Abstract: The present disclosure comprises graphene quantum dots that exhibit emission in the near-infrared region in response to a variety of excitation wavelengths. The exciting wavelengths may be in the visible region, near-infrared region, or both. The quantum dots may be synthesized via a top-down method or a bottom-up method. The quantum dots are useful in imaging, drug delivery, and biosensing. The quantum dots comprise carbon, oxygen, hydrogen, nitrogen, and metal atoms in various combinations.

Abstract: The present disclosure comprises graphene quantum dots that exhibit emission in the near-infrared region in response to a variety of excitation wavelengths. The exciting wavelengths may be in the visible region, near-infrared region, or both. The quantum dots may be synthesized via a top-down method or a bottom-up method. The quantum dots are useful in imaging, drug delivery, and biosensing. The quantum dots comprise carbon, oxygen, hydrogen, nitrogen, and metal atoms in various combinations.

Abstract: A new route is shown for antibiotic delivery in fighting drug resistant infections. Nanotubes and antibiotics and complexed non-covalently, with no chemical bonding, but through adsorption of antibiotics onto the nanotube surface governed by sufficiently strong molecular attraction between hydrophobic systems of the two. This allows the antibiotics to be freed from the nanotubes more easily as they reach the cell membrane. When antibiotics are introduced with nanotubes in this manner, bacterial resistance is mitigated by nanotube transport potentially into the membrane of the bacteria. Nanotubes used in this way help to overcome antibiotic resistance.

Abstract: A new route is shown for at delivery in fighting drug resistant infections. Nanotubes and antibiotics and complexed non-covalently, with no chemical bonding, but through adsorption of antibiotics onto the nanotube surface governed by sufficiently strong molecular attraction between hydrophobic systems of the two. This allows the antibiotics to be freed from the nanotubes more easily as they reach the cell membrane. When antibiotics are introduced with nanotubes in this manner, bacterial resistance is mitigated by nanotube transport potentially into the membrane of the bacteria. Nanotubes used in this way help to overcome antibiotic resistance.

Abstract: A new route is shown for at delivery in fighting drug resistant infections. Nanotubes and antibiotics and complexed non-covalently, with no chemical bonding, but through adsorption of antibiotics onto the nanotube surface governed by sufficiently strong molecular attraction between hydrophobic systems of the two. This allows the antibiotics to be freed from the nanotubes more easily as they reach the cell membrane. When antibiotics are introduced with nanotubes in this manner, bacterial resistance is mitigated by nanotube transport potentially into the membrane of the bacteria.