…”

Section: Physicalmentioning

confidence: 99%

Recent Advances in Field‐Controlled Micro–Nano Manipulations and Micro–Nano Robots

Chen

Liang

et al. 2021

Advanced Intelligent Systems

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Figure 6. Recent research and applications of acoustic control. A) Acoustic controlled RBC-PL-robot for removal of pathogenic bacteria and toxins.Reproduced with permission. [115] Copyright 2017, ACS. B) Acoustic controlled rotation of microbeads and oocytes. Reproduced with permission. [116] Copyright 2019, AIP. C) Acoustic controlled nanoswimmer for propulsion to maneuver micro-/nanosized objects. Reproduced with permission. [118] Copyright 2019, ACS. D) An untethered ultrasound-controlled actuator for targeted drug delivery. Reproduced with permission. [119] Copyright 2019, Springer Nature. E) Acoustic controlled micro rotor in PDMS channel for microelectromechanical systems. Reproduced with permission. [120]

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Section: Physicalmentioning

confidence: 99%

Recent Advances in Field‐Controlled Micro–Nano Manipulations and Micro–Nano Robots

Chen

Liang

et al. 2021

Advanced Intelligent Systems

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“…This is a very appealing new technology that could circumvent many of the drawbacks of 3D printing. Indeed, using acoustic surface standing waves that position cells or organoids at static pressure nodes, it is possible to quickly and spatially orchestrate patterning of different cell types or organoids in space within a hydrogel (reviewed in [50][51][52]). It enabled the engineering of aligned muscle tissue constructs using myoblasts embedded in type I collagen hydrogels [53].…”

Section: Sound-induced Morphogenesis: a Step Forward In Cardiac Tissu...mentioning

confidence: 99%

Cardiac Organoids and Gastruloids to Study Physio-Pathological Heart Development

Jaconi

Pucéat

2021

JCDD

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Ethical issues restrict research on human embryos, therefore calling for in vitro models to study human embryonic development including the formation of the first functional organ, the heart. For the last five years, two major models have been under development, namely the human gastruloids and the cardiac organoids. While the first one mainly recapitulates the gastrulation and is still limited to investigate cardiac development, the second one is becoming more and more helpful to mimic a functional beating heart. The review reports and discusses seminal works in the fields of human gastruloids and cardiac organoids. It further describes technologies which improve the formation of cardiac organoids. Finally, we propose some lines of research towards the building of beating mini-hearts in vitro for more relevant functional studies.

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“…Nevertheless, utilizing audible sound (in the range of 20–20,000 Hz) to control any molecular or supramolecular events and synthesis is still in its infancy, most likely due to its low intensity, which is unable to induce chemical transformations 33 . However, it has been long known that vertical shaking of a liquid-filled dish using audible sound (or a vibration generator) can generate a standing wave pattern on the liquid surface (Faraday instability), and the patterns change significantly depending on the frequency of the applied sound and the shape of the dish 34 – 38 . Based on this phenomenon, very recently we have developed a facile strategy that utilizes audible sound to control the spatiotemporal distribution of chemical components in out-of-equilibrium systems resulting in the formation of predictable chemical patterns 39 .…”

Section: Introductionmentioning

confidence: 99%

Cascade reaction networks within audible sound induced transient domains in a solution

et al. 2022

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Spatiotemporal control of chemical cascade reactions within compartmentalized domains is one of the difficult challenges to achieve. To implement such control, scientists have been working on the development of various artificial compartmentalized systems such as liposomes, vesicles, polymersomes, etc. Although a considerable amount of progress has been made in this direction, one still needs to develop alternative strategies for controlling cascade reaction networks within spatiotemporally controlled domains in a solution, which remains a non-trivial issue. Herein, we present the utilization of audible sound induced liquid vibrations for the generation of transient domains in an aqueous medium, which can be used for the control of cascade chemical reactions in a spatiotemporal fashion. This approach gives us access to highly reproducible spatiotemporal chemical gradients and patterns, in situ growth and aggregation of gold nanoparticles at predetermined locations or domains formed in a solution. Our strategy also gives us access to nanoparticle patterned hydrogels and their applications for region specific cell growth.

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The waves that make the pattern: a review on acoustic manipulation in biomedical research

Cited by 61 publications

References 112 publications

Recent Advances in Field‐Controlled Micro–Nano Manipulations and Micro–Nano Robots

Recent Advances in Field‐Controlled Micro–Nano Manipulations and Micro–Nano Robots

Cardiac Organoids and Gastruloids to Study Physio-Pathological Heart Development

Cascade reaction networks within audible sound induced transient domains in a solution

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