An implantable medical instrument for use within a body includes a container that has an opening and holds a medicinal solution, and a soft portion that closes the opening. The medical instrument further includes a power receiver that receives power transmitted externally, and a light emitter that emits light by way of the power received by the power receiver. The light emitter includes at least one of a first light emitter that emits light having a center wavelength of 600 nm or more and 1100 nm or less, and a second light emitter that emits light having a center wavelength of 400 nm or more and 480 nm or less.

An electronic sanitizing device includes a germicidal light source and one or both of a red light source or a near infrared light source. The germicidal light source is configured to output germicidal light with a peak wavelength of 250 to 270 nanometers. The red light source is configured to output red light with a peak wavelength of 620 to 700 nanometers. The near infrared light source is configured to output near infrared light with a peak wavelength of 800 to 1200 nanometers.

Dehydration and drying are some of the oldest methods of preserving food and other biological materials such as proteins and both live and dead live microorganisms or their metabolites. The invention disclosed herein seeks a method of further improving the process of preserving biological material by combining the freezing or freeze-drying process with a partial infrared dehydration step. By using infrared radiation energy to perform simultaneous blanching and dehydration, the drying speed is greatly increased and better cellular and molecular integrity is maintained. The invention herein is also particularly useful in connection with cannabis and hemp.

A device to provide sterilized surfaces and skin with the application of multiple bactericidal agents in combinations accentuating each agent's efficacy. UV, IR, and potentially others, in conjunction with minimal Ozone levels conditioned to rapidly move through the air surface/boundary layer for effective and timely activation of oxidizing effects on bacterial agents and secondarily through surface layer absorption for continued bacterial inactivation/oxidation after the stenlization event has occurred.

A device comprising a housing having a handle end and a treatment end. The treatment end is configured to provide an antimicrobial treatment and a heat treatment. The treatment end comprises an applicator having an applicator surface for providing at least the heat treatment. The device includes a heat generation unit configured to heat the applicator surface in use, a source of antimicrobial agent, and a control unit operatively connected to at least the heat generation unit for controlling the heat generation unit. The device can be a hand-held device and used to apply topical treatment to a treatment area of a subject.

A system and method that include using biophotonic and/or phononic systems for deactivating viruses, bacteria, and other pathogens that may be present on people, their clothing, or other surfaces. Biophotonic refers to the use of photons in specific wavelengths of the FAR Ultraviolet C radiation and/or FAR Infrared C radiation to affect the interior structure and chemistry of bacteria and viruses to degrade them and render them harmless. The infrared radiation may also provide a phononic effect that degrades the physical conditions of the cell or virus sufficiently to disrupt the cellular machinery, deactivating the virus. Furthermore, a higher temperature Inside the UVIR system makes negligible the rate of propagation of the Virus. The system of the present invention is operable to use electromagnetic radiation to disinfect the exterior surfaces of living mammal animals without harming the animal's tissue, but still effective to degrade microbe and sanitize the exterior surfaces.

Disclosed herein is a photochemical preparation method of an autologous plasma inactivated vaccine for the treatment of acquired immune deficiency syndrome (AIDS), including the following steps: drawing autologous blood from an AIDS patient to form blood to be treated; separating the blood to obtain plasma to be treated; adding a photosensitizer into the plasma to be treated to form plasma to be inactivated; and subjecting the plasma to be inactivated to photochemical inactivation to obtain the autologous plasma inactivated vaccine.

A system and method that include using biophotonic and/or phononic systems for deactivating viruses, bacteria, and other pathogens that may be present on people, their clothing, or other surfaces. Biophotonic refers to the use of photons in specific wavelengths of the FAR—Ultraviolet C radiation and/or FAR—Infrared C radiation to affect the interior structure and chemistry of bacteria and viruses to degrade them and render them harmless. The infrared radiation may also provide a phononic effect that degrades the physical conditions of the cell or virus sufficiently to disrupt the cellular machinery, deactivating the virus. Furthermore, a higher temperature Inside the UVIR system makes negligible the rate of propagation of the Virus. The system of the present invention is operable to use electromagnetic radiation to disinfect the exterior surfaces of living mammal animals without harming the animal's tissue, but still effective to degrade microbe and sanitize the exterior surfaces.

The present invention is directed to a system and method for photoeradication of microorganisms from a target. The method includes the step of obtaining test data for a plurality of experiments each of which comprises irradiating test microorganisms with a plurality of light pulses having a wavelength that ranges from 380 nm to 500 nm. The light pulses have a plurality of pulse parameters (peak irradiance, pulse duration, and off time between adjacent light pulses) and are provided at a radiant exposure that ranges from 0.5 J/cm.sup.2 to 60 J/cm.sup.2 during each of a plurality of irradiation sessions. The test data comprises a survival rate for the test microorganisms after irradiation with the light pulses. The method also includes the step of analyzing the test data to identify the pulse parameters for the light pulses and the radiant exposure for each of the irradiation sessions that result in a desired survival rate for the test microorganisms. The method further includes the step of irradiating the microorganisms of the target with light pulses having the identified pulse parameters at the identified radiant exposure for each of the irradiation sessions so as to photoeradicate all or a portion of the microorganisms.

A device comprising a housing having a handle end and a treatment end. The treatment end is configured to provide an antimicrobial treatment and a heat treatment. The treatment end comprises an applicator having an applicator surface for providing at least the heat treatment. The device includes a heat generation unit configured to heat the applicator surface in use, a source of antimicrobial agent, and a control unit operatively connected to at least the heat generation unit for controlling the heat generation unit. The device can be a hand-held device and used to apply topical treatment to a treatment area of a subject.