Disclosed herein are compositions and methods for labeling cells using click chemistry reagents. The compositions and methods disclosed herein provide a specific and efficient means of localizing desired agents to a variety of cell types in vivo and in vitro.

An antibody specifically binding to IL-17A or a functional fragment thereof. The antibody or functional fragment thereof includes an IL-17A chimeric antibody and a functional fragment thereof, and an IL-17A humanized antibody and a functional fragment thereof.

Provided is a mitochondrial copper depleting strategy that exploits the potential vulnerability for this metabolic by cancer cells such as Triple Negative Breast Cancer cells. A nanoparticle is provided that comprises a self-reporting copper-depleting moiety (CDM) embedded in or on the matrix comprising a semi-conducting polymer and a phospholipid-polyethylene glycol (PEG). The positively charged copper-depleting complex targets mitochondria and deprives cytochrome c oxidase of its necessary copper co-factor. Inhibition of the electron transport chain complex IV compromises oxygen consumption and abrogates fatty acid oxidation, resulting in energy deficiency induced apoptosis of the targeted cancer cells. The copper-depleting nanoparticle can report the copper depleting status through multimodal optical signal changes while decreasing the copper level in tumors to inhibit tumor growth with low toxicity and significantly prolonged survival.

The present invention relates to the use of binding equivalents of monoclonal antibody 31.1, including chimerized and/or humanized versions thereof, antibody fragments as well as competitively binding and co-specific antibodies and antibody fragments, in the treatment of pancreatic cancer.

Provided herein are novel compositions comprising anti-DEspR antibodies and fragments thereof, including fully human, composite engineered human, humanized, monoclonal, and polyclonal anto-DEspR antibodies and fragments thereof, and methods of their use in a variety of therapeutic applications. The compositions comprising the anti-DEspR antibodies and fragments thereof described herein are useful in diagnostic and imaging methods, such as DEspR-targeted molecular imaging of angiogenesis, and for companion diagnostic and/or in vivo-non invasive imaging and/or assessments.

Acoustically responsive stabilized microbubbles formulated with a phospholipid monolayer shell, an encapsulated bioactive gas, and an encapsulated perfluorocarbon gas of the formula C.sub.xF.sub.y in a volume ratio of from about 10:1 to about 1:10, wherein X is greater than or equal to 3, are disclosed. Also provided are methods for promoting localized vasodilation in a patient in need thereof by delivering a microbubble comprising a phospholipid monolayer shell and an encapsulated bioactive gas locally to a target diseased section of the patient's vasculature; and releasing the bioactive gas at the target diseased section, wherein the microbubble comprises the bioactive gas in a ratio of from about 10:1 to about 1:10 by volume with a perfluorocarbon gas.

Compositions and methods for detection and diagnosis of pancreatic cancer are disclosed. An engineered anti-thymocyte differentiation antigen 1 (Thy1) single-chain antibody and bioconjugates thereof can be used for detecting and diagnosing pancreatic adenocarcinoma. The anti-Thy1 single-chain antibody selectively binds to the Thy1 antigen, which is overexpressed on pancreatic tumor neovasculature and precancerous lesions, and is capable of detecting pancreatic cancer even at the earliest stages of the disease. Thy1-targeted diagnostic agents can be produced by conjugation of the anti-Thy1 single-chain antibody to various diagnostic agents, such as contrast agents, photoactive agents, or detectable labels that are useful for detection and medical imaging of pancreatic tumors.

The current inventive technology includes system, methods and compositions for the generation of a cloaked microbubble having buried-ligand architecture (BLA) that may allow the cloaked microbubble to circumvent potentially deleterious immunogenic, or other unwanted chemical responses in a host. The current inventive technology may also includes systems and methods to isolate monodisperse size populations of microbubbles for enhanced therapeutic and diagnostic applications.

A method, device and system for ultrasonic delivery and attachment of ligand-receptor based drugs and/or drug carriers and/or image enhancing contrast agents utilizing catch and slip bond mechanisms in a targeted part(s) of the human or animal (patient) body or organs or tissue is described and disclosed. The system includes an acoustic power source coupled to an acoustic transducer with the acoustic transducer placed upon a patient's delivery zone. The acoustic transducer transmits an acoustic field to the target drug delivery and/or imaging zone. A detection probe and/or a probe of an imaging system are placed over or within said delivery zone and the probe is coupled to a sensing/imaging system. A control computer that controls power and wave shape of the acoustic signal generated into the acoustic filed by the acoustic power source and receives data from the sensing/imaging system. This system utilizes catch and slip bonds for the delivery of drugs and/or drug carriers and/or image enhancing contrast agents. Placing an acoustic transducer over a delivery zone having ligand-receptor based drugs and/or drug carriers and/or image enhancing contrast agents. The method includes coupling an acoustic power source to said acoustic power source and installing a probe within or over said delivery zone. The probe is coupled to a sensing/imaging system. A control computer is used to control a power and a wave shape of the acoustic field generated by said acoustic transducer. The method uses a catch and slip bonds within said acoustic field to deliver ligand-receptor based drugs and/or drug carriers and/or image enhancing contrast.

Provided is a bilirubin derivative-based ultrasound contrast agent for diagnosis and treatment. The fine particles including the bilirubin derivative are sensitive to reactive oxygen species (ROS), bind with hydrophobic drugs, and can effectively chelate metals such as iron oxide nanoparticles. Therefore, the fine particle of the present invention can be used as an ultrasound contrast agent for diagnosis, as a magnetic resonance imaging contrast agent, or as a carrier for hydrophobic drugs or platinum-based drugs.