Floating magnetic microrobots for fiber functionalization

Barbot, Antoine; Tan, Haijie; Power, Maura; Seichepine, Florent; Yang, Guang‐Zhong

doi:10.1126/scirobotics.aax8336

Cited by 57 publications

(50 citation statements)

References 39 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This ratio will be studied to understand how many electrodes an implant can accommodate and the diameter of these electrodes to allow the implant to fully recover shape. Conversely, we can explore other alternatives to include electrodes in our SMP‐based CI, such as co‐drawing SMP and low temperature melting metal or introducing electrodes in the implant as suggested by Barbot et al [ 32 ] The results also showed a degree of variability that can be explained in part by how the material molds or collapses around the metal electrode during the molding stage, as shown by the implants tested to assess the stiction effect, which laid closer to the calculated fit line. The effect of the electrode during molding was also noticed when we compared the average initial angle after molding for the implants with and without an electrode used in this work experiments, which was 320° ( n = 30) and 282° ( n = 9), respectively.…”

Section: Resultsmentioning

confidence: 99%

Towards a Functional Atraumatic Self‐Shaping Cochlear Implant

Bautista‐Salinas

Abdelaziz

Temelkuran

et al. 2021

Macro Materials & Eng

View full text Add to dashboard Cite

Cochlear implants (CIs) have been shown to improve hearing in patients suffering from sensorineural hearing loss. CIs deliver electrical pulses to the hearing nerve via an electrode array that is carefully inserted in the scala tympani in a complex surgical procedure. However, current CIs can cause trauma during insertion, threatening hearing preservation. Existing pre‐curved CIs use external mechanisms to be inserted. In this work, a pre‐curved CI is proposed that curls into the cochlea under the influence of body temperature. By comparison to existing CIs, the proposed device can be smaller and easily inserted. The implant material is implemented in COMSOL to simulate its behavior, and an analytical study is conducted to verify the material model. Two additional studies are carried out to assess the implant recovery forces and their ability to recover shape even with embedded metal. Numerical modeling and experimental tests suggest that the CI recovery forces are below the rupture threshold. The recovery study in a functional self‐shaping CI shows that the device will still be able to curl in the cochlea. This implant concept has thus shown potential to be eventually used in clinical practice and improve hearing outcomes seen at present.

show abstract

Section: Resultsmentioning

confidence: 99%

Towards a Functional Atraumatic Self‐Shaping Cochlear Implant

Bautista‐Salinas

Abdelaziz

Temelkuran

et al. 2021

Macro Materials & Eng

View full text Add to dashboard Cite

show abstract

“…The actuating magnetic field itself can be supplied using electromagnetic coils or permanent magnets, but the latter option was incorporated into our system due to space constraints and its simplicity of implementation. Permanent magnets have been used for actuation in a variety of other robotic systems, including helical microrobot platforms [ 47 , 48 , 49 ], a microrobotic system for aligning floating electronic circuits to fibers in a wet transfer process [ 50 ], and a larger system involving magnetic capsule endoscopes [ 51 ]. More recently, point-to-point closed-loop motion control of magnetically driven screws actuated using permanent magnets was demonstrated within an agar gel tissue phantom [ 52 ].…”

Section: Discussionmentioning

confidence: 99%

A Tumbling Magnetic Microrobot System for Biomedical Applications

Niedert

Adam

et al. 2020

Micromachines

View full text Add to dashboard Cite

A microrobot system comprising an untethered tumbling magnetic microrobot, a two-degree-of-freedom rotating permanent magnet, and an ultrasound imaging system has been developed for in vitro and in vivo biomedical applications. The microrobot tumbles end-over-end in a net forward motion due to applied magnetic torque from the rotating magnet. By turning the rotational axis of the magnet, two-dimensional directional control is possible and the microrobot was steered along various trajectories, including a circular path and P-shaped path. The microrobot is capable of moving over the unstructured terrain within a murine colon in in vitro, in situ, and in vivo conditions, as well as a porcine colon in ex vivo conditions. High-frequency ultrasound imaging allows for real-time determination of the microrobot’s position while it is optically occluded by animal tissue. When coated with a fluorescein payload, the microrobot was shown to release the majority of the payload over a 1-h time period in phosphate-buffered saline. Cytotoxicity tests demonstrated that the microrobot’s constituent materials, SU-8 and polydimethylsiloxane (PDMS), did not show a statistically significant difference in toxicity to murine fibroblasts from the negative control, even when the materials were doped with magnetic neodymium microparticles. The microrobot system’s capabilities make it promising for targeted drug delivery and other in vivo biomedical applications.

show abstract

“…In addition to these approaches, there are also some other techniques specifically for integrating sensors on readymade soft devices, e.g., laser‐tuned selective transfer printing [ 306 ] and wet transfer process. [ 307 ] Among them, the laser‐tuned selective transfer printing technology can also be used for the assembly and reconstruction of soft magnetic robots, [ 308 ] through which we can perceive its potential of being used to construct complex 3D soft structures in a layer‐by‐layer manner. Introducing them as a postprocessing step or directly integrating them with other methods can be considered in future.…”

Section: Fabrication Techniquesmentioning

confidence: 99%

Intelligent Soft Surgical Robots for Next‐Generation Minimally Invasive Surgery

Zhu

Lyu

et al. 2021

Advanced Intelligent Systems

View full text Add to dashboard Cite

Endowed with the expected visions for future surgery, minimally invasive surgery (MIS) has become one of the most rapid developing areas in modern surgery. Soft robotics, which originates from interdisciplinary advances in materials, fabrication, and electronics, featuring better adaptability and safer interaction, holds great promises in addressing current technical challenges in MIS, which are difficult to be solved with current rigid robotic technologies. For the first time, herein, the expected characteristics of next-generation MIS from the surgeons' perspectives are analyzed and the recent progress of soft surgical instruments from three different aspects is comprehensively summarized: engineering design, fabrication techniques, and human-robot interaction. Perspectives of nextgeneration soft surgical robots are then discussed, where some exciting possibilities are emphasized. It is believed that further developments of intelligent soft robotics enable the next-generation MIS to agilely navigate to the target and conduct dexterous diagnostic or therapeutic procedures without any trade-offs in invasiveness and ultimately be a propitious solution for future surgery.

show abstract

Floating magnetic microrobots for fiber functionalization

Cited by 57 publications

References 39 publications

Towards a Functional Atraumatic Self‐Shaping Cochlear Implant

Towards a Functional Atraumatic Self‐Shaping Cochlear Implant

A Tumbling Magnetic Microrobot System for Biomedical Applications

Intelligent Soft Surgical Robots for Next‐Generation Minimally Invasive Surgery

Contact Info

Product

Resources

About