Abstract: Provided herein are microbubble compositions comprising nitro-fatty acids and/or esters thereof, such as amphiphilic esters or allyl esters thereof. Also provided are methods of reducing local inflammation at a site in a patient comprising delivering the microbubbles to a site of inflammation in the patient and applying ultrasound to the microbubbles. The methods may be used to treat fibrosis or cancer.

Abstract: The presently disclosed drug-loaded liposomal conjugated to polymer microbubbles showed: i) increased tumor drug concentration; ii) reduced tumor growth; and ii) increased survival time in a mouse cancer model when exposed to concurrent high and low acoustic pressure ultrasonic pulses as compared to individual high or low acoustic pressure ultrasonic pulses. Notably, when unconjugated drug-loaded liposome were administered with free microbubbles and exposed to concurrent high and low acoustic pressure ultrasonic pulses, a superior tumor growth inhibition was also seen. Three weeks after treatments, DoxLPX+US group showed significantly better left ventricular function indices from echocardiography imaging than the free Dox group. Clinical methods using these liposomal conjugated microbubbles permit an increased therapeutic drug delivery and improved safety profile, respectively due to enhanced, preferential drug accumulation in target tumor tissue and simultaneously reduced drug delivery to non-target tissue.

Abstract: Various methods of performing ultrasound contrast assisted therapy are provided. One such method includes delivering a plurality of microbubble-based ultrasound contrast agents to a target area and disrupting the microbubble-based ultrasound contrast agents by delivering tone bursts of ultrasound to the target area. The oscillation of the microbubble-based ultrasound contrast agents can be achieved by delivering ultrasound tone bursts of greater than 5 acoustic cycles with a pulse repetition frequency of between 0.01 and 20 Hz, with pressure greater than 0.3 MPa.

Abstract: A method of imaging a blood vessel includes delivering a bubble-based contrast agent within the vessel and positioning at least one ultrasound device in the vicinity of the bubble-based contrast agent within the vessel. A first burst of low-frequency ultrasound energy can be delivered to excite the bubble-based contrast agent into oscillation within the vessel, and a second burst of high-frequency ultrasound energy can be delivered at the excited bubble-based contrast agent. A return signal from the burst of high-frequency ultrasound energy can be received and processed to obtain one or more images.

Abstract: The present invention discloses compositions and methods for clinical imaging. In particular, these compositions and methods provide improvements to cardiovascular imaging. Such improvements are drawn to the creation and use of polymer-based microbubbles comprising metal nanoparticle additives that provide contrast images of highly improve resolution when compared to conventional lipid based microbubbles. For example, the compositions and methods may be used for dark field X-ray scattering contrast images for angiography.

Abstract: A method of imaging a blood vessel includes delivering a bubble-based contrast agent within the vessel and positioning at least one ultrasound device in the vicinity of the bubble-based contrast agent within the vessel. A first burst of low-frequency ultrasound energy can be delivered to excite the bubble-based contrast agent into oscillation within the vessel, and a second burst of high-frequency ultrasound energy can be delivered at the excited bubble-based contrast agent. A return signal from the burst of high-frequency ultrasound energy can be received and processed to obtain one or more images.

Abstract: A method of imaging a blood vessel includes delivering a bubble-based contrast agent within the vessel and positioning at least one ultrasound device in the vicinity of the bubble-based contrast agent within the vessel. A first burst of low-frequency ultrasound energy can be delivered to excite the bubble-based contrast agent into oscillation within the vessel, and a second burst of high-frequency ultrasound energy can be delivered at the excited bubble-based contrast agent. A return signal from the burst of high-frequency ultrasound energy can be received and processed to obtain one or more images.

Abstract: Various methods of performing ultrasound contrast assisted therapy are provided. One such method includes delivering a plurality of microbubble-based ultrasound contrast agents to a target area and disrupting the microbubble-based ultrasound contrast agents by delivering tone bursts of ultrasound to the target area. The oscillation of the microbubble-based ultrasound contrast agents can be achieved by delivering ultrasound tone bursts of greater than 5 acoustic cycles with a pulse repetition frequency of between 0.01 and 20 Hz, with pressure greater than 0.3 MPa.

Abstract: A method of imaging a blood vessel includes delivering a bubble-based contrast agent within the vessel and positioning at least one ultrasound device in the vicinity of the bubble-based contrast agent within the vessel. A first burst of low-frequency ultrasound energy can be delivered to excite the bubble-based contrast agent into oscillation within the vessel, and a second burst of high-frequency ultrasound energy can be delivered at the excited bubble-based contrast agent. A return signal from the burst of high-frequency ultrasound energy can be received and processed to obtain one or more images.

Abstract: Methods for delivering drugs, vectors, cells diagnostic agents and other chemical or biological entities to a tissue or cellular surface are disclosed. The methods generally involve coupling a molecule to the tissue or cellular surface. The molecule comprises at least one reactive group that reacts with groups present on the surface, and at least one signaling molecule. A chemical or biological entity having a recognition molecule attached thereto or expressed thereby is introduced to the surface. The recognition molecule and signaling molecule bind so as to attach the entity to the surface. Localized delivery of various chemical and biological entities is thereby achieved. The molecule can also contain a polymer that can mask adhesive information inherent to the tissue or cellular surface. Tissues and cells modified according to the present methods are also disclosed.