The unit for non-invasive stimulation of visual cortex cells in severe visual impairment comprises the image sensor (1) provided with the video chip (2) connected to the control processor (9) to convert the image signal to signals capable of stimulating the brain, to which the first transmitting sensor (3) for self-stimulation, the second transmitting sensor (4) of the position stabilisation and the receiving sensor (8) of the position stabilisation feedback are connected via the position stabilisation unit (6), wherein these sensors are connected to the carrier (16) of the active/passive sensors (7) via transmitting active/passive sensors (7) of the position stabilisation feedback. The communication module is connected to the control processor (9); this communication module may be interconnected to the mobile unit (15), and the individual elements may be placed within the supporting structure (5).

This “in vivo” medical treatment/diagnostic invention has the “intended use” of bombarding the family of coronavirus cells (and COVID-19 and variants) with an energy beam at a tuned frequency to cause them to resonant at a turbulent velocity the outer shell shatters causing their destruction. A Treatment Probe is advanced through the mouth into the windpipe, then an energy beam of extremely high frequency electromagnetic waves causes the cells to react by oscillating at a turbulence sufficient to shatter their electrostatic viral fields thus denaturing these viral cells The remaining active cells are attack by the body's immune system. Repeating treatment sessions stimulate the body's immune system to denatures/destroys the family of coronavirus cells.

TABLE-US-00001 Table of Contents number Title page # TITLE  2 PATENT DECLATION  2 CROSS REFERENCE TO RELATED APPLICATIONS  2 FEDERALLY SPONSORED RESEARCH  2 SEQUENCE LISTING, ETC ON CD  2 BACKGROUND OF THE INVENTION  3 NEED FOR THIS INVENTION  3 Description of Related Art  5 DESCRIPTION OF RELATED ART  5 BRIEF SUMMARY OF THE INVENTION  6 Stimulating the immune system  7 BACKGROUND OF THE INVENTION  8 Technological characteristics  8 DETAILED DESCRIPTION OF THE INVENTION  9 Science Elements  9 Energy Transfer Characteristics 10 Description Of The Destructive Mechanism 11 Power and Frequency 12 Maximum Safe Power 13 Safe Radiation Properties 14 Hardware Design 14 EM Generator Elements 15 Diagnostic Mode 16 Treatment Session Description 17 Treatment/Diagnostic Sequencing 18 [031] BRIEF DESCRIPTION OF THE DRAWING 20 FIG. 1. Description 20 FIG. 2. Description 21 FIG. 3. Description 21 FIG. 4. Description 22 GLOSSARY OF TERMS 22-25 ABSTRACT OF THE DISCLOSURE 26 Drawing Document 27-30 Claims Document 31-32

A dual-mode microwave applicator for treating tissue comprises a control unit, a rod-shaped element, a coaxial line, and a metal sleeve. The control unit controls the applicator in an application mode and a sensing mode. In the application mode microwave radiation is applied and during the sensing mode tumorous tissue is detected. The rod-shaped element comprises a tip. The coaxial line is formed in the rod-shaped element to relay microwaves to the tip for treatment of the tissue. The coaxial line comprises an inner conductor and an outer conductor. The outer conductor includes a slot of a slot length formed at a slot distance from the tip. The metal sleeve at a sleeve distance from the slot. The sleeve distance is about 0.55 mm, the slot length is about 1.75 mm, and the slot distance is about 7.7 mm.

A ventilation arrangement (1) comprises an induction device (2) and a control unit (3). The induction device (2) has an electro-magnetic field generator (21) with a coil design (211) configured to generate a spatial electro-magnetic field having a targeted shape. The control unit (3) is in communication with the induction device (2) and configured to control the induction device (2) to generate the electro-magnetic field. The electro-magnetic field generator (21) of the induction device (2) is configured to be positioned at a human or animal patient (5) such that, for activating a diaphragm of the patient (5), a Phrenic nerve of the patient (5) is stimulatable by the spatial electro-magnetic field generated by the coil design (211). The control unit (3) is connectable to a ventilation machine (6) to receive ventilation data about a ventilation of the patient (5). The control unit (3) is configured to evaluate the ventilation data and to operate the induction device (2) in accordance with the evaluated ventilation data.

A microwave source used in the radiotherapy device can be provided. The microwave source may include an anode block and one or more cathodes. The cathode of the microwave source may include a cathode support element having a plurality of slots. The plurality of slots can be axially around a circumference of the cathode support element. The microwave source may include a cathode heater including at least one filament. A first part of the at least one filament may be wound around the cathode support element along a first direction and received by a first portion of the plurality of slots, and a second part of the at least one filament may be wound around the cathode support element along a second direction and received by a second portion of the plurality of slots.

A microwave device for a disinfection treatment of a human being is disclosed. The microwave device includes a radiation pad including an array of antennas and a microwave generator configured to excite the array of antennas to cause each antenna in the array of antennas to transmit a continuous-wave microwave signal. Each antenna is arranged in the radiation pad so that as the radiation pad is positioned adjacent a treatment area of the human being the continuous-wave microwave signals from the array of antennas combine in the near field in the treatment area to inactivate microbial pathogens comprising bacteria or fungus.

A neurostimulator implant includes an insulating member and an elongate circuitry unit. The circuitry unit includes (a) a first electrode, disposed on an outer surface of a first end portion of the circuitry unit; (b) a second electrode, disposed on an outer surface of a second end portion of the circuitry unit; and (c) circuitry, disposed inside the circuitry unit, and configured to be wirelessly powered to drive an electrical current between the first and second electrodes. The circuitry unit is disposed alongside a medial part of the insulating member, bulging away from the insulating member to define a generally arced portion of the implant. Lateral parts of the insulating member extend laterally outward from the medial part to define lateral zones laterally beyond the circuitry unit. The second side of the insulating member defines a generally flat side of the implant. Other embodiments are also described.

Headache treatment methods are described and include providing, an energy delivery device; locating a secondary or higher-order branch of a postganglionic nerve that provides innervation for a patient's head, by identifying a target region of the patient's head that includes the nerve branch; positioning, within the target region, a portion of the energy delivery device; and applying, from the positioned portion of the energy delivery device to the target region, an amount of energy effective to result in a stimulation activity of the nerve branch; and, after observing the stimulated nerve branch activity, delivering, from the energy delivery device to the nerve branch, energy in an amount effective to reduce a headache severity in the patient.

A system for sterilizing viruses includes beam generation circuitry for generating a radiating wave having radiating energy therein at a predetermined frequency therein. A controller controls the radiating wave generation at the predetermined frequency. The predetermined frequency equals a resonance frequency of a particular virus. The predetermined frequency induces a mechanical resonance vibration at the resonance frequency of the particular virus within the particular virus for destroying a capsid of the particular virus. Radiating circuitry projects the radiating wave on a predetermined location to destroy the particular virus at the predetermined location.

Embodiments provide for systems and methods for modulating activity of a live neuronal circuit within the brain of a mammal. In one example, a method comprises applying a focused microwave pulse to a focal spot corresponding to the live neuronal circuit, while simultaneously monitoring a brain image produced by a brain imaging system. In this way, the focused microwave pulse may be used to transiently modulate the function of the live neuronal circuit, as guided by anatomical and functional information provided via the brain imaging system, useful for both research purposes and for treating psychiatric, neurological and neuroendocrine disorders.