| No. |
Subject |
File |
| 378 |
Ferrofluid Soft-robot Bio-inspired by Amoeba Locomotion |
 |
| 377 |
Mechanical Mechanism and Principles for Active CapsuleLocomotion |
|
| 376 |
Electroactive Polymer Actuator Based PVDF and Graphene through Electrospinning |
|
| 375 |
A Hybrid Actuated Microrobot using an Electromagnetic Field and Flagellated Bacteria for Tumor |
|
| 374 |
Motion control of bacteriobots based on bacterial chemotaxis |
|
| 373 |
Development of a bacteria-based microrobot using chitosan-coated liposome |
|
| 372 |
Active Triggering Biopsy Device for Magnetically Driven Capsule Endoscope |
|
| 371 |
Simulation of Effect of Cable Robot Configuration onNatural Frequency |
|
| 370 |
Simulation on Vibration of planar cable-driven parallel robot |
|
| 369 |
Light-assisted Direct Writing, Visualizing, Analyzing System forMicro Pattern using Biomaterials |
|
| 368 |
An Integrated Platform for Light-assisted Direct Writing, Visualizing, Analyzing System using Biomaterials |
|
| 367 |
Novel electroactive actuator based on PAMPS and TEMPO-mediated oxidized bacterial cellulose nanocomposites |
|
| 366 |
Development of self-assembled hyaluronic acid micelles for controlled drug release |
|
| 365 |
약물 전달을 위한 히알루론산 마이크로비드를 이용한 전자기구동 시스템기반 마이크로로봇 |
|
| 364 |
Development of Paclitaxel-encapsulated Chitosan-coated Microbeads forTumor Therapy |
|
 [11] [12] [13] [14] [15] [16] [17] [18] [19] [20]  |
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