3D steerable, acoustically powered microswimmers for single-particle manipulation

Ren, Liqiang; Nama, Nitesh; McNeill, Jeffrey M.; Soto, Fernando; Yan, Zi; Liu, Wu; Wang, Wei; Wang, Joseph; Mallouk, Thomas E.

doi:10.1126/sciadv.aax3084

Cited by 222 publications

(267 citation statements)

References 40 publications

(47 reference statements)

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“…Compared with microbubbles, microrobots are more stable and their mechanical properties are more prominent, but their manufacturing costs are higher and their use involves some difficulties. Some schemes combine microbubbles and microrobots, such as Ren et al [83] (Figure 7d). A microbubble was enclosed in a semi-capsule-shaped robot, and the secondary Bjerknes force formed between the bubble and the actuator was used to drive the microrobot motion.…”

Section: Vibrated Microbubbles and Microrobotsmentioning

confidence: 99%

“…A microbubble was enclosed in a semi-capsule-shaped robot, and the secondary Bjerknes force formed between the bubble and the actuator was used to drive the microrobot motion. [31], Ahmed et al [77,78], Xie et al [81,82], and Ren et al [83]. The reason why microbubbles and microrobots are classified into one category is that they both perform secondary micromanipulation, which means that their motion requires manipulation, and their motion characteristics drive the micromanipulation for other particles.…”

Section: Vibrated Microbubbles and Microrobotsmentioning

confidence: 99%

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Advances in Micromanipulation Actuated by Vibration-Induced Acoustic Waves and Streaming Flow

et al. 2020

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The use of vibration and acoustic characteristics for micromanipulation has been prevalent in recent years. Due to high biocompatibility, non-contact operation, and relatively low cost, the micromanipulation actuated by the vibration-induced acoustic wave and streaming flow has been widely applied in the sorting, translating, rotating, and trapping of targets at the submicron and micron scales, especially particles and single cells. In this review, to facilitate subsequent research, we summarize the fundamental theories of manipulation driven by vibration-induced acoustic waves and streaming flow. These methods are divided into two types: actuated by the acoustic wave, and actuated by the steaming flow induced by vibrating geometric structures. Recently proposed representative vibroacoustic-driven micromanipulation methods are introduced and compared, and their advantages and disadvantages are summarized. Finally, prospects are presented based on our review of the recent advances and developing trends.

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Section: Vibrated Microbubbles and Microrobotsmentioning

confidence: 99%

Section: Vibrated Microbubbles and Microrobotsmentioning

confidence: 99%

Advances in Micromanipulation Actuated by Vibration-Induced Acoustic Waves and Streaming Flow

et al. 2020

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“…R OBOTS capable of swimming at the microscale, microswimmers, have great potential as tools for a diverse set of applications such as drug delivery [1], micromixing [2], and micromanufacturing [3]. Due to their small size, microswimmers are difficult to manufacture and are generally controlled by an outside stimulus, e.g., a magnet that responds to an external field.…”

Section: Introductionmentioning

confidence: 99%

A Customizable DNA and Microsphere-Based, Magnetically Actuated Microswimmer

Harmatz

Travers

Taylor

2020

J. Microelectromech. Syst.

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Locomoting microscale robots-microswimmershave the potential to impact numerous applications due to their ability to selectively interact with their environment with microscale control. Previous microswimmer designs lack either submicron-level precision over their construction or instantaneous control over their shape. Thus, existing microswimmer designs limit the control afforded over microswimmer interactions with their environment. This work presents a magnetically actuated microswimmer constructed from DNA and microspheres in a hybrid top-down and bottom-up assembly technique that allows for submicron-level precision over microswimmer body construction. Microscale features were fabricated via two-photon polymerization, from which polydimethylsiloxane templates were molded. Templated assembly by selective removal was used to deposit microspheres of select size and composition into the templates. This technique was confirmed to be sizeselective within a population of microspheres. To construct the microswimmer, a ferromagnetic microsphere and a nonmagnetic microsphere were deposited into a template, connected with DNA nanotubes in their arrangement, magnetized, and pulled from the template. We demonstrate instantaneous control over shape changes via expansion and contraction of a microswimmer's body in an external magnetic field. In a rotating magnetic field of constant magnitude, the microswimmer expanded as the two microspheres separated a distance of 4.1±0.5 micrometers, approximately the distance between microspheres deposited in the template. In an oscillating magnetic field, the same microswimmer contracted and locomoted 58.8±0.7 micrometers over 126 seconds.

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“…Bubbles and sharp-edged solid structures excited by acoustic waves generate steady streaming in liquids, [28][29][30][31] providing a minimally invasive and scalable solution for powering untethered micromachines in vivo. [32][33][34][35][36] While bubbles are quite efficient in transducing acoustic energy, [37] microrobotic systems actuated by entrapped bubbles work reliable only for hours. [34,35] The size and mechanical response of bubbles do not stay the same under physiological conditions, thereby gradually shifting the resonance frequency of the actuators and deteriorating the performance of the machine.…”

mentioning

confidence: 99%

“…[32][33][34][35][36] While bubbles are quite efficient in transducing acoustic energy, [37] microrobotic systems actuated by entrapped bubbles work reliable only for hours. [34,35] The size and mechanical response of bubbles do not stay the same under physiological conditions, thereby gradually shifting the resonance frequency of the actuators and deteriorating the performance of the machine. Furthermore, stable entrapment and precise actuation of multiple bubbles inside a compartmentalized microrobot is quite challenging due to surface effects.…”

mentioning

confidence: 99%

Addressable Acoustic Actuation of 3D Printed Soft Robotic Microsystems

2020

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A design, manufacturing, and control methodology is presented for the transduction of ultrasound into frequency-selective actuation of multibody hydrogel mechanical systems. The modular design of compliant mechanisms is compatible with direct laser writing and the multiple degrees of freedom actuation scheme does not require incorporation of any specific material such as air bubbles. These features pave the way for the development of active scaffolds and soft robotic microsystems from biomaterials with tailored performance and functionality. Finite element analysis and computational fluid dynamics are used to quantitatively predict the performance of acoustically powered hydrogels immersed in fluid and guide the design process. The outcome is the remotely controlled operation of a repertoire of untethered biomanipulation tools including monolithic compound micromachinery with multiple pumps connected to various functional devices. The potential of the presented technology for minimally invasive diagnosis and targeted therapy is demonstrated by a soft microrobot that can on-demand collect, encapsulate, and process microscopic samples. Microfabricated devices have led to revolutionary changes in our ability to manipulate small volumes of fluid and microscopic samples contained therein. [1] As a result, majority of state-of-the-art in vitro biomedical platforms contain microfluidic components. Operating these devices requires the use of bulky pumps, compressors, or tethered electrical powering units, which significantly increase the overall size and limit the portability. A key technological challenge has been the development of untethered microfluidic systems that are capable of providing such functionality with wireless control for in vivo applications. Ideally, such systems are expected to determine the timing, duration, and dosage of the intervention and allow remote, noninvasive, repeatable, and reliable control of diagnostic or

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3D steerable, acoustically powered microswimmers for single-particle manipulation

Cited by 222 publications

References 40 publications

Advances in Micromanipulation Actuated by Vibration-Induced Acoustic Waves and Streaming Flow

Advances in Micromanipulation Actuated by Vibration-Induced Acoustic Waves and Streaming Flow

A Customizable DNA and Microsphere-Based, Magnetically Actuated Microswimmer

Addressable Acoustic Actuation of 3D Printed Soft Robotic Microsystems

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