Recent advances in ultra-small fluorescent Au nanoclusters toward oncological research

Au nanoclusters possess a series of excellent properties owing to their size being comparable to the Fermi wavelength of electrons. For example, they show excellent biocompatibility, optical stability, large Stokes shift, intense size-dependent emission and monodispersion, and thus could effectively...

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Published in	Nanoscale Vol. 11; no. 39; pp. 17967 - 1798
Main Authors	Yang, Jingjing, Wang, Fenglong, Yuan, Huiqing, Zhang, Lishu, Jiang, Yanyan, Zhang, Xue, Liu, Chao, Chai, Li, Li, Hui, Stenzel, Martina
Format	Journal Article
Language	English
Published	England Royal Society of Chemistry 10.10.2019
Subjects	Biocompatibility Drug delivery systems Fluorescent dyes Fluorescent Dyes - chemistry Fluorescent Dyes - therapeutic use Gold - chemistry Gold - therapeutic use Humans Metal Nanoparticles - chemistry Metal Nanoparticles - therapeutic use Nanoclusters Neoplasms - metabolism Neoplasms - pathology Neoplasms - therapy Optical properties Photodynamic therapy Portraits as Topic Radiation therapy
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Abstract	Au nanoclusters possess a series of excellent properties owing to their size being comparable to the Fermi wavelength of electrons. For example, they show excellent biocompatibility, optical stability, large Stokes shift, intense size-dependent emission and monodispersion, and thus could effectively compensate for the shortcomings of traditional organic fluorescent dyes and fluorescent quantum. In this review, we detail the latest developments of Au nanoclusters employed in the field of biomedicine, especially in oncology research, by summarizing the application of imaging, sensing and drug delivery based on their excellent luminescent properties and unique structural features. We also discuss the significant work relating to Au NCs that now is being devoted in other therapeutic strategies, such as radiotherapy, photothermal therapy and photodynamic therapy, for example. It is anticipated that this review will provide new insights and theoretical guidance to allow the advantages of Au nanoclusters to be realized in oncotherapy. The structure, properties of gold nanoclusters and their applications in targeting anti-cancer fields have been reviewed.
AbstractList	Au nanoclusters possess a series of excellent properties owing to their size being comparable to the Fermi wavelength of electrons. For example, they show excellent biocompatibility, optical stability, large Stokes shift, intense size-dependent emission and monodispersion, and thus could effectively compensate for the shortcomings of traditional organic fluorescent dyes and fluorescent quantum. In this review, we detail the latest developments of Au nanoclusters employed in the field of biomedicine, especially in oncology research, by summarizing the application of imaging, sensing and drug delivery based on their excellent luminescent properties and unique structural features. We also discuss the significant work relating to Au NCs that now is being devoted in other therapeutic strategies, such as radiotherapy, photothermal therapy and photodynamic therapy, for example. It is anticipated that this review will provide new insights and theoretical guidance to allow the advantages of Au nanoclusters to be realized in oncotherapy. Au nanoclusters possess a series of excellent properties owing to their size being comparable to the Fermi wavelength of electrons. For example, they show excellent biocompatibility, optical stability, large Stokes shift, intense size-dependent emission and monodispersion, and thus could effectively compensate for the shortcomings of traditional organic fluorescent dyes and fluorescent quantum. In this review, we detail the latest developments of Au nanoclusters employed in the field of biomedicine, especially in oncology research, by summarizing the application of imaging, sensing and drug delivery based on their excellent luminescent properties and unique structural features. We also discuss the significant work relating to Au NCs that now is being devoted in other therapeutic strategies, such as radiotherapy, photothermal therapy and photodynamic therapy, for example. It is anticipated that this review will provide new insights and theoretical guidance to allow the advantages of Au nanoclusters to be realized in oncotherapy. The structure, properties of gold nanoclusters and their applications in targeting anti-cancer fields have been reviewed. Au nanoclusters possess a series of excellent properties owing to their size being comparable to the Fermi wavelength of electrons. For example, they show excellent biocompatibility, optical stability, large Stokes shift, intense size-dependent emission and monodispersion, and thus could effectively compensate for the shortcomings of traditional organic fluorescent dyes and fluorescent quantum. In this review, we detail the latest developments of Au nanoclusters employed in the field of biomedicine, especially in oncology research, by summarizing the application of imaging, sensing and drug delivery based on their excellent luminescent properties and unique structural features. We also discuss the significant work relating to Au NCs that now is being devoted in other therapeutic strategies, such as radiotherapy, photothermal therapy and photodynamic therapy, for example. It is anticipated that this review will provide new insights and theoretical guidance to allow the advantages of Au nanoclusters to be realized in oncotherapy.Au nanoclusters possess a series of excellent properties owing to their size being comparable to the Fermi wavelength of electrons. For example, they show excellent biocompatibility, optical stability, large Stokes shift, intense size-dependent emission and monodispersion, and thus could effectively compensate for the shortcomings of traditional organic fluorescent dyes and fluorescent quantum. In this review, we detail the latest developments of Au nanoclusters employed in the field of biomedicine, especially in oncology research, by summarizing the application of imaging, sensing and drug delivery based on their excellent luminescent properties and unique structural features. We also discuss the significant work relating to Au NCs that now is being devoted in other therapeutic strategies, such as radiotherapy, photothermal therapy and photodynamic therapy, for example. It is anticipated that this review will provide new insights and theoretical guidance to allow the advantages of Au nanoclusters to be realized in oncotherapy.
