Fibrin-targeted microbubbles and their use in ultrasound-based diagnostic and therapeutic applications are disclosed. In particular, the invention relates to the use of fibrin-targeted polymerized shell lipid microbubbles and methods of fabricating and using such fibrin-targeted microbubbles for ultrasound imaging of fibrin deposition in tissue, including adhesions and atherosclerotic plaques. The invention further relates to the use of such fibrin-targeted microbubbles as carriers for drug delivery and in ultrasound-based methods of treatment.

Provided are photoacoustic imaging contrast agents that include at least one radiation-absorbing component comprising a copper-complexed and/or manganese-complexed chlorin and/or bacteriochlorin and/or a derivative thereof, or a combination thereof. Also provided are methods for using the disclosed photoacoustic imaging contrast agents either singly or in combination for generating an image of a volume, optionally a subject or a body part, cell, tissue, or organ thereof. Further provided are compositions and methods for multiplex photoacoustic imaging of a volume, optionally a subject or a body part, cell, tissue, or organ thereof using photoacoustic imaging contrast agents that include a plurality of the presently disclosed copper-complexed and/or manganese-complexed chlorins and/or bacteriochlorins and/or derivatives thereof simultaneously.

Acoustically activatable particles having low vaporization energy and methods for making and using same are disclosed. A particle of material includes a first substance that includes at least one component that is a gas 25° C. and atmospheric pressure. A second substance, different from the first substance, encapsulates the first substance to create a droplet or emulsion that is stable at room temperature and atmospheric pressure. At least some of the first substance exists in a gaseous phase at the time of encapsulation of the first substance within the second substance to form a bubble. After formation of the bubble, the bubble is condensed into a liquid phase, which causes the bubble to transform into the droplet or emulsion having a core consisting of a liquid. The droplet or emulsion is an activatable phase change agent that remains a droplet having a core consisting of a liquid at 25° C. and atmospheric pressure. The first substance has a boiling point below 25° C. at atmospheric pressure.

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.

The present subject matter provides compounds, compositions, and methods for identifying, monitoring, treating, and removing diseased tissue. Compounds, compositions, and methods for identifying, monitoring, and detecting circulating fluids such as blood are also provided.

Affibody polypeptides that specifically bind to B7-H3 are provided. Exemplary anti-B7-H3 affibodies are provided. The affibody polypeptides specifically recognize and bind to B7-H3 with high affinity. The affibodies can be conjugated to contrast agents, including without limitation microbubbles for contrast-enhanced ultrasound imaging

Gas vesicles, protein variants and related compositions methods and systems for singleplexed and/or multiplexed ultrasound imaging of a target site in which a gas vesicle provides contrast for the imaging which is modifiable by application of a selectable acoustic collapse pressure value of the gas vesicle.

The invention discloses a recombinant protein (P-selectin glycoprotein ligand-1 and Neural Retina-specific Leucine Zipper) PSGL-1-NRL chimeric protein comprising a Selectin Binding domain and a non-covalent dimerization domain, which is a leucine zipper and is more preferably the leucine zipper domain of the human or mouse Neural Retina-specific Leucine Zipper. The chimeric protein further comprises a covalent dimerization domain with at least one cysteine suitable to form a disulfide bridge with another chimeric protein to form a homodimer.

In the chimeric protein, the PSGL-1 domain corresponds to the extracellular region of Human PSGL-1 and is more preferably the selectin binding region of the mature protein.

The chimeric protein is correctly post-translationally modified and is efficiently expressed in a mammalian system. It is sulfated, O-linked glycosylated and sialylated and binds P, E and L selectin, allowing in vivo and in vitro targeting for diagnostic or therapeutic purposes.

A method of non-invasively detecting and purging bacterial cells using a modified photoacoustic in vivo flow cytometer device is described herein. In particular, a method of detecting bacterial cells by analyzing photoacoustic pulses emitted in response to laser pulses from a pulsed laser source and/or selectively destroying the detected bacterial cells using a non-linear photothermal response induced by a high-energy laser pulse is described herein.

Cancer treatment methods using thermotherapy and/or enhanced immunotherapy are disclosed herein. In one embodiment, the method comprising the steps of administering a plurality of nanoparticles to target a tumor in a patient, the nanoparticles being coated with an antitumor antibody, cell penetrating peptides (CPPs), and a polymer, and the nanoparticles containing medication and/or gene, and a dye or indicator in the polymer coating, at least some of the nanoparticles attaching to surface antigens of tumor cells so as to form a tumor cell/nanoparticle complex; exciting the nanoparticles using an ultrasound source generating an ultrasonic wave so as to peel off the polymer coating of the nanoparticles, thereby releasing the dye or indicator into the circulation of the patient and the medication and/or gene at the tumor site; and imaging a body region of the patient so as to detect the dye or indicator released into the circulation of the patient.