Abstract: The present invention relates to intraoperative fluorescent imaging (IFI) used both pre-clinically using in-vivo models, as well as clinically to map sentinel lymph nodes in breast cancer, skin cancer, GI cancer, lung cancer, prostate cancer and several other cancers. IFI can be used to image solid tumors both non-specifically in hepatobiliary and breast cancers as well as in prostate and ovarian cancer. In one embodiment, two-dimensional resolution to 10 ?m2 is possible with optical imaging, significantly higher than other imaging modalities. In one embodiment, the present invention relates to a series of self-assembled nanoparticles using HLA (hyaluronic acid) as both a polymeric backbone as well as targeting ligand. In some embodiments, the present invention relates to the synthesis of HLA conjugates, and the effect of variation of the hydrophobic ligand structure and conjugation level on nanoparticle self-assembly, size, ICG loading efficiency, and ICG fluorescence quenching and reactivation.

Abstract: According to one aspect, a system for intraoperatively providing anatomical guidance in a diagnostic or therapeutic procedure is disclosed. In one embodiment, the system includes: a first light source configured to emit a beam of visible light; second light source configured to emit a beam of near-infrared light; a handheld probe optically coupled to the second light source; a second imaging device configured to detect visible light; a third imaging device configured to detect near-infrared light having a first predetermined wavelength; a fourth imaging device configured to detect near-infrared light having a second predetermined wavelength; a display for displaying at least one visual representation of data; and, a controller programmed to generate at least one real-time integrated visual representation of an area of interest and to display the real-time visual representation on the display for guidance during the diagnostic or therapeutic procedure.

Abstract: According to one aspect, a system for intraoperatively providing anatomical guidance in a diagnostic or therapeutic procedure is disclosed. In one embodiment, the system includes: a first light source configured to emit a beam of visible light; second light source configured to emit a beam of near-infrared light; a handheld probe optically coupled to the second light source; a second imaging device configured to detect visible light; a third imaging device configured to detect near-infrared light having a first predetermined wavelength; a fourth imaging device configured to detect near-infrared light having a second predetermined wavelength; a display for displaying at least one visual representation of data; and, a controller programmed to generate at least one real-time integrated visual representation of an area of interest and to display the real-time visual representation on the display for guidance during the diagnostic or therapeutic procedure.

Abstract: According to one aspect, a system for intraoperatively providing anatomical guidance in a diagnostic or therapeutic procedure is disclosed. In one embodiment, the system includes: a first light source configured to emit a beam of visible light; second light source configured to emit a beam of near-infrared light; a handheld probe optically coupled to the second light source; a second imaging device configured to detect visible light; a third imaging device configured to detect near-infrared light having a first predetermined wavelength; a fourth imaging device configured to detect near-infrared light having a second predetermined wavelength; a display for displaying at least one visual representation of data; and, a controller programmed to generate at least one real-time integrated visual representation of an area of interest and to display the real-time visual representation on the display for guidance during the diagnostic or therapeutic procedure.