A method for applying ultrasound to activate a cavitation enhancing agent in the presence of a therapeutic compound and a microbial biofilm is provided. The ultrasound energy causes the cavitation enhancing agent to cavitate in the ultrasound field. The cavitation of the resultant bubble causes fluid streaming and shear forces at and near the biofilm, causing enhanced penetration of the therapeutic compound into the biofilm, and resulting in improved efficacy of the therapeutic compound against the biofilm. The method further includes cavitation enhancing agents which can be loaded with oxygen gas or combined with microbubbles which carry oxygen gas, which further potentiate antibiotic efficacy against the biofilm.

The present invention relates to methods of treating, preventing, reducing the severity of, reducing the incidence of, delaying the onset of, or reducing pathogenesis of an inflammatory skin disease, condition or lesion in a human subject, which include the step of administering to the subject a therapeutically effective amount of mi RNA compositions. In addition, methods of this invention may be used to treat symptoms of inflammatory skin diseases and reduce and/or inhibit keratinocyte proliferation.

This application relates to methods of targeted focal treatment for localized prostate cancer.

The invention relates to a microbubble-chemotherapeutic agent complex comprising a microbubble carrying a combination of chemotherapeutic agents for use in a method of treating cancer in a patient, wherein said combination of chemotherapeutic agents comprises: (a) a 5-fluoropyrimidine or a derivative thereof; (b) irinotecan or a derivative thereof; and (c) a platinum-based chemotherapeutic agent or a derivative thereof; and wherein said method comprises simultaneous, separate or sequential administration of folinic acid or a derivative thereof. The invention is particularly suitable for use in the treatment of deep-sited tumours and associated metastatic disease, for example in the treatment of pancreatic cancer. The invention further relates to the microbubble- chemotherapeutic agent complexes themselves, to methods for their preparation and to pharmaceutical compositions which contain them, optionally in combination with folinic acid or a folinic acid derivative.

There is disclosed systems and methods for non-invasive delivery of an agent to biological tissues. Delivery of the agent to the tissues can be by one or more modalities. In some embodiments the systems and methods use agent carrier body including a tissue contacting surface for non-invasively engaging tissues under treatment. The tissue contacting surface can be at least partly defined by a plurality of protrusions that are in fluid communication with one or more reservoirs forming part of the agent carrier body. The protrusions may extend outward from an inside of a void and terminate at said tissue contacting surface.

Methods and apparatus are provided for applying an fragment of a neurotoxin such as the active light chain (LC) of the botulinum toxin (BoNT), such as one of the serotype A, B, C, D, E, F or G botulinum toxins, via permeabilization of targeted cell membranes to enable translocation of the botulinum neurotoxin light chain (BoNT-LC) molecule across the targeted cell membrane to the cell cytosol where a therapeutic response is produced in a mammalian system. The methods and apparatus include use of catheter based delivery systems, non-invasive delivery systems, and transdermal delivery systems.

The present invention is directed to methods for reducing systemic absorption of therapeutic compounds or agents while enhancing efficiency of delivery and targeting of intranasal administration of such compounds or agents to the central nervous system. More specifically, use of ultrasound technology in conjunction with intranasal delivery of a therapeutic compound, or pharmaceutical composition, wherein the intranasal delivery is preferably to the upper one third of a patient's nasal cavity, thereby reducing therapeutic compound or agent absorption into the blood. At the same time, the present invention results in reducing the delivery of therapeutic compounds and/or agents to the peripheral tissues, increases therapeutic delivery of the compounds and/or agents to the central nervous system generally, and increases targeting of the therapeutics and/or agents to specific target regions within the central nervous system.

Compositions comprising electro-activated aqueous solutions and methods for the prevention and treatment of dysfunctional cardiovascular conditions are provided.

Various methods and devices of treating infectious diseases are described. In one example embodiment, a method of treating an infectious disease in an individual in need thereof is provided, including administering a therapeutic agent to the individual and electroporating a tissue of the individual, wherein the therapeutic agent is inhalable.

Disclosed herein is a vaccine comprising an antigen and IL-21. Also disclosed herein are methods for increasing an immune response in a subject. The methods may comprise administering the vaccine to the subject in need thereof.