Carbon-based antiviral nanomaterials: graphene, C-dots, and fullerenes. A perspective

Innocenzi, Plinio; Stagi, Luigi

doi:10.1039/d0sc02658a

Cited by 194 publications

(151 citation statements)

References 113 publications

(147 reference statements)

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“…Molecular dynamics simulations were also utilized to explore the interactions between graphene and the Ebola virus protein VP40, showing that the graphene sheets could recognize and destroy the hydrophobic protein-protein interactions in VP40 ( Pokhrel et al, 2017 ). In addition to their direct action on viruses, GO can improve their ability to inhibit viral activity by self-assembling AgNPs ( Du et al, 2018 ) or by mimicking cell surface receptors through surface functionalization ( Donskyi et al, 2019 ; Innocenzi and Stagi, 2020 ; Yang et al, 2017 ). Although the current level of knowledge is not sufficient to directly apply graphene to antiviral applications, it is anticipated that graphene will play an important role in the global fight against COVID-19 by being used in medical devices, personal protective equipment or mask coatings to minimize the risk of transmission ( Palmieri and Papi, 2020 ).…”

Section: Graphenementioning

confidence: 99%

Graphene biosensors for bacterial and viral pathogens

Jiang

Feng

et al. 2020

Biosensors and Bioelectronics

131

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: The infection and spread of pathogens (e.g., COVID-19) pose an enormous threat to the safety of human beings and animals all over the world. The rapid and accurate monitoring and determination of pathogens are of great significance to clinical diagnosis, food safety and environmental evaluation. In recent years, with the evolution of nanotechnology, nano-sized graphene and graphene derivatives have been frequently introduced into the construction of biosensors due to their unique physicochemical properties and biocompatibility. The combination of biomolecules with specific recognition capabilities and graphene materials provides a promising strategy to construct more stable and sensitive biosensors for the detection of pathogens. This review tracks the development of graphene biosensors for the detection of bacterial and viral pathogens, mainly including the preparation of graphene biosensors and their working mechanism. The challenges involved in this field have been discussed, and the perspective for further development has been put forward, aiming to promote the development of pathogens sensing and the contribution to epidemic prevention.

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Section: Graphenementioning

confidence: 99%

Graphene biosensors for bacterial and viral pathogens

Jiang

Feng

et al. 2020

Biosensors and Bioelectronics

131

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“…However, their mechanical strength and stability are low. On the contrary, carbon-based nanomaterials provide mechanically strong and flexible, electrically and thermally conductive assets in addition to biocompatibility and antiviral properties [ 20 , 63 ]. Considering electroanalytical performance and immobilization of recognition elements, current biosensor platforms mostly integrates diverse nanomaterials [ 65 , 66 ] stemmed from carbonaceous materials (e.g., carbon nanotubes [ 67 ], graphene [ 68 – 71 ], carbon nanoparticles [ 72 ]), inorganic materials (e.g., magnetic and metal nanoparticles [ 73 ]), organic nanoparticles (e.g., dendrimers [ 74 ]) conductive and insulating polymers (e.g., nanosized and nanostructured polymers or molecularly imprinted polymers [ 75 ]), and hybrid materials (e.g., hydrogel [ 76 ]).…”

