Disclosed are methods of increasing blood circulation at a target site of a subject comprising exposing a target site of the subject to an alternating electric field for a period of time, the alternating electric field having a frequency and field strength, and exposing the target site of the subject to a vasodilator, wherein the vasodilator increases blood circulation at the target site of the subject. Disclosed are methods of maintaining or decreasing temperature at a target site of a subject comprising exposing a target site of the subject to an alternating electric field for a period of time, the alternating electric field having a frequency and field strength, and exposing the target site of the subject to a vasodilator, wherein the vasodilator increases circulation at the target site of the subject, wherein increased circulation maintains or decreases temperature at the target site.

Disclosed are methods of delivering a therapeutic to a target site of a subject comprising administering a lipid capsule to a target site of a subject, wherein the lipid capsule comprises a therapeutic agent; and applying an alternating electric field, at a frequency for a period of time, to the target site of the subject, wherein the alternating electric field releases the therapeutic from lipid capsule at the target site of the subject. Disclosed are methods of increasing target site specific release of a therapeutic agent in a subject comprising administering a lipid capsule to a target site of a subject, wherein the lipid capsule comprises a therapeutic agent; and applying an alternating electric field, at a frequency for a period of time, to the target site of the subject, wherein the alternating electric field releases the therapeutic agent from the lipid capsule at the target site of the subject, thereby increasing the target site specific release of the therapeutic agent. Disclosed are methods of treating comprise administering a lipid capsule to a target site of a subject in need thereof, wherein the lipid capsule comprises a therapeutic agent; and applying an alternating electric field, at a frequency for a period of time, to the target site of the subject in need thereof, wherein the alternating electric field releases the therapeutic agent from the lipid capsule at the target site of the subject in need thereof. Disclosed are methods of killing a cell comprising administering a lipid capsule to a target site, wherein the lipid capsule comprises a therapeutic agent; and applying an alternating electric field for a period of time, to the target site, wherein the alternating electric field releases the therapeutic agent from the lipid capsule at the target site, wherein the target site comprises a cell, wherein the therapeutic kills the cell.

Systems are provided for compact implantable multi-site optical stimulation and/or combined electrical and optical stimulation of spinal cord, brain, dorsal root ganglion, peripheral nerve, or other tissue. High-power LEDs or other light-emitting elements are provided at the site of stimulation, avoiding complex fiber optics or other means for coupling light from a distant laser along a stimulator to target tissue. Colocation of electrical stimulation contacts and light emitters allows the same tissue to be stimulated electrically and optically, at the same time or according to an alternating or other pattern of combined electrical and optical stimulation. These stimulators can be used as part of permanently implanted systems and/or as part of temporary, percutaneous stimulator systems. Optical and/or combined electrical and optical stimulation can be provided for pain relief, to encourage wound healing in nervous or non-nervous tissue, or to provide other clinical benefits.

A multi-type combination electrical stimulation method is for medical treatment of surface and internal infected tissues, surface wounds and ulcers, trauma injuries, abnormal plasia and fibrotic changes, and pain conditions. The multi-type electrotherapy system for non-invasive treatment of both surface and deep body bacterial and viral infections and wound healing includes a machine learning function optimization task algorithm, and a stimulation device electronically with the ability to generate carrier base waveforms with amplitude modulation of these waveforms by secondary frequencies. The ranges of such frequencies are base frequencies in the range of 1-20,000 Hz and modulating frequencies in the range of 1-200 Hz. The waveforms are generated by either direct digital synthesis (DDS) or digital to analogue (DAC) converter electronics.

A treatment apparatus includes a motorized subsystem in a handpiece housing having a rotating output shaft, an axial cam driven in rotation by the output shaft, and a push rod linearly driven by the axial cam. A cartridge is removably attachable to the handpiece housing and includes a cartridge housing, a needle assembly, a piston in the housing engaging the needle assembly and linearly driven forward by the push rod, and a first biasing member urging the piston rearward.

The systems and methods of this disclosure are directed to the treatment of disease states, and particularly different types of cancer, by application of low energy emission therapy. The device and method provide treatments of disease states in a patient, and particularly of cancer types, by the application to the patient of particular and disease-specific low energy high frequency radiation. The device uses a high precision frequency synthesizer to generate radio frequency radiation that is amplitude-modulated at identified tumor-specific frequencies for application to the patient during therapy.

A stimulation system includes an energy source, an electronics unit with a controller, and an actuator that is coupled with the electronics unit and/or the energy source. The actuator emits electromagnetic waves for stimulation of genetically manipulated tissue. The electronics unit is disposed in a housing. The stimulation system is configured for at least temporary implantation in a human or animal body. The controller controls the stimulation of tissue in the body by way of the electromagnetic waves emitted by the actuator. A selector of the stimulation system selects the area of the said tissue for stimulation. The selector includes a masking device for masking certain areas of the tissue, so that an intensity of the stimulation for the masked areas is reduced or equal to zero.

A stimulation system includes an energy source, an electronics unit with a controller, and an actuator that is coupled with the electronics unit and/or the energy source. The actuator emits electromagnetic waves for stimulation of genetically manipulated tissue. The electronics unit is disposed in a housing. The stimulation system is configured for at least temporary implantation in a human or animal body. The controller controls the stimulation of tissue in the body by way of the electromagnetic waves emitted by the actuator. A selector of the stimulation system selects the area of the said tissue for stimulation. The selector includes a masking device for masking certain areas of the tissue, so that an intensity of the stimulation for the masked areas is reduced or equal to zero.

Devices and methods for blocking signal transmission through neural tissue. One step of a method includes placing a therapy delivery device into electrical communication with the neural tissue. The therapy delivery device includes an electrode contact having a high charge capacity material. A multi-phase direct current (DC) can be applied to the neural tissue without damaging the neural tissue. The multi-phase DC includes a cathodic DC phase and anodic DC phase that collectively produce a neural block and reduce the charge delivered by the therapy delivery device. The DC delivery can be combined with high frequency alternating current (HFAC) block to produce a system that provides effective, safe, long term block without inducing an onset response.

Devices and methods for blocking signal transmission through neural tissue. One step of a method includes placing a therapy delivery device into electrical communication with the neural tissue. The therapy delivery device includes an electrode contact having a high charge capacity material. A multi-phase direct current (DC) can be applied to the neural tissue without damaging the neural tissue. The multi-phase DC includes a cathodic DC phase and anodic DC phase that collectively produce a neural block and reduce the charge delivered by the therapy delivery device. The DC delivery can be combined with high frequency alternating current (HFAC) block to produce a system that provides effective, safe, long term block without inducing an onset response.