In methods for treating a patient, a time varying magnetic field is applied to a patient's body and causes a muscle contraction. The time-varying magnetic field may be monophasic, biphasic, polyphasic and/or static. The method may reduce adipose tissue, improve metabolism, blood and/or lymph circulation. The method may use combinations of treatments to enhance the visual appearance of the patient.

A system and method for automatically producing and monitoring a cryotherapy session within a chamber includes a plumbing system coupled to the chamber for cooling the chamber. A central controller may be coupled to the plumbing system. The central controller may be operable for: initiating the cryotherapy session within the chamber with a cryogenic gas flowing through the plumbing system for cooling the chamber to a first temperature; determining if the first temperature has been reached within the chamber; determining if a check-in command has been received for the cryotherapy session; and stopping the cryotherapy session after a predetermined period of time. The central controller may also monitor a cooling rate for the chamber and a heater associated with the cooling rate.

Technologies are described herein for cooling systems. In some aspects, a cooling system includes an adsorbent chamber and an evaporator. The cooling effect caused by the evaporation of refrigerant in the evaporator is applied to a patient on a support device, such as a gurney or stretcher, cooling the patient. The evaporated refrigerant is adsorbed by absorbent in the adsorbent chamber.

The invention concerns a fluid circulation and mixing system (100) for a cryocabin arrangement used in a whole-body cryotherapy treatment and a related cryocabin arrangement (120), including a system (100) and a cabin (101) for accommodating a patient. The fluid circulation system (100) includes appliances for effective mixing of cryogenic liquid with ambient air and/or for preventing the cryogenic liquid from settling down on the bottom of evaporator. The cryocabin arrangement (120) further includes appliances for generating and maintaining a fluidic whirl (vortex) within the patient cabin, thus enhancing an overall efficiency of the cryotherapy treatment in general and improving beneficial effects of each individual cryotherapy treatment session.

One variation of a method for delivering a digital medicine experience to a user includes: loading the digital medicine experience at a sensory immersion vessel; calculating a target value of a bioindicator of the physiological state of the user, the target value of the bioindicator corresponding to a target physiological state of the user; at an initial time, rendering sensory representations of a set of elements in a multi-sensory virtual environment within the sensory immersion vessel at an initial progression rate; at a time during the digital medicine experience, succeeding the initial time, measuring a value of the bioindicator; calculating a progression rate through the digital medicine experience based on a difference between the value of the bioindicator and the target value of the bioindicator; and at a second time succeeding the time, rendering sensory representations of the set of elements in the multi-sensory virtual environment at the progression rate.

An invention concerns a moisture control in a cryotherapy system and creating of snow mist. The system comprises a treatment chamber for at least one person, a closable entry to the treatment chamber, and a cooling apparatus. The cooling apparatus comprises an evaporator configured to function with a coolant and a valve for flow control of the coolant, wherein the evaporator is placed in the treatment chamber and the valve is coupled to the evaporator. The system further comprises a ventilation aperture for obtaining an additional air into the treatment chamber, the ventilation aperture being placed far from the evaporator to such spot that the additional air flows from the ventilation aperture towards the centre of the treatment chamber and simultaneously mixes with an air included in the treatment chamber so that water vapour of the additional air changes from gas to solid ice crystals and forms snow mist in the treatment chamber.

One general aspect includes a system to mitigate motion sickness/emesis, the system including: a memory configured to include one or more executable instructions and a processor configured to execute the executable instructions, where the executable instructions enable the processor to: in response to an activation of a motion-equalizing device installed in an interior of a vehicle, provide electric stimulus to a vehicle occupant via the motion-equalizing device, where the electric stimulus is designed to mitigate one or more symptoms of motion sickness and/or emesis for the vehicle occupant.

Various systems and devices are provided for determining a weaning readiness for weaning a patient from a thermoregulated microenvironment. In one example, a method includes receiving a plurality of current patient parameters of a patient housed in a thermoregulated microenvironment, applying a weaning model to the plurality of current patient parameters to generate a weaning index representing a likelihood that the patient will be successfully weaned from the microenvironment if weaned at that time, the weaning model trained to correlate the current patient parameters with the likelihood based on historical data of prior patients and known outcomes for those prior patients, and outputting the weaning index for display on a display device and/or for storage in a medical record of the patient.

The present disclosure relates to thermal contrast therapy systems, and automated thermal contrast therapy devices configured to interact with such systems and to perform customized thermal contrast therapy treatment sequences. Treatments may be prescribed by a treatment provider or selected by a user of a thermal contrast therapy device associated with such a system. In some embodiments, a thermal contrast therapy device may be configured to receive an indication from one or more temperature sensors and/or flow meters and to effect a desired measure of heat transfer during treatment, for example, by automatically adjusting the temperature and/or flow rate of the heat transfer fluid. In some embodiments, a thermal contrast therapy device may be configured to receive an indication of one or more physiological parameter values and to perform a customized thermal contrast therapy treatment sequence based, at least in part, on the one or more physiological parameter values.

A method, connector and system for obtaining an indirect measurement of a parameter in a patient with a total liquid ventilation (TLV) system. At least one parameter measurement is obtained of a liquid taken in the TLV system comprising an endotracheal tube having a distal end inserted in a patient's trachea. At least one flow measurement is obtained of a liquid taken in the TLV system. Considering a fluid model of the TLV system, the at least one parameter measurement and the least one flow measurement are processed into the indirect measurement of the parameter in the patient. The indirect measurement may be a temperature or pressure. The temperature can be a lung temperature, a blood temperature or an organ temperature. The pressure may be a tracheal pressure or an alveolar pressure.