A wound or incision closure apparatus comprises a first and second panel. Each of the panels comprises a bottom adhesive layer, a medial substrate layer, and an upper load distribution layer which connect the two panels. A sensory or therapeutic element is disposed adjacent, within, or between two or more of the layers. The sensory or therapeutic element can provide sensing and/or therapy for the incision and/or monitor the incision so that the therapy can be customized and updated.

The present invention discloses a mechanical device for joint distraction of the Temporomandibular Joint (TMJ) comprising an upper arm (19) and lower arm (20) joined in a pivotal zone by a mechanical and pivoting component (5) and by a spring (6) or mechanical component between the arms (19) (20). Each arm has a handle (1) of the upper arm (19) and a handle (4) of the lower arm (20). Each arm has an intraoral mouth end for contact with dental surfaces: the upper arm (19) has a tray (2) with a flat support surface for the maxillary teeth flanked by a containment flap (11) of the upper tray; the lower arm (20) has a curvature until its end, with a customized surface (3) for supporting the lower teeth. It presents a mechanical component (13) that limits the extent of movement and force applied by the patient or clinician.

An embodiment of a system for treating sleep apnea includes a collar, pump, motor, sensor, memory, and controller, which is configured to store, in the memory, information related to sleep-apnea events or sleep-apnea treatment, experienced by the subject. For example, the controller can obtain, and store in the memory, information related to sleep-apnea events, and the controller, or another computing system, can correlate this information with the subject's lifestyle choices, and can recommend lifestyle changes to improve the subject's sleep apnea. Furthermore, the controller can obtain and store, in the memory, information related to usage and settings of the sleep-apnea system, and the controller, or another computing system, can correlate this information with the subject's wellbeing, and can recommend changes in the usage or the settings of the sleep-apnea system that can improve the subject's wellbeing.

Systems, and methods relate to a medical device receiving a treatment parameter operating point within a first operating region defined by a first set of operating points for which automatic incremental adjustment of a parameter in the current operation is permitted. In an illustrative example, incremental adjustment may use artificial intelligence based on patient feedback and sensor measurement of outcomes. Some exemplary devices may receive a request to alter the current treatment parameter operating point to a second treatment parameter operating point outside the first operating region and in a second operating region in a known safe operation zone, bounded by a known unsafe zone unavailable to the user. In the second operating region, some examples may restrict the step size of incremental adjustments requested by the user. Data may be collected for cloud-based analysis, for example, to facilitate discovery of more effective treatment protocols.

The invention provides for a medical apparatus (100, 200, 300) for treating cells of a subject comprising at least one transducer (102, 224) with a vibrating surface (116). The transducer further comprises an applicator (118, 600) for attaching the vibrating surface to an outer surface of the subject (108, 218). The transducer is operable to vibrate at a frequency between 10 Hz and 1000 Hz. The medical apparatus further comprises a controller (104, 222, 230) for controlling the vibration of the transducer. The controller is operable for causing the transducer to vibrate for greater than a predetermined period of time for treating the cells. The predetermined period of time is greater than one hour.

Active fabrics can be created by combining active and passive materials. Active materials with shape memory or other actuation characteristics can generate compression or dynamic fit, and the level of compression and/or change in fit can be determined by setting a knit index, wire diameter, and garment ease, or fit in relation to the body. Maximum compression can be set not only by varying physical properties of the knit structure but by built-in circuit breaking technologies, or by segmentation and control of the garment by a controller. In some embodiments, additive manufacturing can be combined with traditional textile equipment (e.g., circular knitting machine). Uniquely functional or active textiles can be made from additively manufactured, heterogeneous filaments. Yarn-like filament with varying properties (such as elasticity, stiffness, conductivity, activation, or surface properties) can be additively manufactured. This filament can be formed into a textile or garment with functional properties that are a results of emergent interactions between the heterogeneous filament components.

A multi-mode personal massaging including a sensor unit configured to detect one or more biofeedback signals from a user of a personal massaging device or a partner is disclosed. The system can further include a controller configured to analyze the one or more biofeedback signals, and determine one or more corresponding and modifiable outputs stored in a memory, based on the one or more biofeedback signals. The system can further include a massaging unit configured to output the one or more outputs determined by the controller, based on the one or more biofeedback signals.

A soft wearable medical device may comprise a soft compliant pumpactuator or actuators at least partially disposed in a glove assembly. Responsive to a detection of a tremor, such as an ataxia tremor, an actuator at least partially inflates to provide a stabilizing counterforce and reduce or eliminate the tremor.

A vibration module for applying vibrational tractions to a wearer's skin is presented. Use of the vibration module in headphones is illustrated for providing tactile sensations of low frequency for music, for massage, and for electrical recording and stimulation of the wearer. Damped, planar, electromagnetically-actuated vibration modules of the moving magnet type are presented in theory and reduced to practice, and shown to provide a substantially uniform frequency response over the range 40-200 Hz with a minimum of unwanted audio.

Described herein are interactive devices that mimic a portion of a human male and a female genitalia. The male device includes a unique bead drive assembly for providing an extending and retracting motion. Also included on the male device is a massager sub-assembly able to inflate and deflate while being able to slide along a shaft of the male device. The female device includes a clamshell constrictor having an inflation mechanism that is able to provide a squeezing motion as well as being able to slide back and forth within the body of the female device. Also disclosed herein are method of communication and interaction between a pair of interactive devices or multiple interactive devices. Finally, methods of managing interactive sessions between multiple interactive devices are also described.