Transformable liquid-metal nanomedicine

Lü, Yue; Hu, Quanyin; Lin, Yiliang; Pacardo, Dennis B.; Wang, Chao; Sun, Wujin; Ligler, Frances S.; Dickey, Michael D.; Gu, Zhen

doi:10.1038/ncomms10066

Cited by 552 publications

(660 citation statements)

References 35 publications

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“…Chemical passivation is an intrinsic property of Ga that enables Ga and Ga-based alloys to be used as dielectrics, although it also hinders their general use as liquid conductors. The surfaces of pure Ga or eutectic Ga-based alloys are easily oxidised and form an amorphous Ga oxide layer in the ambient environment that decreases the surface tension of the liquid metal [11][12][13]. The thickness of the intrinsically formed Ga oxide surface layer is 0.5-3 nm [14][15][16].…”

Section: Introductionmentioning

confidence: 97%

“…These approaches are limited by certain factors, however, such as toxicity and lack of biodegradability [12]. Lu et al reported a method to use Ga-based liquid metal nanoparticles for drug delivery, owing to the low toxicity of Ga and its alloys [12,104]. They use EGaIn-based drug nanocarriers that are assembled with thiolated ligands on the surfaces of these nanoparticles through ultrasonication around room temperature.…”

Section: Drug Deliverymentioning

confidence: 99%

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Recent progress on liquid metals and their applications

Ren

et al. 2018

Advances in Physics: X

107

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Gallium-based liquid metals show excellent thermal and electrical conductivities with low viscosity and non-toxicity. Their melting points are either lower than or close to room temperature, which endows them with additional advantages in comparison to the solid metals; for example, they are flexible, stretchable and reformable at room temperature. Recently, great improvements have been achieved in developing multifunctional devices by using Ga-based liquid metals, including actuators, flexible circuits, bio-devices and self-healing superconductors. Here, we review recent research progress on Gallium-based liquid metals, especially on the applications aspects. These applications are mainly based on the unique properties of liquid metals, including low melting point, flexible and stretchable mechanical properties, excellent electrical and thermal conductivities and biocompatibility.

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Section: Introductionmentioning

confidence: 97%

Section: Drug Deliverymentioning

confidence: 99%

Recent progress on liquid metals and their applications

Ren

et al. 2018

Advances in Physics: X

107

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“…Terminating Cancer with LiquidMetal-Based Drug Delivery Systems 10 While the use of inorganic nanomaterials in drug delivery remains an area of active research in nanomedicine, clinical translation of inorganic material-based drug delivery systems has been difficult due to their toxicity and clearance failures. A promising new approach that overcomes these hurdles was developed by Zhen Gu and his team at the University of North Carolina at Chapel Hill (USA) and North Carolina State University (USA).…”

Section: Slippery Rough Surfaces Inspired By Lotus Leaves and Nepenthmentioning

confidence: 99%

“…[8][9][10] This year's honorees represent the best in research that advances translational science and technology, and we are proud to honor these researchers for their amazing work. JALA and SLAS would like to thank all the nominees as well as those who nominated them.…”

mentioning

confidence: 99%

“…7 Beyond building better biosensors and more effective and cost-efficient devices, work featured this year includes improvements in automation of large-cargo intracellular delivery, as well as innovating the use of inorganic and biomaterials in medical applications. [8][9][10] This year's honorees represent the best in research that advances translational science and technology, and we are proud to honor these researchers for their amazing work. JALA and SLAS would like to thank all the nominees as well as those who nominated them.…”

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confidence: 99%

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Congratulations to the 2016 JALA Ten!

Chow

2016

SLAS Technology

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EditorialOn behalf of the JALA scientific advisors and JALA editorial board, I am happy to present this year's honorees of the prestigious JALA Ten. Each year, JALA seeks to highlight and honor the very best work of the year that will have a deep impact on how technology is used across a wide range of disciplines, including automation, life sciences and biomedical research, diagnostics, drug delivery, and regenerative medicine. Implementing the latest advances in microfluidics, nanotechnology, materials science, and other fields of research, this year's JALA Ten honorees have and will continue to change the way research is performed and the way diseases are diagnosed and treated. As such, the work highlighted here should have far-reaching impact in our everyday lives. It demonstrates the promise that science brings toward a better future.While a number of areas of research will feel the impact of this year's JALA Ten, one highlight of the collection is the diverse ways in which the honorees have advanced biological molecule detection and established foundations for tomorrow's biosensors in life sciences research and medical diagnostics.1-3 For example, Peter Lillehoj at Michigan State University (USA) and his collaborators have developed a microfluidic biosensor using immobilized antimicrobial peptides for highly specific, multiplexed detection of bacterial pathogens.1 Showing both high pathogen detection specificity and accurate pathogen quantification, this work is an example of how microfluidic technology is changing how medical professionals will track and diagnose infectious diseases.On the other end of the spectrum, Somin Eunice Lee at the University of Michigan (USA) has harnessed the power of nanotechnology to develop a gold nanoparticle-based plasmon ruler that is capable of single-molecule measurements.2 Even more impressive is the application of this plasmon ruler toward the accurate detection and measurement of secreted single molecules in the cellular microenvironment. Understanding how cells communicate with their cellular microenvironment remains a challenge to study. Tools such as Lee's plasmon ruler vastly improve life sciences researchers' abilities to learn more about the interplay between cells and their microenvironments.Another area of research highlighted this year is the advancement of technology toward customizable platforms for increased personalized clinical and research applications. [4][5][6][7] The development of tunable injectable microporous gel scaffolds by researchers at the University of California, Los Angeles (USA) not only brings truly personalized medicine to regenerative medicine, but also allows researchers to quickly optimize culture conditions in research and drug development applications that require complex three-dimensional (3D) cell cultures. 4 The development of integrated platforms composed of modular technologies increases the diversity of clinical and research applications to which technology such as microfluidics can be applied and is highlighted here by work f...

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Room‐Temperature Liquid Metals as Functional Liquids

Song

Dickey

2019

Functional Organic Liquids

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Transformable liquid-metal nanomedicine

Cited by 552 publications

References 35 publications

Recent progress on liquid metals and their applications

Recent progress on liquid metals and their applications

Congratulations to the 2016 JALA Ten!

Room‐Temperature Liquid Metals as Functional Liquids

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