Proposed are an ultrasound-assisted drug delivery carrier containing a ligand linked with a drug through an ester bond, a phospholipid, and a PEGylated phospholipid, a composition for drug delivery including the drug delivery carrier, and a method of preventing or treating a disease including administering the composition to an individual other than a human and releasing a drug by subjecting the site of administration of the composition to ultrasound irradiation. The ultrasound-assisted drug delivery carrier containing a ligand linked with a drug through an ester bond, a phospholipid, and a PEGylated phospholipid can be provided in the form of microbubbles or nanobubbles, and is capable of accelerating drug release due to collapse of the bubbles and promotion of hydrolysis of the ester bond during ultrasound irradiation, making it possible to deliver the drug to a desired site with high efficiency.

The present invention relates to iontophoretic compositions comprising a ketamine salt, a thickener in an amount to provide a viscosity of at least 500 mPas (at 20° C.), and water, and to their use for treating pain or depression. The present invention further relates to kits that comprise corresponding iontophoretic compositions and an iontophoresis device.

This invention related to manufactured microbubbles, as well as methods of using manufactured microbubbles, for example, in medicinal applications. The invention pertains to the physical structure and materials of the microbubbles, as well as to methods for manufacturing microbubbles, methods for targeting microbubbles for specific medicinal applications, and methods for delivering microbubbles in medical treatment.

An intracellular delivery system and method are provided. The intracellular delivery system comprises a laser-activated surface and cells positioned at a distance from the laser-activated surface. A laser provided a laser pulse that is used to porate membranes of the cells to deliver or extract cargo from the cells into a liquid surrounding the cells. The method of intracellular delivery comprises positioning a laser-activated surface at a distance from cells and applying a laser pulse from the laser to the surface to porate membranes of the cells to deliver or extract cargo from the cells into a liquid surrounding the cells.

Provided herein are compositions and methods for diagnosis and treatment of early-stage atherosclerotic plaques and reduction of plaques in arteries. In particular, provided herein are high-density-lipoprotein-functionalized magnetic nanostructures (HDL-MNS) capable of (i) precise anatomic detection of atherosclerotic lesions, (ii) removal of excess cholesterol from macrophage cells in atherosclerotic plaque, and/or (iii) delivery of therapeutic agents to plaque locations, and methods of diagnosis and treatment of atherosclerosis.

A medicament containment device (106) is provided containing a medicament (114) and is associated with an implant, such as an orthopedic implant (102). The medicament containment device (106) can degrade upon exposure to energy, such as energy (112) from an energy source (110). The orthopedic implant (102), including the medicament containment device is implanted or inserted into an environment (100) such as a patient's body. The energy source (110) can be used outside the patient's body, but in proximity to the orthopedic implant (102), to apply energy (112) to the medicament containment device (106). Upon exposure to the energy (112), the medicament containment device (106) can degrade and release the medicament (114) into the environment (100). The medicament (114) can kill and/or disrupt bacterial cells (108) or other infectious cells that form in proximity to the orthopedic implant (102).

Compositions including pH sensitive lipid vesicles comprised of a lipid layer, an agent, and an organic halogen such that the agent is released from the vesicles after exposure to ionizing radiation. Methods of delivering the agent to a target in a subject using the compositions provided herein are also described. The methods allow for controlled release of the agent. The timing of release of the agent from the lipid vesicle may be controlled as well as the location of release by timing and localizing the exposure to ionizing radiation exposure.

Embodiments of the invention provide methods for transdermal delivery of therapeutic agents for treatment of addictive cravings e.g., from nicotine. Embodiment of a method for such delivery comprises positioning at least one electrode assembly in electrical communication with a patient's skin. The assembly includes a solution comprising a therapeutic agent which passively diffuses into skin. A dose of agent is delivered from the assembly into skin during a first period using a first current having a characteristic e.g., polarity and magnitude, to repel agent out of the assembly. During a second period, a second current having a characteristic to attract agent is used to retain agent in the assembly such that delivery of agent into skin is minimized. In particular embodiments, a dose of agent may be delivered on-demand using an input from the patient using an inhalation sensing device which mimics an inhaled form of tobacco.

Provided are compositions and methods for transport, monitoring the transport, and controlled release of active agents. The compositions comprise surface functionalized iron oxide nanoparticles. The iron oxide nanoparticles are surface functionalized with cucurbitril[7] macrocycles. The cavity formed by the CB[7] macrocycles can be used for storage and transport of active agents. The active agents may be imaging agents or may be therapeutic agents which can be released by applying an alternating magnetic field at desired locations.

The invention provides articles of manufacture comprising biocompatible nanostructures comprising nanotubes and nanopores for, e.g., organ, tissue and/or cell growth, e.g., for bone, kidney or liver growth, and uses thereof, e.g., for in vitro testing, in vivo implants, including their use in making and using artificial organs, and related therapeutics. The invention provides lock-in nanostructures comprising a plurality of nanopores or nanotubes, wherein the nanopore or nanotube entrance has a smaller diameter or size than the rest (the interior) of the nanopore or nanotube. The invention also provides dual structured biomaterial comprising micro- or macro-pores and nanopores. The invention provides biomaterials having a surface comprising a plurality of enlarged diameter nanopores and/or nanotubes.