Hydrothermal vs microwave nanoarchitechtonics of carbon dots significantly affects the structure, physicochemical properties, and anti-cancer activity against a specific neuroblastoma cell line

Carbon dots (CDs) from glucose were synthesized using two of the most common bottom-up methods, namely, microwave assisted (MW) and hydrothermal carbonization (HT). Synthetic parameters such as reaction time, temperature, and precursor concentration were changed to study the effects of each parameter on CD size, structure, surface functionalities, charge, photoluminescence behavior, quantum yield, cytotoxicity, blood-brain barrier (BBB) crossing ability and bioimaging. A detailed analysis is per-formed to compare the structure and properties of the CDs synthesized in ten different conditions. We show that the synthesis route drastically changes the structure, properties, and related functions of glucose-derived CDs yielding two different subtypes of CDs. Surprisingly, CDs that was synthesized via HT method showed specific anticancer activity against a neuroblastoma cell line while being non-toxic towards healthy cell lines, indicating significant potential for therapeutic applications. CDs synthesized via MW crosses the BBB in zebrafish and rat models, and accumulates in neurons. CDs synthesized via MW method showed high biocompatibility and a great potential to be used for bioimaging applications in vitro and in vivo targeting neurons. Finally, a formation mechanism of CDs is proposed for both HT and MW synthesis routes. (C) 2022 Elsevier Inc. All rights reserved.

Automated summary

This study synthesized carbon dots using glucose and compared the synthesis results of microwave-assisted and hydrothermal carbonization methods. The research found that the synthesis route has a significant impact on the structure, properties, and functions of carbon dots, and it also discovered the potential of carbon dots for anticancer and blood-brain barrier crossing applications.