A process for heat treating biological tissue includes providing a plurality of energy emitters formed into an array. Treatment energy is generated from the plurality of emitters and applied to target tissue. The treatment energy has energy and application parameters selected so as to raise the target tissue temperature sufficiently to create a therapeutic effect while maintaining an average temperature of the target tissue over several minutes at or below a predetermined temperature so as not to destroy or permanently damage the target tissue.

An apparatus comprises a flexible substrate, a phased array antenna system disposed on the substrate, and a wearable applicator. The flexible substrate is configured to conform to a shape corresponding to a portion of a human body. The phased array antenna system comprises a plurality of antenna elements configured to resonate in response to an input signal and to generate a collective output electromagnetic pattern to propagate wirelessly to a target region in a human body. The wearable applicator is configured to align the collective output electromagnetic pattern with the target region.

Cancer treatment and imaging methods using thermotherapy and drug delivery are disclosed herein. In one embodiment, the method comprises the steps of administering a plurality of antibody or aptamer-conjugated nanoparticles, liposomes, and/or micelles containing a medication and/or gene to a patient in need thereof so as to target a tumor in the patient, at least some of the antibody or aptamer-conjugated nanoparticles, liposomes, and/or micelles attaching to surface antigens of tumor cells of the tumor so as to form a tumor cell/nanoparticle/liposome/micelle complex; and heating the antibody or aptamer-conjugated nanoparticles, liposomes, and/or micelles using an energy source so as to raise the temperature of the tumor cell/nanoparticle complex, micelle complex, and/or liposome complex, thereby releasing one or more medications from the antibody or aptamer-conjugated nanoparticles, liposomes, and/or micelles, and damaging one or more tumor cell membranes at the tumor site.

Embodiments disclosed include systems, methods, and apparatuses, directed to administering thermal neural modulation to mammalian tissue to control nerve conduction. Embodiments disclosed include an apparatus comprising a thermal energy source, a first heat exchanger coupled to the thermal energy source and configured to receive thermal energy therefrom, a thermal applicator configured to be disposed and secured to the anatomy of a subject having a nerve therein, in contact with the skin on the anatomy and overlying a treatment portion of the nerve, the thermal applicator configured to transfer thermal energy to the skin to raise the temperature of the treatment portion of the nerve above a physiologic temperature, a second heat exchanger is coupled to the thermal applicator and configured to transfer thermal energy thereto, and a fluid conduit having a first portion coupled to the first heat exchanger and a second portion coupled to the second heat exchanger. The fluid conduit is configured to have fluid circulated therethrough to convey thermal energy from the thermal energy source via the first heat exchanger and to the thermal applicator via the second energy at a temperature.

Illumination devices for impinging light on tissue, for example within a body cavity of a patient, to induce various biological effects are disclosed. Biological effects may include at least one of inactivating and/or inhibiting growth of one or more pathogens, upregulating a local immune response, increasing endogenous stores of nitric oxide, releasing nitric oxide from endogenous stores, and inducing an anti-inflammatory effect. Biological effects may include upregulating and downregulating inflammatory immune response molecules within a target tissue. Wavelengths of light are selected based on intended biological effects for one or more of targeted tissue types and targeted pathogens. Light treatments may provide multiple pathogenic biological effects, either with light of a single wavelength or with light having multiple wavelengths. Devices for light treatments are disclosed that provide light doses for inducing biological effects on various targeted pathogens and tissues with increased efficacy and reduced cytotoxicity.

Illumination devices for impinging light on tissue, for example within a body cavity of a patient, to induce various biological effects are disclosed. Biological effects may include at least one of inactivating and/or inhibiting growth of one or more pathogens, upregulating a local immune response, increasing endogenous stores of nitric oxide, releasing nitric oxide from endogenous stores, and inducing an anti-inflammatory effect. Wavelengths of light are selected based on intended biological effects for one or more of targeted tissue types and targeted pathogens. Light treatments may provide multiple pathogenic biological effects, either with light of a single wavelength or with light having multiple wavelengths. Devices for light treatments are disclosed that provide light doses for inducing biological effects on various targeted pathogens and tissues with increased efficacy and reduced cytotoxicity. Illumination devices may be configured to communicate with networks and/or servers to provide control and/or management of phototherapy treatments.

A process for heat treating biological tissue includes repeatedly applying a pulsed energy to a target tissue over a period of time so as to controllably raise a temperature of the target tissue to create a therapeutic effect to the target tissue without destroying or permanently damaging the target tissue. After the first treatment is concluded the application of the pulsed energy to the target tissue is halted for an interval of time. Within a single treatment session a second treatment is performed on the target tissue after the interval of time by repeatedly reapplying the pulsed energy to the target tissue so as to controllably raise the temperature of the target tissue to therapeutically treat the target tissue without destroying or permanently damaging the target tissue.

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.

A method of applying heat to living tissue mainly uses a device for performing heat treatment on at least a portion of the living tissue in high-low-high temperature steps. In high temperature step, the temperature of the at least a portion of the living tissue is heated and kept between 39-46° C., and the heating period is no longer than 30 minutes. In low temperature step, the at least a portion of the living tissue is cooled, and the low temperature period should not be greater than a natural cooling time interval. In addition, the low temperature period must also be shorter than the heating period. Thus, the present invention allows the abnormal cells to be selectively restored or apoptotic without damaging the normal cells.

Catheter apparatus comprises a coaxial cable having proximal and distal ends. The cable includes a hollow center conductor, an outer conductor and an electrically insulating layer between the conductors. An antenna is at the distal end of the cable, and a diplexer is connected to the cable, the diplexer including a transmit path for connecting the antenna to a transmitter which transmits first frequency signals and a receive path for connecting the antenna to a receiver which detects second frequency signals the diplexer isolating the signals on the two paths from one another. A transmission line connects the cable to the diplexer, the transmission line having a segment with a tubular inner conductor one end of which is connected to the center conductor and a second end of which is adapted for connection to a coolant source, the center and inner conductors forming a continuous coolant pathway.