Soft Tunable Gelatin Robot with Insect-like Claw for Grasping, Transportation, and Delivery

Liu Yang; Jiaqi Miao; Gen Li; Hao Ren; Tieshan Zhang; Dong Guo; Yifeng Tang; Wanfeng Shang; Yajing Shen

doi:10.1021/acsapm.2c00522

Soft Tunable Gelatin Robot with Insect-like Claw for Grasping, Transportation, and Delivery

Liu Yang, Jiaqi Miao, Gen Li, Hao Ren, Tieshan Zhang, Dong Guo, Yifeng Tang, Wanfeng Shang^*, Yajing Shen^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

38 Citations (Scopus)

Abstract

Recently, insect-scale soft robots have received increasing attentions for diverse applications owing to their ability to access hard-to-reach areas. However, most of them are composed of non-degradable materials like PDMS and silicone rubbers, and such chemical inertness may become an obstacle for future clinical applications where tunable material properties or degradation abilities are required. Here, we present a small-scale soft robot from a magnetic gelatin hydrogel, whose mechanical properties can be easily tuned through one-step Hofmeister effected-assisted reaction. Moreover, the robot is designed with insect claw-like legged structure, allowing it to perform grasping and cargo transportation tasks as its non-degradable counterparts. The degradation and controlled delivery ability of the robot are also demonstrated to show the advantages of magnetic hydrogels over non-degradable polymers. Our study provides an alternative for the tunable and degradable millirobot construction with an effective manipulation ability and promotes the applications of millirobot in biomedical sceneries.

Original language	English
Pages (from-to)	5431–5440
Journal	ACS Applied Polymer Materials
Volume	4
Issue number	8
Online published	11 Jul 2022
DOIs	https://doi.org/10.1021/acsapm.2c00522
Publication status	Published - 12 Aug 2022

Funding

This work was support by the National Natural Science Foundation of China (NSFC61922093 and U1813211), Hong Kong RGC General Research Fund (CityU 11216421), and Shenzhen Key Basic Research Project (JCYJ20200109114827177 and SGDX20201103093003017).

Research Keywords

bioinspired
hydrogel-based robots
magnetic actuation
soft robots
tunable

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title = "Soft Tunable Gelatin Robot with Insect-like Claw for Grasping, Transportation, and Delivery",

abstract = "Recently, insect-scale soft robots have received increasing attentions for diverse applications owing to their ability to access hard-to-reach areas. However, most of them are composed of non-degradable materials like PDMS and silicone rubbers, and such chemical inertness may become an obstacle for future clinical applications where tunable material properties or degradation abilities are required. Here, we present a small-scale soft robot from a magnetic gelatin hydrogel, whose mechanical properties can be easily tuned through one-step Hofmeister effected-assisted reaction. Moreover, the robot is designed with insect claw-like legged structure, allowing it to perform grasping and cargo transportation tasks as its non-degradable counterparts. The degradation and controlled delivery ability of the robot are also demonstrated to show the advantages of magnetic hydrogels over non-degradable polymers. Our study provides an alternative for the tunable and degradable millirobot construction with an effective manipulation ability and promotes the applications of millirobot in biomedical sceneries.",

keywords = "bioinspired, hydrogel-based robots, magnetic actuation, soft robots, tunable",

author = "Liu Yang and Jiaqi Miao and Gen Li and Hao Ren and Tieshan Zhang and Dong Guo and Yifeng Tang and Wanfeng Shang and Yajing Shen",

year = "2022",

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doi = "10.1021/acsapm.2c00522",

language = "English",

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TY - JOUR

T1 - Soft Tunable Gelatin Robot with Insect-like Claw for Grasping, Transportation, and Delivery

AU - Yang, Liu

AU - Miao, Jiaqi

AU - Li, Gen

AU - Ren, Hao

AU - Zhang, Tieshan

AU - Guo, Dong

AU - Tang, Yifeng

AU - Shang, Wanfeng

AU - Shen, Yajing

PY - 2022/8/12

Y1 - 2022/8/12

N2 - Recently, insect-scale soft robots have received increasing attentions for diverse applications owing to their ability to access hard-to-reach areas. However, most of them are composed of non-degradable materials like PDMS and silicone rubbers, and such chemical inertness may become an obstacle for future clinical applications where tunable material properties or degradation abilities are required. Here, we present a small-scale soft robot from a magnetic gelatin hydrogel, whose mechanical properties can be easily tuned through one-step Hofmeister effected-assisted reaction. Moreover, the robot is designed with insect claw-like legged structure, allowing it to perform grasping and cargo transportation tasks as its non-degradable counterparts. The degradation and controlled delivery ability of the robot are also demonstrated to show the advantages of magnetic hydrogels over non-degradable polymers. Our study provides an alternative for the tunable and degradable millirobot construction with an effective manipulation ability and promotes the applications of millirobot in biomedical sceneries.

AB - Recently, insect-scale soft robots have received increasing attentions for diverse applications owing to their ability to access hard-to-reach areas. However, most of them are composed of non-degradable materials like PDMS and silicone rubbers, and such chemical inertness may become an obstacle for future clinical applications where tunable material properties or degradation abilities are required. Here, we present a small-scale soft robot from a magnetic gelatin hydrogel, whose mechanical properties can be easily tuned through one-step Hofmeister effected-assisted reaction. Moreover, the robot is designed with insect claw-like legged structure, allowing it to perform grasping and cargo transportation tasks as its non-degradable counterparts. The degradation and controlled delivery ability of the robot are also demonstrated to show the advantages of magnetic hydrogels over non-degradable polymers. Our study provides an alternative for the tunable and degradable millirobot construction with an effective manipulation ability and promotes the applications of millirobot in biomedical sceneries.

KW - bioinspired

KW - hydrogel-based robots

KW - magnetic actuation

KW - soft robots

KW - tunable

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U2 - 10.1021/acsapm.2c00522

DO - 10.1021/acsapm.2c00522

M3 - RGC 21 - Publication in refereed journal

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JO - ACS Applied Polymer Materials

JF - ACS Applied Polymer Materials

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ER -

Soft Tunable Gelatin Robot with Insect-like Claw for Grasping, Transportation, and Delivery

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GRF: Nanofiber-based Biodegradable Multi-legged Millirobot

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Soft Tunable Gelatin Robot with Insect-like Claw for Grasping, Transportation, and Delivery

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GRF: Nanofiber-based Biodegradable Multi-legged Millirobot

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