Plasmonics-active metal nanostars are provided that can be used for treating and detecting cells in a subject. The modes of treatment include a photo-activated drug, which is activated by the photo-response of the nanostar to electromagnetic stimulation; a thermally-activated drug, which is activated by a thermal response of the nanostar to electromagnetic stimulation; and the thermal response of the nanostar itself to electromagnetic stimulation, which may directly or indirectly cause the death of an undesirable cell. Uptake of nanostars by undesirable cells may also aid in detection, by enhancing contrast or otherwise transforming electromagnetic stimulation during imaging.

Compositions and articles comprising diamond particles, such as nanodiamond based pharmaceutical compositions, are generally provided. In some embodiments, the articles and methods comprising (nano)diamond particles may be useful for monitoring and/or treating a disease (e.g., in a subject).

A tumor-targeting multi-mode imaging and analyzing method for living body based on gold nanoclusters can include incubating the relevant cells with chloroauric acid and the salt solution thereof with certain concentration under physiological conditions, thereby generating gold nanoclusters. After, real-time non-invasive fluorescence imaging, Raman imaging and/or ultrasonic imaging can be used to image the tumor tissue.

A nanocomposite for detection and treatment of a target of interest including tumor cells or pathogens includes at least one nanostructure, each nanostructure having a core and a shell surrounding the core; a reporter assembled on the shell of each nanostructure; and a layer of a treating agent and a targeting agent conjugated to the reporter. In use, the nanocomposite targets to the target of interest according to the targeting agent and releases the treating agent and the nanostructure therein for therapeutic treatment of the target of interest, and the target of interest transmits at least one signature responsive to the reporter for detection of the target of interest.

UV-Laser-synthesized, fluorescent, spherical and magnetic nanoparticles are loaded Sophorolipid mesostructures useful for bio-imaging and therapeutic applications.

A multi-chromophore virus particle is constructed by covalent binding of chromophores and provides super-radiant behavior. A virus-enabled targeted vector is provided for imaging with qualitatively different optical emission properties from state-of-the-art agents. Bright emission is obtained through quantum coherence, which in turn is facilitated by the symmetry of the virus shell. In an exemplary embodiment the targeted vector is used in laser-guided surgery, specifically for the treatment of in brain cancer.

A probe for monitoring new bone formation and osseointegration containing an integrin α5β1 ligand conjugated to a near-infrared fluorescent dye in which the integrin α5β1 ligand is a cyclic peptide lacking an RGD sequence. Also disclosed is a bone repair and osteogenesis-monitoring probe formed of a bisphosphonate conjugated to a gold nanoparticle, the probe having a size of 1 nm to 10 nm. Further disclosed are two methods for monitoring bone formation, each of which is carried out by administering the above probes and obtaining a near-infrared fluorescence image.

A radiotherapy treatment system and method used for conducting radiographic X-ray imaging on a target organ during radiographic treatment. The system comprises (a) an x-ray beam source configurable to deliver an X-ray beam to a target organ, (b) optical means for converging and shaping said beam to a cone-shaped X-ray beam of photons which hit the target organ simultaneously, (c) multiple high-Z nanoparticles attachable to the target organ, said high-Z nanoparticles absorbing said X-ray radiation and emitting X-ray fluorescence (XRF) photons, (d) at least one XRF detector for detecting said XRF photons ejecting out of a patient's body, and (e) control means for controlling the radiotherapy treatment procedure.

The x-ray beam is focusable on a section in the target organ where the concentration of said high-Z nanoparticles leading to a desirable emission of said XRF photons, and in case the emission of said XRF photons decreases, the x-ray beam is movable to refocus on the section in the target organ where the emission of said XRF photons is desirable.

Provided are cubic-phase (α-phase) erbium (Er)-doped near-infrared-II (NIR-II)-emitting nanoparticles. In certain embodiments, the nanoparticles are near-infrared-IIb (NIR-IIb)-emitting nanoparticles. Also provided are nanoparticles having disposed thereon a layer-by-layer crosslinked polymeric hydrophilic biocompatible coating. Also provided are compositions comprising the nanoparticles of the present disclosure. Methods of using the nanoparticles, e.g., for in vivo imaging, are also provided.

Plasmonics-active metal nanostars are provided that can be used for treating and detecting cells in a subject. The modes of treatment include a photo-activated drug, which is activated by the photo-response of the nanostar to electromagnetic stimulation; a thermally-activated drug, which is activated by a thermal response of the nanostar to electromagnetic stimulation; and the thermal response of the nanostar itself to electromagnetic stimulation, which may directly or indirectly cause the death of an undesirable cell. Uptake of nanostars by undesirable cells may also aid in detection, by enhancing contrast or otherwise transforming electromagnetic stimulation during imaging.