A face mask apparatus with N95 filter capability is formed with a breathing chamber that provides adjustable warm and humidified air for inhalation. The breathing chamber heats cold air that is breathed in through the face mask during normal breathing, which is worn over the nose and mouth of a person. A temperature gauge monitors temperature for future adjustment of the amount of heat generating current. The air in the chamber is heated for inhalation by a heating pad. The temperature of the Heating Pad and by extension the warm air generated), is regulated/adjusted by increasing or decreasing the current output settings on a controller connected to the power source. Warm and humidified air is produced. The air intake front end includes one or more slots to accommodate N95 filters, dust and pollutant capturing filters, or exercise air flow barriers therein.

A face mask apparatus with N95 filter capability is formed with a breathing chamber that provides adjustable warm and humidified air for inhalation. The breathing chamber heats cold air that is breathed in through the face mask during normal breathing, which is worn over the nose and mouth of a person. A temperature gauge monitors temperature for future adjustment of the amount of heat generating current. The air in the chamber is heated for inhalation by a heating pad. The temperature of the Heating Pad and by extension the warm air generated), is regulated/adjusted by increasing or decreasing the current output settings on a controller connected to the power source. Warm and humidified air is produced. The air intake front end includes one or more slots to accommodate N95 filters, dust and pollutant capturing filters, or exercise air flow barriers therein.

Disclosed are biofeedback methods and devices suitable for providing biofeedback useful for helping a user control an own breathing, for example, to help in inducing deep breathing, and such biofeedback devices further comprising a dispenser for dispensing an inhalable substance.

An oxygen trainer system that includes a circulation body attachable to and in fluid communication with a mouthpiece. A valve cover can be mounted over a valve seat and a one-way valve. The valve can be configured to seal against the valve seat to prevent intake of air during inhalation into the circulation body from one or more exhaust apertures. A knob can be rotatably coupled to a second end of the circulation body. The knob can include an open end with one or more walls extended to a second end opposite the first end and an array of apertures positioned on the one or more walls between the first and second ends. The knob can be rotatable so that at least one of the apertures is alignable with an intake aperture of the system to control an air level resistance of the system.

An oxygen trainer system that includes a circulation body attachable to and in fluid communication with a mouthpiece. A valve cover can be mounted over a valve seat and a one-way valve. The valve can be configured to seal against the valve seat to prevent intake of air during inhalation into the circulation body from one or more exhaust apertures. A knob can be rotatably coupled to a second end of the circulation body. The knob can include an open end with one or more walls extended to a second end opposite the first end and an array of apertures positioned on the one or more walls between the first and second ends. The knob can be rotatable so that at least one of the apertures is alignable with an intake aperture of the system to control an air level resistance of the system.

Systems, devices, and methods for determining a user's lung capacity may employ a sound-producing breathing device and a recording device such as a microphone included in a user electronic device (e.g., smart phone or tablet computer). A user may inhale or exhale through the sound-producing breathing device, thereby producing a sound that is received by the microphone and communicated to a processor. The processor may analyze the received sound recording to determine one or more sound intensity values over, for example, the duration of the received sound and/or points in time within the sound recording. The sound intensity values may then be used to determine the user's lung capacity.

A respiratory therapy device having a diagonal feedback array, and methods for the user thereof.

A respiratory therapy device having a diagonal feedback array, and methods for the user thereof.

An oscillating positive expiratory pressure system including an oscillating positive expiratory pressure device, an adapter coupled to the device, and a control module coupled to the adapter. The control module provides real time information about the use of the device, and provides feedback and storage of the information to improve the use thereof.

Systems, devices, and methods for determining a user's lung capacity may employ a sound-producing breathing device and a recording device such as a microphone included in a user electronic device (e.g., smart phone or tablet computer). A user may inhale or exhale through the sound-producing breathing device, thereby producing a sound that is received by the microphone and communicated to a processor. The processor may analyze the received sound recording to determine one or more sound intensity values over, for example, the duration of the received sound and/or points in time within the sound recording. The sound intensity values may then be used to determine the user's lung capacity.