Author	Yuan, Huiqing Liu, Chao Zhang, Xue Stenzel, Martina Chai, Li Li, Hui Yang, Jingjing Zhang, Lishu Wang, Fenglong Jiang, Yanyan
AuthorAffiliation	Ministry of Education the Second Hospital of Shandong University Key Laboratory for Liquid-Solid Structural Evolution and Processing of Materials Institute of Medical Sciences Shandong University University of New South Wales Department of Stomatology Shandong Provincial Hospital Affiliated to Shandong University Centre for Advanced Macromolecular Design (CAMD) School of Chemistry
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BackLink	https://www.ncbi.nlm.nih.gov/pubmed/31355833$$D View this record in MEDLINE/PubMed
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Notes	Fenglong Wang gained his PhD in chemical engineering under the supervision of Professor Rose Amal and Dr Yijiao Jiang at the University of New South Wales, Australia. Afterwards, he worked as a specific researcher at Kyoto University within Professor Hiroshi Kitagawa's group from 2016 to 2018. He started his independent career as a professor of materials science at Shandong University in April 2018. His research interests are nanomaterials for solar energy conversion and environmental remediation applications. Chao Liu completed her PhD at Shandong University in 2015 and is now working as a postdoc fellow at Shanghai Jiaotong University. She worked in Ying Xu's laboratory in Georgia University in the US from 2013 to 2015. Her research interests are the mechanism of cancer development, biomarkers of early cancer, and new treatments for cancers. Hui Li received his PhD in 1999 from Shandong University. He then carried out his postdoctoral research in Nanjing University (1999) and University of Trento (2002). He has been promoted to full professor since 2005 in the School of Materials Science and Engineering at Shandong University. He has also been appointed as a Taishan Scholar by Shandong Province since 2013. His research interests are in the areas of wetting transformation of novel 2D materials, synthesis of low expansion alloy and refractory alloys and design of nano-electronic devices. Martina Stenzel studied chemistry at the University of Bayreuth, Germany, before completing her PhD in 1999 at the University of Stuttgart, Germany. She started as a postdoctoral fellow at UNSW in 2000 and is now a full professor. Her research interest is focused on the synthesis of functional polymers with complex architectures such as glycopolymers and other polymers for biomedical applications, especially polymers with in-built metal complexes for the delivery of metal-based anti-cancer drugs. She is a fellow of the Australian Academy of Science and currently the chair of the National Chemistry Committee. Jingjing Yang is currently pursuing a master's degree within the School of Materials Science and Engineering at Shandong University under the supervision of Professor Yanyan Jiang. She is conducting research on the synthesis of metal nanoparticles and clusters for targeting anti-cancer applications. Yanyan Jiang completed her PhD in Professor Martina Stenzel's group, School of Chemical Engineering at the University of New South Wales, Australia in 2016. She was awarded (2016) Japan Society for Promotion of Science (JSPS) Postdoctoral Research Fellowship at Kyoto University under the supervision of Professor Itaru Hamachi. Since 2018, she has been appointed as a full professor of materials science and engineering at Shandong University. Her research interests are in the synthesis of functional nanoparticles serving as anti-cancer drug carriers, biosensors, catalysts, and theoretical studies of the mechanism and properties of these nanoparticles. ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 14 ObjectType-Review-3 content type line 23
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Snippet	Au nanoclusters possess a series of excellent properties owing to their size being comparable to the Fermi wavelength of electrons. For example, they show...
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SubjectTerms	Biocompatibility Drug delivery systems Fluorescent dyes Fluorescent Dyes - chemistry Fluorescent Dyes - therapeutic use Gold - chemistry Gold - therapeutic use Humans Metal Nanoparticles - chemistry Metal Nanoparticles - therapeutic use Nanoclusters Neoplasms - metabolism Neoplasms - pathology Neoplasms - therapy Optical properties Photodynamic therapy Portraits as Topic Radiation therapy
Title	Recent advances in ultra-small fluorescent Au nanoclusters toward oncological research
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