Disclosed herein is a pH activated nanoparticle that can be used to deliver labile therapeutic or diagnostic agents to the cytoplasm of cells. These nanoparticles allow the agents to escape the endosome by releasing a gas in an amount effective to disrupt the endosome and release the agents into the cytoplasm. The disclosed nanoparticles have a shell, such as a phospholipid bilayer shell, and a core containing a gas bound to a substrate by a pH sensitive interaction. Also disclosed herein is are methods for delivering a pH sensitive cargo to the cytoplasm of a cell, treating triple negative breast cancer (TNBC) in a subject, and treating HER2+ breast cancer in a subject.

A goggle system is provided. The goggle system includes a computing device, a goggle device configured to be worn by a user and including a detector configured to simultaneously acquire image data of a subject in a first image mode and a second image mode, at least one eye assembly configured to display at least one of an image in the first image mode, an image in the second image mode, and a hybrid image including pixels of image data from the first image mode and pixels of image data from the second image mode, and a communications module configured to transmit acquired image data from the goggle device to the computing device.

A goggle system is provided. The goggle system includes a computing device, a goggle device configured to be worn by a user and including a detector configured to simultaneously acquire image data of a subject in a first image mode and a second image mode, at least one eye assembly configured to display at least one of an image in the first image mode, an image in the second image mode, and a hybrid image including pixels of image data from the first image mode and pixels of image data from the second image mode, and a communications module configured to transmit acquired image data from the goggle device to the computing device.

This invention relates to, in part, methods and compositions that are useful for the diagnosis, treatment, or prevention of a blinding eye disease, including in the discovery of drugs that are efficacious against these diseases. Diseases include, for example, age related macular degeneration and reticular pseudodrusen disease, and the methods described herein include, for example, the method named delayed near infrared analysis (DNIRA).

Methods of imaging described herein comprises disposing a first and second ultrasound-switchable fluorophore in an environment; exposing the environment to an ultrasound beam to create an activation region; disposing the first and/or second fluorophore within the activation region to switch the first and/or second fluorophore from an off state to an on state; exposing the environment to a beam of electromagnetic radiation; detecting a first photoluminescence signal at a first location within the environment, the photoluminescence signal comprising at least one of a first ultrasound fluorescence signal emitted by the first fluorophore, a first fluorescence signal emitted by the second fluorophore, and a background signal; correlating the first photoluminescence signal with a first reference signal to generate a correlation coefficient for the first location; and multiplying the first photoluminescence signal by the first correlation coefficient for the first location to generate a first modified photoluminescence signal for the first location.

The development of a new, targeted drug delivery paradigm coupled to improved PI3K inhibitors (e.g., PI3Kα inhibitors) represents a significant advance in cancer therapy. Provided herein are compounds, such as compounds of Formula (I) and (II), and pharmaceutically acceptable salts, hydrates, solvates, polymorphs, co-crystals, tautomers, stereoisomers, isotopically labeled derivatives, and prodrugs thereof. The compounds provided herein are PI3K (e.g., PI3Kα) inhibitors and are therefore useful for the treatment and/or prevention of various diseases (e.g., proliferative diseases such as cancer). Also provided herein are nanoparticles and nanogels (e.g., P-selectin targeting nanoparticles) comprising PI3K inhibitors, such a compound described herein. In certain embodiments, a nanoparticle or nanogel described herein encapsulates a compound described herein for targeting delivery to cancer cells or tumors.

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The present invention provides a cyanine modified telodendrimer, nanoparticles thereof, and methods of using the nanoparticles to treat various diseases such as cancer.

A fusogenic liposome comprising a detectable agent and optionally a cytotoxic drug in its internal aqueous compartment or bound to the liposome membrane is provided, wherein said fusogenic liposome comprises a lipid bilayer comprising a plurality of lipid molecules having 14 to 24 carbon atoms, and at least one of said lipid molecules further comprises a cationic group, a cationic natural or synthetic polymer, a cationic amino sugar, a cationic polyamino acid or an amphiphilic cancer-cell binding peptide; and at least one of said lipid molecules further comprises a stabilizing moiety selected from the group consisting of polyethylene glycol (PEG), polypropylene glycol, polyvinyl alcohol, polyvinylpyrrolidone (PVP), dextran, a polyamino acid, methyl-polyoxazoline, polyglycerol, poly(acryloyl morpholine), and polyacrylamide. Methods utilizing these liposomes in treatment of cancer are further provided.

A mouthwash for fluorescence endoscopic dental imaging includes at least one fluorescent dye and a liquid base. A method for fluorescent endoscopic dental imaging includes orally administering a mouthwash to a subject; waiting a predetermined period of time; removing excess mouthwash from the subject; illuminating the subject with visible or near-infrared light; and capturing fluorescent light from the subject to create an image.

The present invention relates to contrast agent enhanced medical ultrasound imaging. In particular, the contrast agents provided are useful for cell imaging and cell therapy, as well as in vivo targeting, drug delivery and perfusion or vascular imaging applications. More specifically, it provides a particle comprising a fluorinated organic compound and a metal. Such particles may be advantageously employed in qualitative or quantitative imaging such as acoustic imaging including photoacoustic and ultrasound imaging, MRI imaging, such as 19F imaging, 1H imaging including T1 and T2 weighted imaging, SPECT, PET, scintigraphy, fluorescence imaging and optical coherence imaging and tomographic applications. This may then be employed in cell labeling, microscopy, histology or for imaging vasculature or perfusion in vivo and in vitro.