Fundamental toxicology studies of 2D transition metal dichalcogenides

Two-dimensional quantum materials have garnered increasing interest in a wide

variety of applications due to their promising optical and electronic properties. These

quantum materials are highly anticipated to make transformative quantum sensors and

biosensors. Biosensors are currently considered among one of the most promising

solutions to a wide variety of biomedical and environmental problems including highly

sensitive and selective detection of difficult pathogens, toxins, and biomolecules.

However, scientists face enormous challenges in achieving these goals with current

technologies. Quantum biosensors can have detection with extraordinary sensitivity and

selectivity through manipulation of their quantum states, offering extraordinary properties

that cannot be attained with traditional materials. These quantum materials are anticipated

to make significant impact in the detection, diagnosis, and treatment of many diseases.

Despite the exciting promise of these cutting-edge technologies, it is largely

unknown what the inherent toxicity and biocompatibility of two-dimensional (2D)

materials are. Studies are greatly needed to lay the foundation for understanding the

interactions between quantum materials and biosystems. This work introduces a new

method to continuously monitor the cell proliferation and toxicity behavior of 2D

materials. The cell viability and toxicity measurements coupled with Live/Dead

fluorescence imaging suggest the biocompatibility of crystalline MoS2 and MoSSe

monolayers and the significantly-reduced cellular growth of defected MoTe2 thin films

and exfoliated MoS2 nanosheets. Results show the exciting potential of incorporating

kinetic cell viability data of 2D materials with other assay tools to further fundamental

understanding of 2D material biocompatibility.