In one aspect of the invention, a method of charging a medical device includes receiving radiofrequency signals from a remote machine remote from the medical device via a receiver of the medical device. The method includes converting the radiofrequency signals into electrical energy via a generator of the medical device. The method includes storing the electrical energy in an energy cell of the medical device. The method also includes powering a power consumption component of the medical device by transmitting the energy from the energy cell to the power consumption component.

The disclosure relates to a sensor arrangement for an injection device to determine an axial position of at least one device component of the injection device inside a housing of the injection device. The sensor arrangement includes an elongated member located inside the housing, extending in an axial direction and having at least a first section and a second section of different magnetization. The first and second sections are separated in an axial direction. The sensor arrangement also includes at least one magnetic sensor element attached to the housing to detect the axial position of at least one of the first and second sections.

A dialysis system (e.g., a hemodialysis (HD) system) can be designed to operate in alternative environments, such as disaster relief settings or underdeveloped regions. The dialysis system can include a solar panel for generating electricity to power the dialysis machine and an atmospheric water generator for extracting water from ambient air. The extracted water can be used to generate dialysate and saline on-site. One or more of the components of the dialysis machine can be discrete components that are configured to facilitate fast shipping and simple on-site assembly (e.g., at a remote location). In some implementations, the discrete components may be configured to be attached to an existing dialysis system (e.g., a dialysis system designed for operation in a traditional environment) to permit the dialysis system to operate in an alternative environment.

Some embodiments have a pump assembly mounted to or supported by a dressing for reduced pressure wound therapy. The dressing can have visual pressure, saturation, and/or temperature sensors to provide a visual indication of the level of pressure, saturation, and/or temperature within the dressing. Additionally, the pump assembly can have a pressure sensor in communication with the flow pathway through the pump, and at least one switch or button supported by the housing, the at least one switch or button being accessible to a user and being in communication with the controller. The pump assembly can have a controller supported within or by the housing, the controller being configured to control an operation of the pump. The pump can be configured to be sterilized following the assembly of the pump such that all of the components of the pump have been sterilized.

In one aspect the present disclosure relates to a sensor for measuring at least one physical or chemical parameter of a cartridge or syringe filled with a liquid substance. In further aspects the disclosure relates to a cartridge equipped with such a sensor as well as to a drug delivery device equipped with such a cartridge, wherein the sensor comprises:

a planar flexible foil arrangeable to an outer circumference of a barrel of the cartridge or syringe,

at least a first and a second measuring electrode arranged on said foil, and at least a first and a second contact electrode arranged on said foil,

wherein the first contact electrode is connected to the first measuring electrode and wherein the second contact electrode is connected to the second measuring electrode.

A dialysis system (e.g., a hemodialysis (HD) system) can be designed to operate in alternative environments, such as disaster relief settings or underdeveloped regions. The dialysis system can include a solar panel for generating electricity to power the dialysis machine and an atmospheric water generator for extracting water from ambient air. The extracted water can be used to generate dialysate and saline on-site. One or more of the components of the dialysis machine can be discrete components that are configured to facilitate fast shipping and simple on-site assembly (e.g., at a remote location). In some implementations, the discrete components may be configured to be attached to an existing dialysis system (e.g., a dialysis system designed for operation in a traditional environment) to permit the dialysis system to operate in an alternative environment.

A monitoring device provided for monitoring the delivery of fluids through a drip chamber. The device includes an electromagnetic radiation (EMR) source and an EMR detector. The device includes a tubing set mount for receiving a flange or other portion of a tubing set, such that fluid falling through the drip chamber of the tubing set is detected by the detector. The device is operable to determine one or more rolling averages based on intervals of drops or time.

Some embodiments are directed to a compliance monitor for monitoring patient usage of a dry powder medicament delivery device. The medicament delivery device includes a store of medicament housed within a main body portion, and a base portion which is rotatable with respect to the main body portion. The medicament delivery device also includes a medicament dispenser for dispensing a dose of medicament into an inhalation chamber, a mouthpiece through which the dose of medicament may be inhaled by a user, and a replaceable cap. The compliance monitor includes a first portion for receiving and/or retaining the base portion of the medicament delivery device, and a second portion for releasably securing the medicament delivery device to the first portion.

The present disclosure relates to systems and methods for producing a consistent and effective herbal vapor. A sealed container pod may include a chamber wall defining an internal volume within which a pre-processed herbal composition (e.g., cannabis) is located. The container pod may include filters for the vapor produced from the herbal composition. The container pod may also include a support member for holding and evenly distributing the herbal composition within the internal volume during vaporization. A vaporizer may be configured to obtain information regarding the contents of the herbal composition. The vaporizer may expose the herbal composition to an automated series of timed temperature adjustments specifically tailored for producing a desirable herbal vapor. The herbal vapor may be collected into a bag and/or canister for subsequent consumption.

The present disclosure provides personal multimedia pods that convert from an enclosable premium theater system with seating for one or more users to an unenclosed chair and/or to an output audio/video device capable of connecting (e.g., wirelessly connecting) to other audio/visual equipment.