Methods and devices for treating nasal airways are provided. Such devices and methods may improve airflow through an internal and/or external nasal valve, and comprise the use of mechanical re-shaping, energy application and other treatments to modify the shape, structure, and/or air flow characteristics of an internal nasal valve, an external nasal valve or other nasal airways.

Methods, apparatuses and systems are provided for non-invasive delivery of microwave therapy. Microwave energy may be applied to epidermal, dermal and subdermal tissue of a patient to achieve various therapeutic and/or aesthetic results. In one embodiment, the microwave energy is applied to a target tissue via an energy delivery applicator connected to an energy generator. The energy delivery applicator may comprise one or more antennas, including monopole, dipole, slot and/or waveguide antennas (among others) that are used to direct the microwave energy to the target tissue. The energy delivery applicator may also comprise a cooling element for avoiding thermal destruction to non-target tissue and/or a suction device to localize thermal treatment at specific portions of a skin fold.

Provided herein are systems, devices and methods for the treatment of fungus. In particular, provided herein are systems, devices and methods employing energy to nail and tissue structures to treat fungal infection.

A method for reshaping a nasal airway in a patient involves advancing an inflatable balloon of a reshaping device in an uninflated configuration into a nostril of the patient and between a nasal septum and a lateral wall of the nasal airway. The method then involves inflating the inflatable balloon to an inflated configuration to cause the inflatable balloon to contact nasal mucosa covering the nasal septum and the lateral wall, delivering energy from an energy delivery member attached to or inside of the inflatable balloon, and removing the reshaping device from the nasal airway.

A system for mid-intensity, non-ablative acoustic treatment of injured tissue is disclosed. The system produces a non-ablative therapeutic ultrasound beam profile within the injured tissue. The system terminates energy delivery if a motion sensor senses movement speed below a speed threshold. The non-ablative therapeutic ultrasound beam profile provides substantially uniform heating throughout a treatment volume. The heating is non-ablative and triggers a healing response in the injured tissue.

Devices and systems for impinging light on tissue to induce one or more biological effects and, more particularly, illumination devices and related systems for implementing therapeutic treatments of light are disclosed. Systems may include illumination devices that are configured to provide phototherapy for a variety of medical indications and/or health-related benefits. Illumination devices may be connected to systems that administer and/or monitor multiple illumination devices across multiple geographic regions to compile regional and/or global information related to phototherapeutic usage. Certain aspects relate to system elements, such as local devices and/or servers that are capable of generating treatment protocols for illumination devices based on diagnostic information. After treatment protocols are implemented by illumination devices, administered treatment information along with location information may be provided to the local devices and/or servers.

A method for early stage pathology detection, location, imaging, evaluation, and treatment of cells and/or extracellular vesicles in the circulation.

Localized heating can use a fixed-frequency planar transmission line resonators arranged along a main-line, selected by tuning an electromagnetic input signal frequency applied to the main line for depositing heat in an adjacent active substrate. More generally, adjusting input signal frequency can be used to selectively address and energize an electromagnetic-to-heat, an electromagnetic-to-vibration, or other transducer to controllably direct energy toward a desired transducer load. Resonators or other electromagnetically energized transducers can be arranged to electromagnetically interfere, such that specifying or adjusting a relative phase of applied electrical signals can be used to specify or adjust the energy directed toward a desired transducer load. Temperature sensing can characterize a material in a target region near the transducer. A cold-hot-cold temperature profile can better manage temperature and avoid overheating a dielectric material such as the active substrate material.

Device for the treatment of malaria A method and device for the treatment of malaria which comprises applying microwave energy to a patient under non-thermal conditions. The non-thermal conditions are achieved by applying the microwave energy under conditions that the normal heating effects of microwaves are not significant. For example, microwave energy may be switched on in pulses lasting less than 6 seconds.

Cancer imaging methods and cancer treatment methods using thermotherapy and drug delivery are disclosed herein. In one embodiment, the temperature of heated tissue is determined from radio-frequency data from an ultrasound transducer based upon a change in backscattered energy of acoustic harmonics. In another embodiment, a plurality of nanocarriers containing an anti-tumor medication are administered to a patient, and are excited in a first non-thermal ultrasound mode and/or a second thermal ultrasound mode using an ultrasound source. In yet another embodiment, a plurality of nanoparticles are administered to a patient, then at least some of the nanoparticles are heated along with tissue at a site of a tumor, and a photoacoustic imaging unit is used to determine a temperature of the heated tissue at the site of the tumor.