An ergonomic inflatable decubitus positioning support for medical use has a central opening, shaped for at least abdominal reception of a patient in ventral decubitus, and an inflatable load-bearing peripheral structure surrounding the central opening. This inflatable load-bearing peripheral structure extends according to a mainly rectangular inflatable shape with two lateral portions and two transversal portions, shaped in such a way that one of the two transversal portions, the so-called upper transversal portion, has at least locally, when the load-bearing peripheral structure is inflated, an inflated cross-section of smaller dimensions than those of the inflated cross-sections of the two lateral portions for an upper thoracic reception of the patient.

A microclimate management system including a person support surface including one or more sensors, a fluid supply device coupled to an inlet of the person support surface and configured to supply fluid to an outlet the person support surface, and a controller configured to detect an inlet condition value at the inlet of the person support surface, detect an outlet condition value at the outlet of the person support surface, determine a difference between the inlet condition value and the outlet condition value, and transmit a first alert in response to determining that a rate of change of the difference between the inlet condition value and the outlet condition value is below a lower condition threshold.

Described herein are devices, systems, and methods relating to making individuals comfortable when in contact with surfaces (e.g., seats and beds) including preventing pressure injuries on subjects. In embodiments, disclosed herein are pressure injury prevention systems comprising actuator assemblies that can simultaneously provide immersion and offloading of pressure while allowing a subject to retain balance. In other embodiments, moisture control devices and/or sensing networks can be used in conjunction with said actuator assemblies to prevent pressure injuries in a subject in need thereof. In embodiments, also described herein are computing devices and applications that alert a manual intervention or trigger an automated intervention between the individual and the intervention surface based on a risk determination. Such interventions can send instructions to the system to relieve pressure and/or moisture at one or more interface locations on the interface surface between the system and a subject according to a set of rules based on a predetermined profile, data collected continuously in real time, or both.

A dynamic-directional seat pad which contains an inflating element (1), wherein a plan view of the inflatable element (1) contains a back side (4), concave sides (2) and a concave front side (3).

Provided is an automatically inflatable patient transfer air mattress designed to enable immobile persons, such as patients with mobility difficulty, to be rapidly laid and transferred thereon in the event of a disaster or an accident, prevent an injury to the patient caused by a falling object dropping from a ceiling or any other place, and reduce impact in the case of movement via stairs. The automatically inflatable patient transfer air mattress includes a main mattress portion forming a plate shape having a predetermined thickness when charged and inflated with air, a protective cover portion provided on one side surface of the main mattress portion in a longitudinal direction, and configured to cover one surface of the main mattress portion when deployed, and a cushion wheel unit disposed on a bottom portion of the main mattress portion to absorb impact from below.

A mattress support assembly includes a mattress cover that has a coupling feature. A support casing defines an attachment feature and is selectively coupled to the mattress cover via the coupling feature. A support member is operably coupled to the attachment feature of the support casing. The support member has a load surface, a base surface, and an expandable body defined between the load surface and the base surface.

Apparatus and methods for adjusting a support to a body are described in which a portable support assembly may be worn or used by a bed-stricken or wheel-chair restricted individual around particular regions of the body where pressure ulcers tend to form. The portable support assembly may generally include adjustable supports which conform the assembly to the patient's body and which also help to distribute one or more fluid pad assemblies relative to the body. The support assembly may be incorporated into a design for a wheelchair or a bed.

A fluid source comprises a connector assembly for connecting a fluid supply device to either a first therapy device or to a second therapy device. A controller automatically provides a first configuration of a user interface associated with a first therapy when a supply connector is operatively coupled to the first therapy device and provides a second configuration of the user interface associated with a second therapy, different than the first configuration, when the supply connector is operatively coupled to the second therapy device. A hanger assembly is provided to hang the fluid source on different support structures. The fluid source also comprises a housing with a watershed region to shed liquid away from the user interface.

Provided are a method for managing bedsores based on an artificial intelligence model and an electronic device performing the same. According to an exemplary embodiment, a method for managing, by an electronic device, bedsores based on an artificial intelligence model may include: acquiring user information of a user who uses a smart mat connected to the electronic device; acquiring at least one type of sensor data from the smart mat connected to the electronic device; when at least one type of sensor data is input, acquiring the bedsores management contents for the user from the artificial intelligence model by inputting the sensor data into the artificial intelligence model that outputs the bedsores management contents for each user according to the user information; and outputting the acquired bedsores management contents.

An automatically adjusting comfort method includes measuring pressure applied by a user via a pressure-sensor array, determining a pressure profile based on measurements from the pressure-sensor array, comparing the pressure profile to a first limit, determining a cumulative pressure profile over a predetermined duration, comparing the cumulative pressure profile to a second limit, and adjusting one or more of a plurality of adjusting mechanisms configured to alter the pressure profile for increased comfort of the user when the pressure profile exceeds the first limit or the second limit. An automatically adjusting comfort system includes a pressure-sensor array communicatively coupled to a controller for determining a cumulative pressure profile over time, and a plurality of adjusting mechanisms configured to alter the pressure profile to increase a user's comfort, wherein the controller automatically adjusts one or more of the plurality of adjusting mechanisms based on the cumulative pressure profile.