The present disclosure provides a method of positioning a patient. The patient is provided on a support surface, an inflatable positioning mattress disposed between the patient and the support surface. Air flow into the inflatable positioning mattress is initiated to inflate the inflatable positioning mattress. A downward force is applied on the inflatable positioning mattress proximate to a first side of the support surface. A portion of the inflatable positioning mattress proximate to a second side of the support surface is raised. At least one wedge is positioned beneath the inflatable positioning mattress. Subsequently, the patient is lowered onto the at least one wedge.

A mobility device that includes support assemblies that may be secured to feet, legs, thighs, and torso of a user. An exemplary mobility device may further include an actuator that may be coupled with the exemplary support assemblies and may actuate rotational movements of the exemplary support assemblies with respect to each other. Such movement of support assemblies may accordingly move respective limbs of a disabled user. An exemplary mobility device may allow for a user to change position from a lying position to a standing position or from a standing position to a sitting position, which may significantly increase mobility of a disabled user. An exemplary mobility device may further include an exemplary wheeled base that may allow a disabled user to further move around.

An improved wheel for a mobility apparatus designed is disclosed herein. The wheel conforms to obstacles in the ground, creating a smoother walking experience. The inner web of a tire of the wheel preferably consists of polygonal reliefs offset from each other over multiple layers in a radially symmetric pattern to create a web which naturally compresses to absorb shock from obstacles. The tire's inner core preferably consists of a hexagonal membrane that extends parallel to the axel of the tire and extends out of each side of the wheel such that it is visible.

A patient support apparatus for use in ambulating a patient to a floor surface. A patient support deck is operatively attached to a base and has a seat section, a leg section, and a pair of foot sections. The patient support deck is operable between a bed configuration and a chair configuration. In the bed configuration, the seat section, leg section, and foot sections support the patient in a flat position. In the chair configuration, the seat section supports the patient in a seated position, the leg section is articulated adjacent to the floor surface, and the foot sections are articulated relative to the leg section and out of support of the patient. A handle to facilitate patient ambulation is coupled to each of the foot sections, and the handles are arranged to facilitate patient ambulation when the patient support deck is in the chair configuration.

The present invention is to provide a fiber for artificial hair which can freely change the hairstyle at home while maintaining the wave shape of the fiber. A fiber for artificial hair having a bending rigidity maintaining ratio defined by formula (1) is 40 to 80% and a heat shrinkage ratio defined by formula (2) is 0.0 to 5.0% is provided.
bending rigidity maintaining ratio (%)=100{(bending rigidity in a state after conditioning for 24 hours at 30 C.90% RH)/(bending rigidity in a state after conditioning for 24 hours at 23 C.50% RH)}(1)
heat shrinkage ratio (%)=100{(length before heat treatment)(length after heat treatment for 5 min at 155 C.)}/(length before heat treatment)(2).

A system includes a first radiation source configured to provide therapeutic radiation in a treatment area and an automated patient transport configured to transport a patient from a preparation area to the treatment area, to position a treatment volume in the patient relative to the therapeutic radiation from the first radiation source, and to support the patient in receiving the therapeutic radiation. The automated patient transport comprises a first detector configured to detect a first patient positioning indicator located in and/or on the patient indicative of a position of the treatment volume.

The present disclosure pertains to a ventilator mount system. The system includes a ventilator mount configured to mount a ventilator thereon; a platform configured to be carried by a stand; and a releasable lock assembly configured to affix the ventilator mount to the platform. In some embodiments, the lock assembly is configured to be moved between a locked position and a release position. In some embodiments, the ventilator mount is releasable from the platform when the lock assembly is moved from the locked position to the release position.

A modular patient support system for use in ambulating a patient across a floor, comprising a primary module and a secondary module. The primary module has a primary base and a primary deck arranged for movement relative to the primary base, and the primary deck defines a first patient support area. The secondary module has a secondary base adapted for movement along the floor relative to the primary base and a secondary deck arranged for movement relative to the secondary base. The modular patient support system is operable between a docked configuration where the secondary deck cooperates with the primary deck to define a second patient support area larger than the first patient support area, and an undocked configuration where the secondary module is spaced apart from the primary module to facilitate ambulation concurrent with the secondary module across the floor away from the primary module.

The present disclosure relates generally to systems, methods, and devices for interpreting neural signals to determine a desired movement of a target, transmitting electrical signals to the target, and dynamically monitoring subsequent neural signals or movement of the target to change the signal being delivered if necessary, so that the desired movement is achieved. In particular, the neural signals are decoded using a feature extractor, decoder(s) and a body state observer to determine the electrical signals that should be sent.

The present disclosure relates generally to systems, methods, and devices for interpreting neural signals to determine a desired movement of a target, transmitting electrical signals to the target, and dynamically monitoring subsequent neural signals or movement of the target to change the signal being delivered if necessary, so that the desired movement is achieved. In particular, the neural signals are decoded using a feature extractor, decoder(s) and a body state observer to determine the electrical signals that should be sent.