Self-locomotive, antimicrobial microrobot (SLAM) swarm for enhanced biofilm elimination

Yu Heng Deng; Tomas Ricciardulli; Jungeun Won; Matthew A. Wade; Simon A. Rogers; Stephen A. Boppart; David W. Flaherty; Hyunjoon Kong

doi:10.1016/j.biomaterials.2022.121610

Self-locomotive, antimicrobial microrobot (SLAM) swarm for enhanced biofilm elimination

Yu Heng Deng, Tomas Ricciardulli, Jungeun Won, Matthew A. Wade, Simon A. Rogers, Stephen A. Boppart, David W. Flaherty, Hyunjoon Kong

Research output: Contribution to journal › Article › peer-review

Abstract

Biofilm is a major cause of infections and infrastructure deterioration, largely due to molecular diffusion restrictions that hamper the antimicrobial activity of traditional antibiotics and disinfectants. Here, we present a self-locomotive, antimicrobial microrobot (SLAM) swarm that can penetrate, fracture, and detach biofilm and, in turn, nullify bacterial resistance to antibiotics. The SLAM is assembled by loading a controlled mass of manganese oxide nanosheets on diatoms with the polydopamine binder. In hydrogen peroxide solution, SLAMs produce oxygen bubbles that generate thrust to penetrate the rigid and dense Pseudomonas aeruginosa biofilm and self-assemble into a swarm that repeatedly surrounds, expands, and bursts oxygen bubbles. The resulting cavities continue to deform and fracture extracellular polymeric substances from microgrooved silicone substrates and wounded skin explants while decreasing the number of viable bacterial cells. Additionally, SLAM allows irrigating water or antibiotics to access the residual biofilm better, thus enhancing the synergistic efficacy in killing up to 99.9% of bacterial cells.

Original language	English (US)
Article number	121610
Journal	Biomaterials
Volume	287
DOIs	https://doi.org/10.1016/j.biomaterials.2022.121610
State	Published - Aug 2022

Keywords

Bubble
Diatom
MnO
Polydopamine
Wound

ASJC Scopus subject areas

Biophysics
Bioengineering
Ceramics and Composites
Biomaterials
Mechanics of Materials

Online availability

10.1016/j.biomaterials.2022.121610

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@article{0ae01246f9ec412bb7a88f483fd6b51a,

title = "Self-locomotive, antimicrobial microrobot (SLAM) swarm for enhanced biofilm elimination",

abstract = "Biofilm is a major cause of infections and infrastructure deterioration, largely due to molecular diffusion restrictions that hamper the antimicrobial activity of traditional antibiotics and disinfectants. Here, we present a self-locomotive, antimicrobial microrobot (SLAM) swarm that can penetrate, fracture, and detach biofilm and, in turn, nullify bacterial resistance to antibiotics. The SLAM is assembled by loading a controlled mass of manganese oxide nanosheets on diatoms with the polydopamine binder. In hydrogen peroxide solution, SLAMs produce oxygen bubbles that generate thrust to penetrate the rigid and dense Pseudomonas aeruginosa biofilm and self-assemble into a swarm that repeatedly surrounds, expands, and bursts oxygen bubbles. The resulting cavities continue to deform and fracture extracellular polymeric substances from microgrooved silicone substrates and wounded skin explants while decreasing the number of viable bacterial cells. Additionally, SLAM allows irrigating water or antibiotics to access the residual biofilm better, thus enhancing the synergistic efficacy in killing up to 99.9% of bacterial cells.",

keywords = "Bubble, Diatom, MnO, Polydopamine, Wound",

author = "Deng, {Yu Heng} and Tomas Ricciardulli and Jungeun Won and Wade, {Matthew A.} and Rogers, {Simon A.} and Boppart, {Stephen A.} and Flaherty, {David W.} and Hyunjoon Kong",

note = "We appreciate the National Science Foundation (NSF-DMR 2004719) and the SerVaas Lab. OCT imaging and processing was supported in part by grants from the National Institutes of Health (R01EB013723, R01EB028615, S.A.B.). Electron microscopy and XPS analysis were performed at the Frederick Seitz Materials Research Laboratory Central Facilities at the University of Illinois. ICP-AES was conducted at Microanalysis Laboratory (SCS CORES) at the University of Illinois. Electron microscopy and high-speed camera were performed at Beckman Institute Imaging Technology Group at the University of Illinois. Y.-H.D. and H.K. thank Dr. J.B.Stiethl (Stiehl Tech LLC) for the scientific discussion. We appreciate the National Science Foundation (NSF-DMR 2004719) and the SerVaas Lab. OCT imaging and processing was supported in part by grants from the National Institutes of Health ( R01EB013723 , R01EB028615 , S.A.B.). Electron microscopy and XPS analysis were performed at the Frederick Seitz Materials Research Laboratory Central Facilities at the University of Illinois. ICP-AES was conducted at Microanalysis Laboratory (SCS CORES) at the University of Illinois. Electron microscopy and high-speed camera were performed at Beckman Institute Imaging Technology Group at the University of Illinois. Y.-H.D. and H.K. thank Dr. J.B.Stiethl (Stiehl Tech LLC) for the scientific discussion.",

