This emerging variability of morphology of TDMCs is now attracting interest due to their high surface areas and edge reactivity. The high density of edges with dangling bonds underscores their ability to be readily functionalized with NPs and molecules. In addition, S and Se termination of the basal plane and edges can be particularly favorable to anchor biologically relevant molecules. Nanoflowers of TMDCs present attracting properties in nanomedicine applications because they could host a large number of molecules and NPs on their edges and thus can develop abilities to detect and to inactivate pathogens, to deliver molecules, and to interfere with cellular functioning.220 Their stability in air and their availability as free-standing nanomaterials in addition to their strong substrate anchoring make them suitable for use in different environments such as in aerosols, on surfaces, in face masks, etc., to detect and/or to inactivate the virus.