The material contained in this disclosure pertains to robotics related to convertible robots incorporating telecommunication elements. Embodiments of the system and apparatuses described can facilitate instant communication with family and friends, health status monitoring and support from caregivers; and promote optimal health, longevity, and independent living by providing high-tech economical solutions at each stage of the aging process. Embodiments of the system and apparatuses may be converted from an independent telecommunications robot, to a robotic walker, to a robotic wheelchair.

A portable therapeutic device includes a portable body having a recessed central region and a raised outer peripheral edge surrounding the recessed central region and directly engaged with the recessed central region, a plurality of massage balls seated at the recessed central region and spaced inside a perimeter of the raised outer peripheral edge, a thermal-conductive element channeled inside the outer peripheral edge and spaced from the recessed central region, and a power source communicatively coupled to the massage balls and the thermal-conductive element.

A human-interface device and a guiding apparatus for a visually impaired user including such human-interface device. The human-interface device includes a tactile module arranged to provide a set of haptic signals to a user, wherein the tactile module has a plurality of tactile units each arranged to provide at least a first haptic signal and operable to cooperate with one or more of other tactile units to provide different haptic signals.

A device (900) includes a leg engaging section (101) and a foot engaging section (102 intersecting at a heel receiver (103). The leg engaging section and the foot engaging section defining a leg insertion aperture (104). A first compression wrap member (301) and a second compression wrap member (302) extend from the leg engaging section. An inflatable bladder (501) can be disposed along the leg engaging section between the leg insertion aperture and a compressible cushion layer (902). The inflatable bladder can be selectively inflatable through a connection tube (502) exiting the inflatable bladder at a non-orthogonal angle (504) relative to an edge (507) of the inflatable bladder. The leg engaging section can define at least one channel (1002) to permit the connection tube to exit the device.

A multi-sensory media experience delivery platform includes a vibroacoustic therapy bed that delivers a multi-sensory media experience locally stored, streaming, on-demand, or real-time signals. The vibroacoustic therapy bed drives a plurality of sensory output devices based on a set of sensory output channels to produce sounds, vibrations, light patterns, or other sensory outputs. The channels may be derived from dedicated signals created for a specific sensory output device or may be derived from an audio file or other general set of waveforms. The multi-sensory media experience may be customized to a user based on user profile data, metadata associated with the multi-sensory media experience, or biometric data. Furthermore, users can create customized multi-sensory media experiences from libraries of sounds or other media.

The present invention generally relates to improved medical devices, systems, and methods, with exemplary embodiments providing improved cooling treatment probes and cooling treatment methods and systems. In some embodiments, freezing of the skin may be desirable to effect the hypopigmentation of the skin of the patient. Generally, embodiments may limit supercooling of the skin of the patient during a cooling treatment. Additionally, embodiments may limit adverse side effects such as hyperpigmentation. It has been found that the freezing behavior (frequency and time to freeze) can be modified by adjusting the thermal parameters of the cooling applicator. Accordingly, in some aspects of the invention, a method of treating the skin may be provided where the thermal parameters of the cooling applicator are adjusted during treatment.

Methods and systems for providing pain therapy by utilizing cold/heat-assisted distributed vibration therapy. The pain therapy device includes a plurality of vibration motors that are located along a grid. The device is portable and can be adaptable to the body part requiring pain therapy.

A pneumatic compression assembly that includes a sleeve having an outer layer and an inner layer that defines a sleeve interior configured to receive a body part of a user, and at least a first vibration assembly configured to provide vibration to the body part of the user. A plurality of inflatable compartments are arranged longitudinally along the sleeve between the inner layer and the outer layer. The first vibration assembly includes a plurality of vibration motors positioned between the inner layer and the outer layer of the sleeve.

Systems and methods for exerting forces on a body, including a support structure defining a space and a plurality of surface contacting units that are configured to exert force upon the body, such that the weight is distributed away from the primary weight bearing regions to non-weight bearing regions of the body, or vice versa, without exerting significant shear or frictional forces on surfaces of the body. The systems and methods may be used to exert forces to cause fluid shift in different compartments of the body. Applications include treatment of various disease conditions including pressure ulcers, heart failure, high blood pressure, preeclampsia, osteoporosis, injuries of spine and to slow microgravity-induced bone and muscle loss. The systems and methods may be used to simulate gravity, weightlessness or buoyancy, in rehabilitation medicine. The system may include a chair, bed, a wearable suit or an exoskeleton.

In an embodiment, a compression garment can include one or more of a flex frame, a shape memory material, a backing, and a control module. In some variations, the flex frame can include a set of support regions, a set of cutout regions, a set of bridges, one or more terminals, and one or more rotation points. In some variations, the compression garment 100 can further include a fabric sleeve, one or more fasteners, a power module, and/or any other suitable component. The compression garment functions as a compression device (e.g., to improve circulation, enhance muscle recovery, etc.), and can additionally or alternatively function as a passive compression device, a heating and/or cooling device, or perform any other suitable functionality.