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.

Methods and apparatuses for reducing the bioburden of cannabis using low-pressure radiant energy processing. The present invention achieves sufficient microbial killing and/or adequate drying without impacting product quality (terpene loss, smell, color, texture, etc.) by appropriate determination and application of pressure(s) and radiant energy (e.g., microwave intensity).

Methods and apparatuses for reducing the bioburden of cannabis using low-pressure radiant energy processing. The present invention achieves sufficient microbial killing and/or adequate drying without impacting product quality (terpene loss, smell, color, texture, etc.) by appropriate determination and application of pressure(s) and radiant energy (e.g., microwave intensity).

The present application relates to systems, methods, and computer-readable media for providing generating odors. In aspects, the disclosed methods may include generating, by a chemistry dispersion element, a signal configured to act upon a surface of a chemistry reservoir to disperse an odorous substance retained within the chemistry reservoir. The chemistry reservoir and the chemistry dispersion element may be disposed within a housing. The method also includes generating, by an air pump, a volume of air, and transporting, by an airflow pathway, the volume of air from the air pump to an air outlet. The volume of air passes through at least a portion of the housing as it flows through the airflow pathway from the air pump to the air outlet, and transports at least a portion of the odorous substance dispersed by the chemistry reservoir within the housing to the air outlet.

The invention relates to systems and/or apparatuses capable of sterilizing medical products, preferably reusable urinary catheters, or other products using radiation. The apparatus of the present invention can be efficiently configured and designed to provide sterilization of the surfaces of a medical device by emitting radiation in a range sufficient and effective to destroy contaminants including pathogens and microorganisms. According to one preferred embodiment, radiation emitting diodes are placed in an array such that radiation is emitted into the interior of the apparatus enclosing the medical device for sterilization. Preferably, the systems and/or apparatuses can repeatedly sterilize medical products (e.g., reusable urinary catheters) without damaging them.

The invention relates to systems and/or apparatuses capable of sterilizing medical products, preferably reusable urinary catheters, or other products using radiation. The apparatus of the present invention can be efficiently configured and designed to provide sterilization of the surfaces of a medical device by emitting radiation in a range sufficient and effective to destroy contaminants including pathogens and microorganisms. According to one preferred embodiment, radiation emitting diodes are placed in an array such that radiation is emitted into the interior of the apparatus enclosing the medical device for sterilization. Preferably, the systems and/or apparatuses can repeatedly sterilize medical products (e.g., reusable urinary catheters) without damaging them.

A reusable urinary intermittent catheter comprising: a catheter tube; a funnel connected to the catheter tube; and one or more near-field communication (NFC) tags embedded in the catheter that contain authentication information and validate the authentication information and usage information. The catheter tube may be configured to be inserted into a male or female urethral tract to facilitate drainage of urine from a bladder into a receptacle. The funnel may be curved to facilitate a flow of urine through the catheter tube and slow the flow of the urine exiting the funnel while minimizing splashing of the urine and reducing material strain on the catheter tube when stored with an insertion aid.

A reusable urinary intermittent catheter comprising: a catheter tube; a funnel connected to the catheter tube; and one or more near-field communication (NFC) tags embedded in the catheter that contain authentication information and validate the authentication information and usage information. The catheter tube may be configured to be inserted into a male or female urethral tract to facilitate drainage of urine from a bladder into a receptacle. The funnel may be curved to facilitate a flow of urine through the catheter tube and slow the flow of the urine exiting the funnel while minimizing splashing of the urine and reducing material strain on the catheter tube when stored with an insertion aid.

Disclosed are microwave assisted methods and systems for decontaminating a variety of contaminated surfaces. The systems and methods comprise treating the surfaces with benign chemical formulations followed by exposing to microwave irradiation for short periods of time to achieve at least 6-log reduction in biological contaminants including spores of B. anthracis, B. thuringiensis, and P. roqueforti. Chemical formulations may comprise copper (II) chloride in water. The formulations may include a surfactant such as a polyethylene sorbitol ester surfactant.

Disclosed are microwave assisted methods and systems for decontaminating a variety of contaminated surfaces. The systems and methods comprise treating the surfaces with benign chemical formulations followed by exposing to microwave irradiation for short periods of time to achieve at least 6-log reduction in biological contaminants including spores of B. anthracis, B. thuringiensis, and P. roqueforti. Chemical formulations may comprise copper (II) chloride in water. The formulations may include a surfactant such as a polyethylene sorbitol ester surfactant.