Abstract: Heme released as a result of sustained injury leads to toxicity and triggers an inflammatory response and tissue damage. Heme oxygenase, an enzyme, recognizes, binds free heme and breaks it down as a part of the anti-inflammatory response. The present disclosure relates to a class of peptide amphiphiles that mimic the heme oxygenase function, and have shown that the designed peptide is able to bind and break down heme thus validating its potential as an anti-inflammatory agent that promotes tissue repair and useful in wound healing. The disclosed peptide sequence design provides control of amphiphile peptides' supramolecular structure and function. Applicants have shown that the incorporated heme molecule can transport CO, which suggests that the peptides can also transport NO, O2 and reactive oxygens, the molecules which are responsible for vasodilation, neurotransmission and cell death.

Abstract: A nanostructure comprises a MOX NP and a bidentate ligand on a surface of the MOX NP. A cancer recognition molecule is covalent coupled to the surface of the MOX NP via the bidentate ligand. A biocatalyst is also coupled to the surface of the MOX nanoparticle via the bidentate ligand. The cancer recognition molecule includes a structure configured to selectively recognize a corresponding antigen on a surface of a cancer cell and bind to the antigen. The biocatalyst is structured to selectively catalyze the oxidation of a light emitting compound to produce photons. The photons transform the MOX NPs into an excited state such that the MOX NPs generate reactive oxygen species (ROS) in the vicinity of the cancer cells in the excited state. The reactive oxygen species lyse or cause apoptosis in the cancer cells in situ. The biocatalyst includes luciferase and the light emitting compound includes luciferin.

Abstract: A nanostructure comprises a MOX NP and a bidentate ligand on a surface of the MOX NP. A cancer recognition molecule is covalent coupled to the surface of the MOX NP via the bidentate ligand. A biocatalyst is also coupled to the surface of the MOX nanoparticle via the bidentate ligand. The cancer recognition molecule includes a structure configured to selectively recognize a corresponding antigen on a surface of a cancer cell and bind to the antigen. The biocatalyst is structured to selectively catalyze the oxidation of a light emitting compound to produce photons. The photons transform the MOX NPs into an excited state such that the MOX NPs generate reactive oxygen species (ROS) in the vicinity of the cancer cells in the excited state. The reactive oxygen species lyse or cause apoptosis in the cancer cells in situ. The biocatalyst includes luciferase and the light emitting compound includes luciferin.

Abstract: Heme released as a result of sustained injury leads to toxicity and triggers an inflammatory response and tissue damage. Heme oxygenase, an enzyme, recognizes, binds free heme and breaks it down as a part of the anti-inflammatory response. The present disclosure relates to a class of peptide amphiphiles that mimic the heme oxygenase function, and have shown that the designed peptide is able to bind and break down heme thus validating its potential as an anti-inflammatory agent that promotes tissue repair and useful in wound healing. The disclosed peptide sequence design provides control of amphiphile peptides' supramolecular structure and function. Applicants have shown that the incorporated heme molecule can transport CO, which suggests that the peptides can also transport NO, O2 and reactive oxygens, the molecules which are responsible for vasodilation, neurotransmission and cell death.

Abstract: A nanostructure comprises a MOX NP and a bidentate ligand on a surface of the MOX NP. A cancer recognition molecule is covalent coupled to the surface of the MOX NP via the bidentate ligand. A biocatalyst is also coupled to the surface of the MOX nanoparticle via the bidentate ligand. The cancer recognition molecule includes a structure configured to selectively recognize a corresponding antigen on a surface of a cancer cell and bind to the antigen. The biocatalyst is structured to selectively catalyze the oxidation of a light emitting compound to produce photons. The photons transform the MOX NPs into an excited state such that the MOX NPs generate reactive oxygen species (ROS) in the vicinity of the cancer cells in the excited state. The reactive oxygen species lyse or cause apoptosis in the cancer cells in situ. The biocatalyst includes luciferase and the light emitting compound includes luciferin.