Section: Smart Materials For Sensor Technologiesmentioning

confidence: 99%

Smart materials-integrated sensor technologies for COVID-19 diagnosis

et al. 2021

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After the first case has appeared in China, the COVID-19 pandemic continues to pose an omnipresent threat to global health, affecting more than 70 million patients and leading to around 1.6 million deaths. To implement rapid and effective clinical management, early diagnosis is the mainstay. Today, real-time reverse transcriptase (RT)-PCR test is the major diagnostic practice as a gold standard method for accurate diagnosis of this disease. On the other side, serological assays are easy to be implemented for the disease screening. Considering the limitations of today's tests including lengthy assay time, cost, the need for skilled personnel, and specialized infrastructure, both strategies, however, have impediments to be applied to the resource-scarce settings. Therefore, there is an urgent need to democratize all these practices to be applicable across the globe, specifically to the locations comprising of very limited infrastructure. In this regard, sensor systems have been utilized in clinical diagnostics largely, holding great potential to have pivotal roles as an alternative or complementary options to these current tests, providing crucial fashions such as being suitable for point-of-care settings, cost-effective, and having short turnover time. In particular, the integration of smart materials into sensor technologies leverages their analytical performances, including sensitivity, linear dynamic range, and specificity. Herein, we comprehensively review major smart materials such as nanomaterials, photosensitive materials, electrically sensitive materials, their integration with sensor platforms, and applications as wearable tools within the scope of the COVID-19 diagnosis.

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“…Nanotechnology has tremendous potential in different areas to fight against COVID-19, which include diagnosis, prevention as well as treatment. The application of nanotechnology in antiviral therapy is still in its early stages (Borah et al, 2020;Chen and Liang, 2020;Innocenzi and Stagi, 2020;Palmieri and Papi, 2020). Constant emergences of novel viruses are challenging and need more attention in research on nanotechnology-based targeted antiviral therapy.…”

Section: Graphical Abstract |mentioning

confidence: 99%

“…A recent review by Basak et al, also gives the potential of carbon dots against viral infections briefly along with some other potential nanomaterials (Basak and Packirisamy, 2020). A large number of reviews are published recently mentioning the potential and possibilities of nanomaterials to fight against corona virus (Innocenzi and Stagi, 2020;Manivannan and Ponnuchamy, 2020;Mukherjee et al, 2020;Nair et al, 2020). But our review focus on the possibility of carbon dots and also functionalized or doped carbon dots against viral infection with special emphasis to corona virus.…”

Section: Graphical Abstract |mentioning

confidence: 99%

Exploring the Potential of Carbon Dots to Combat COVID-19

Aldawsari

Badr-Eldin

Alhakamy

et al. 2020

Front. Mol. Biosci.

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Viral diseases are considered as a global burden. The eradication of viral diseases is always a challenging task in medical research due to the high infectivity and mutation capability of the virus. The ongoing COVID-19 pandemic is still not under control even after several months of the first reported case and global spread. Neither a specific drug nor a vaccine is available for public use yet. In the pursuit of a promising strategy, carbon dots could be considered as potential nanostructure against this viral pandemic. This review explores the possibility of carbon nano-dots to combat COVID-19 based on some reported studies. Carbon dots are photoluminescent carbon nanoparticles, smaller than 10 nm in dimension with a very attractive photostable and biocompatible properties which can be surfaced modified or functionalized. These photoluminescent tiny particles have captured much attention owing to their functionalization property and biocompatibility. In response to this pandemic outbreak, this review attempts to summarize the potential use of carbon dots in antiviral therapy with particular emphasis on their probable role in the battlefront against COVID-19 including their possible biosensing applications.

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Carbon-based antiviral nanomaterials: graphene, C-dots, and fullerenes. A perspective

Abstract:
The appearance of new and lethal viruses and their potential threat urgently requires innovative antiviral systems.

Cited by 194 publications

References 113 publications

Graphene biosensors for bacterial and viral pathogens

Graphene biosensors for bacterial and viral pathogens

Smart materials-integrated sensor technologies for COVID-19 diagnosis

Exploring the Potential of Carbon Dots to Combat COVID-19

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Carbon-based antiviral nanomaterials: graphene, C-dots, and fullerenes. A perspective

Abstract: The appearance of new and lethal viruses and their potential threat urgently requires innovative antiviral systems.

Cited by 194 publications

References 113 publications

Graphene biosensors for bacterial and viral pathogens

Graphene biosensors for bacterial and viral pathogens

Smart materials-integrated sensor technologies for COVID-19 diagnosis

Exploring the Potential of Carbon Dots to Combat COVID-19

Contact Info

Product

Resources

About

Abstract:
The appearance of new and lethal viruses and their potential threat urgently requires innovative antiviral systems.