A neurofeedback enhancement system incorporating monaural audio beats, optical LED photic entrainment, and nIR LED photobiomodulation entrainment components to augment the EEG neurofeedback process. The frequency of operation for the entrainment modalities is set based on the dominant energy frequency attributes of the subjects EEG. The intensity of the entrainment modalities is dynamically modulated in response to real time analysis of targeted EEG features, and all modalities are synchronized in time.

Methods providing biofeedback generally comprising: correlating an emotional state with an emotional resonance signal of a person; determining a bio-resonant frequency and wave form from a segment of the emotional resonance signal; and producing a feedback signal that is a higher harmonic of the emotional resonance signal. Said feedback signal can help adjust emotional states, balance brainwave activity, forge new neuro-circuits, increase interhemispheric communication, creativity and brain-efficiency thereby improving a full spectrum of nervous system activity from hyperarousal to deep sleep.

A multimodal therapy delivery system configured to deliver both biochemical material and energy therapies, the multimodal therapy delivery system includes at least one mid-infrared (MIR) laser, at least one MIR transparent fluoride fiber coupled to each of the at least one MIR laser, and a needle assembly with the at least one MIR transparent fluoride fiber threaded therethrough. The multimodal therapy delivery system is configured to deliver biochemical material through the needle assembly and wherein the multimodal therapy delivery system is further configured to deliver energy from the at least one MIR laser through the at least one MIR transparent fluoride fiber threaded through the needle assembly.

Apparatuses, systems, and methods for treating a tissue site. A system for treating a tissue site with negative pressure includes a dressing and a dressing interface. The dressing includes a cover configured to be disposed over the tissue site, a tissue interface configured to be positioned adjacent to the cover, and a wound contact layer configured to be positioned adjacent to the tissue interface. The dressing interface is configured to be coupled to the cover to fluidly couple the tissue interface and the wound contact layer to a therapy unit. The dressing interface is also configured to transmit electromagnetic radiation through the cover.

A therapeutic device includes a base having a first plurality of light emitting devices and a bed supported by the base. A hood is movable between an open position and a closed position, wherein the hood comprises a second plurality of light emitting devices. The device includes first and second end caps attached to opposing ends of the base, wherein when the hood is in the closed position, a substantially enclosed chamber is formed between the base, the hood and the end caps. The device includes at least one airborne energy configured to be delivered into the enclosed chamber through at least one of the end caps. A controller is configured to control the type, intensity and duration of light emitted from the first and second plurality of light emitting devices and the at least one airborne energy to control an environment within the enclosed chamber.

An intraoral phototherapy device is provided that improves illumination of a tonsillar region of the oral cavity. Oral tissue illumination is particularly difficult in the back of the throat. The intraoral phototherapy device improves illumination of these tissues by using a breathing tube to improve patient breathing. The breathing tube allows a patient to breathe through their mouth, which opens up the tonsillar region of the oral cavity. Additionally, objects contacting near the back of the throat often induce a gagging reflex. This gagging reflex shortens the time available to perform phototherapy, making it difficult for phototherapy to be delivered to the back of the throat. The intraoral phototherapy device may reduce the gagging reflex by contacting the hard palate of the oral cavity with a dorsal fin, such that the intraoral phototherapy device does not make contact further back in the oral cavity.