year = "2022",

month = aug,

doi = "10.1016/j.biomaterials.2022.121610",

language = "English (US)",

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AU - Deng, Yu Heng

AU - Ricciardulli, Tomas

AU - Won, Jungeun

AU - Wade, Matthew A.

AU - Rogers, Simon A.

AU - Boppart, Stephen A.

AU - Flaherty, David W.

AU - Kong, Hyunjoon

N1 - We appreciate the National Science Foundation (NSF-DMR 2004719) and the SerVaas Lab. OCT imaging and processing was supported in part by grants from the National Institutes of Health (R01EB013723, R01EB028615, S.A.B.). Electron microscopy and XPS analysis were performed at the Frederick Seitz Materials Research Laboratory Central Facilities at the University of Illinois. ICP-AES was conducted at Microanalysis Laboratory (SCS CORES) at the University of Illinois. Electron microscopy and high-speed camera were performed at Beckman Institute Imaging Technology Group at the University of Illinois. Y.-H.D. and H.K. thank Dr. J.B.Stiethl (Stiehl Tech LLC) for the scientific discussion. We appreciate the National Science Foundation (NSF-DMR 2004719) and the SerVaas Lab. OCT imaging and processing was supported in part by grants from the National Institutes of Health ( R01EB013723 , R01EB028615 , S.A.B.). Electron microscopy and XPS analysis were performed at the Frederick Seitz Materials Research Laboratory Central Facilities at the University of Illinois. ICP-AES was conducted at Microanalysis Laboratory (SCS CORES) at the University of Illinois. Electron microscopy and high-speed camera were performed at Beckman Institute Imaging Technology Group at the University of Illinois. Y.-H.D. and H.K. thank Dr. J.B.Stiethl (Stiehl Tech LLC) for the scientific discussion.

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N2 - Biofilm is a major cause of infections and infrastructure deterioration, largely due to molecular diffusion restrictions that hamper the antimicrobial activity of traditional antibiotics and disinfectants. Here, we present a self-locomotive, antimicrobial microrobot (SLAM) swarm that can penetrate, fracture, and detach biofilm and, in turn, nullify bacterial resistance to antibiotics. The SLAM is assembled by loading a controlled mass of manganese oxide nanosheets on diatoms with the polydopamine binder. In hydrogen peroxide solution, SLAMs produce oxygen bubbles that generate thrust to penetrate the rigid and dense Pseudomonas aeruginosa biofilm and self-assemble into a swarm that repeatedly surrounds, expands, and bursts oxygen bubbles. The resulting cavities continue to deform and fracture extracellular polymeric substances from microgrooved silicone substrates and wounded skin explants while decreasing the number of viable bacterial cells. Additionally, SLAM allows irrigating water or antibiotics to access the residual biofilm better, thus enhancing the synergistic efficacy in killing up to 99.9% of bacterial cells.

AB - Biofilm is a major cause of infections and infrastructure deterioration, largely due to molecular diffusion restrictions that hamper the antimicrobial activity of traditional antibiotics and disinfectants. Here, we present a self-locomotive, antimicrobial microrobot (SLAM) swarm that can penetrate, fracture, and detach biofilm and, in turn, nullify bacterial resistance to antibiotics. The SLAM is assembled by loading a controlled mass of manganese oxide nanosheets on diatoms with the polydopamine binder. In hydrogen peroxide solution, SLAMs produce oxygen bubbles that generate thrust to penetrate the rigid and dense Pseudomonas aeruginosa biofilm and self-assemble into a swarm that repeatedly surrounds, expands, and bursts oxygen bubbles. The resulting cavities continue to deform and fracture extracellular polymeric substances from microgrooved silicone substrates and wounded skin explants while decreasing the number of viable bacterial cells. Additionally, SLAM allows irrigating water or antibiotics to access the residual biofilm better, thus enhancing the synergistic efficacy in killing up to 99.9% of bacterial cells.

KW - Bubble

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KW - Wound

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JO - Biomaterials

JF - Biomaterials

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ER -

Self-locomotive, antimicrobial microrobot (SLAM) swarm for enhanced biofilm elimination

Abstract

Keywords

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