An evaluation system including a hardware system for collecting real-time data for evaluating sleeping comfort performance of a bedding system is disclosed. The hardware system includes a thermal and moisture comfort measurement system, a thermal and moisture comfort control system, a biomechanical comfort control system, and a biomechanical comfort measurement system. The evaluation system also includes a computational system having a processor and a tactile database, and a portable device. The computational system is configured to receive and process the real-time data from the hardware system, and is communicatively connected to the portable device for transmitting real-time data for evaluating the bedding system and adjusting the hardware system. A mobile application executable on the portable device is configured to collect subjective opinion of the sleeper using questionnaires, and the processor is configured to perform combined analysis of the subjective opinion and the real-time data of the bedding system.

A portable patient turning device is provided comprising an inflatable mattress cover having a planar surface configured to substantially cover the surface of a bed, and a control unit connected to the inflatable mattress cover by one or more air hoses. The inflatable mattress cover further comprises a first inflatable chamber proximate to and extending along a left edge of the planar surface, a second inflatable chamber proximate to and extending along a right edge of the planar surface, and a spine cushion positioned between the first inflatable chamber and the second inflatable chamber and extending along a middle portion of the planar surface for at least a portion of the length of the first inflatable chamber and second inflatable chamber.

Described herein are systems and apparatuses for enhanced comfort through contact pressure reduction. In particular, the systems and apparatuses disclosed herein prevent or otherwise mitigate pressure by actively orienting a patient over an anatomy-specific pressure-mitigating contact surface on which the patient rests. A pressure-mitigating contact portion of the contact surface includes a plurality of independently pressurized chambers configured in a specific geometric pattern that is designed to mitigate contact pressure between a support surface (e.g., bed or chair) and a specific anatomic region of a patient’s body when the specific anatomic region of the patient’s body is oriented over an epicenter of the geometric pattern. Additionally, a plurality of elevated side support portions and a wedge interconnected on the base material are configured to actively orient the specific anatomic region of the patient’s body over the epicenter of the geometric pattern.

A support platform supports a mattress. The support platform includes legs. Force sensors are coupled to the legs or to the support platform. The force sensors are configured to sense a force applied to each leg or support platform. A controller is configured to receive at least one force stream from at least one of the force sensors. The at least one force stream represents a force sensed by the force sensor. The controller is configured to, in responses to receiving the at least one force stream, determine a sleep parameter from the following group of sleep parameters: bed presence, weight, heart rate, respiration rate, and motions. The controller is configured to output at least one or more of those parameters to an end user.

An air-conditioned mattress includes a mat device, a cover device, and an air-conditioning device. The mat device includes a first mat configured as a three-dimensional structure made from a plurality of elastic thermoplastic filaments that are randomly tangled with each other. The thermoplastic filaments are fixedly connected at contact portions of the thermoplastic filaments in a way that through holes are formed at non-contact portions of the thermoplastic filaments. The cover device covers the mat device and contacts the top surface of the first mat, and the first mat is more air-permeable than the cover device. The air-conditioning device is disposed inside or outside the mat device and provides heated air flow or cooled air flow into the first mat.

The dry-immersion bed of the present invention is suitable for intensive care units (ICUs) and fulfills the function of providing treatment for diseases such as capillary leak syndrome. The dry immersion bed fulfills the function of recovering cardiovascular physiology by normalizing the systemic distribution of water, albumin and electrolytes, and improving lymphatic drainage, venous return, cardiac output, cell metabolism and immunity.

A person support system including a person support surface. The person support surface may include a blower subassembly and a surface foundation layer. The person support surface may further include a turn assist bladder layer, a working cushion layer, and a support cushion layer positioned between a first lateral side bolster and a second lateral side bolster of the surface foundation layer, a foot bladder layer positioned proximally adjacent the surface foundation layer, and a microclimate management (MCM) layer, where the blower subassembly may be configured to supply air to the MCM layer. A top encasement portion of the person support surface may be removably coupled to a bottom encasement portion of the person support surface to enclose such included components within the person support surface.

Introduced here are methods, apparatuses, and systems for mitigating the contact pressure applied to a human body by the surface of an object, such as a chair, bed, or table. A pressure-mitigation apparatus can include a series of chambers whose pressure can be individually varied. When placed between a patient and a contact surface, a controller can vary the contact pressure on the human body by controllably inflating one or more chambers, deflating one or more chambers, or any combination thereof. By monitoring the pressure in each chamber over time, the controller can also gain an enhanced understanding of movement(s) performed by the human body when positioned on the pressure-mitigation apparatus.

An apparatus, method for the apparatus, and system for using the apparatus that comprises an air bladder formed of a baffle assembly with a plurality of equal-length flaps secured to the inside of an impermeable flexible outer layer and having a port secured to the outer layer to allow air to flow into and out of the air bladder, such that when the air bladder is inflated, the baffle assembly supports the shape of the air bladder.

A patient support apparatus is provided with selective stiffening features. The patient support apparatus may include a support substrate defining a patient support surface. The support substrate may include a magnetorheological material providing selective reinforcement support of at least a portion of the patient support surface to redistribute pressure about a surface of a patient. The magnetorheological material may include a distribution of ferromagnetic particles disposed within a polymeric material and exhibits a shape conforming, variable stiffness in response to exposure to a magnetic field. A controller may be provided and configured to create a correlation of patient specific data with an optimal stiffness or inflection force deflection (IFD) of the patient support surface, and generate a strength of the magnetic field based on the correlation.