Miniaturized Rotary Actuators Using Shape Memory Alloy for Insect-Type MEMS Microrobot

Saito, Ken; Iwata, Kei; Ishihara, Yuki; Sugita, Kazuki; Takato, Minami; Uchikoba, Fumio

doi:10.3390/mi7040058

Cited by 26 publications

(21 citation statements)

References 22 publications

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“…For the purpose of driving the movement of particles, an exogenous power is usually attached to control and coordinate the micro/nanorobot's behaviors. Magnetic field [22], electric field [23], light energy [24], acoustic wave [25], and heat energy [26] are frequently applied in drug carriers as an external power. In the actual design process, several driving modes are often used jointly to manufacture micro/nanorobots with multiple functions.…”

Section: Exogenous Power Driven Micro/nanorobotsmentioning

confidence: 99%

Micro/Nanorobot: A Promising Targeted Drug Delivery System

Chen

et al. 2020

Pharmaceutics

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Micro/nanorobot, as a research field, has attracted interest in recent years. It has great potential in medical treatment, as it can be applied in targeted drug delivery, surgical operation, disease diagnosis, etc. Differently from traditional drug delivery, which relies on blood circulation to reach the target, the designed micro/nanorobots can move autonomously, which makes it possible to deliver drugs to the hard-to-reach areas. Micro/nanorobots were driven by exogenous power (magnetic fields, light energy, acoustic fields, electric fields, etc.) or endogenous power (chemical reaction energy). Cell-based micro/nanorobots and DNA origami without autonomous movement ability were also introduced in this article. Although micro/nanorobots have excellent prospects, the current research is mainly based on in vitro experiments; in vivo research is still in its infancy. Further biological experiments are required to verify in vivo drug delivery effects of micro/nanorobots. This paper mainly discusses the research status, challenges, and future development of micro/nanorobots.

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Section: Exogenous Power Driven Micro/nanorobotsmentioning

confidence: 99%

Micro/Nanorobot: A Promising Targeted Drug Delivery System

Chen

et al. 2020

Pharmaceutics

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“…Those are concerning multidisciplinary fields in the areas of engineering, chemistry, material science, physics, and any specialized field for applications in bioengineering or medicine. Their future holds revolutionary breakthroughs in a wide range of: Nanocircuits, actuators (piezo-electrostatic, shape memory, electromagnetic), sensors, radar, locators, materials, imaging, nanocontact and nano-relays [31,32,33,34,35,36,37,38,39,40,41], micromotors and micropumps [42,43,44,45,46,47,48,49], optical functions and optoelectronic devices, such as switches, integrated energy harvesting, wave length filtering, optical grating switch and optical sensors—these MEMS are called micro optical electromechanical systems (MOMS) [50,51,52], energy storage [28,53], nanocapacitors, data storage and nano-computers [1,30,54,55,56] including 2D superconducting devices to be used for quantum computers [29], and such as, bio-functionalizing, etc. [1,11,16,57,58].…”

Section: Brief Review On Main Mems and Nems Characteristicsmentioning

confidence: 99%

“…With very high stiffness, high thermal conductivity, optical transparency range, chemical stability and wear resistance for the diamond-based materials extend their applicability for MEMS/NEMS [24]. Besides, these diamond materials which are nevertheless presenting a large panel of different structures and properties, and which have to be distinguished from each other’s [3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53,54,55,56,57,58,59,60,…”

Section: Increased Nems Performances With Advanced Carbon Materialsmentioning

confidence: 99%

Selective Carbon Material Engineering for Improved MEMS and NEMS

Neuville¹

2019

Micromachines

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The development of micro and nano electromechanical systems and achievement of higher performances with increased quality and life time is confronted to searching and mastering of material with superior properties and quality. Those can affect many aspects of the MEMS, NEMS and MOMS design including geometric tolerances and reproducibility of many specific solid-state structures and properties. Among those: Mechanical, adhesion, thermal and chemical stability, electrical and heat conductance, optical, optoelectronic and semiconducting properties, porosity, bulk and surface properties. They can be affected by different kinds of phase transformations and degrading, which greatly depends on the conditions of use and the way the materials have been selected, elaborated, modified and assembled. Distribution of these properties cover several orders of magnitude and depend on the design, actually achieved structure, type and number of defects. It is then essential to be well aware about all these, and to distinguish and characterize all features that are able to affect the results. For this achievement, we point out and discuss the necessity to take into account several recently revisited fundamentals on carbon atomic rearrangement and revised carbon Raman spectroscopy characterizing in addition to several other aspects we will briefly describe. Correctly selected and implemented, these carbon materials can then open new routes for many new and more performing microsystems including improved energy generation, storage and conversion, 2D superconductivity, light switches, light pipes and quantum devices and with new improved sensor and mechanical functions and biomedical applications.

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“…S UBSTANTIAL progress has been made in recent years towards the development of fully autonomous microrobots [1], [2]. However, gait design for robot locomotion at the sub-centimeter scale is not a well-studied problem.…”

Section: Introductionmentioning

confidence: 99%

Learning Flexible and Reusable Locomotion Primitives for a Microrobot

Yang

Wang

Calandra

et al. 2018

IEEE Robot. Autom. Lett.

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The design of gaits for robot locomotion can be a daunting process which requires significant expert knowledge and engineering. This process is even more challenging for robots that do not have an accurate physical model, such as compliant or micro-scale robots. Data-driven gait optimization provides an automated alternative to analytical gait design. In this paper, we propose a novel approach to efficiently learn a wide range of locomotion tasks with walking robots. This approach formalizes locomotion as a contextual policy search task to collect data, and subsequently uses that data to learn multi-objective locomotion primitives that can be used for planning. As a proofof-concept we consider a simulated hexapod modeled after a recently developed microrobot, and we thoroughly evaluate the performance of this microrobot on different tasks and gaits. Our results validate the proposed controller and learning scheme on single and multi-objective locomotion tasks. Moreover, the experimental simulations show that without any prior knowledge about the robot used (e.g., dynamics model), our approach is capable of learning locomotion primitives within 250 trials and subsequently using them to successfully navigate through a maze.

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Miniaturized Rotary Actuators Using Shape Memory Alloy for Insect-Type MEMS Microrobot

Cited by 26 publications

References 22 publications

Micro/Nanorobot: A Promising Targeted Drug Delivery System

Micro/Nanorobot: A Promising Targeted Drug Delivery System

Selective Carbon Material Engineering for Improved MEMS and NEMS

Learning Flexible and Reusable Locomotion Primitives for a Microrobot

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