A patient support includes a cover defining an interior region, an air permeable first layer located in the interior region, and a support layer located beneath the air permeable first layer. A pressure sensing layer is located underneath the support layer. At least one air supply is coupled to the support layer. A controller is coupled to the air supply and to the pressure sensing layer. The controller controls inflation and deflation of the support layer in response to a signal from the pressure sensing layer.

An air distribution pad comprises an upper layer, a lower layer, and a spacer material located between the upper layer and the lower layer, the spacer material configured to allow air to pass therethrough. An air distributor is configured to distribute air to the spacer material, wherein the air distributor comprises a port configured to receive an air hose, wherein the port is directed laterally sideways from the air distributor. At least one joining structure is coupled to the upper layer and the lower layer, the at least one joining structure providing one or more channels formed through the spacer material in fluid communication with the air distributor. The one or more channels are configured to direct generally laterally flowing air from the port of the air distributor to a generally longitudinal direction along the at least one channel.

In various embodiments, a support system includes a multi-layer support system with a number of layers. Systems and methods of removing moisture vapor from an environment surrounding patient are disclosed that accomplish such removal.

In various embodiments, a support system includes a multi-layer support system with a number of layers. Systems and methods of removing moisture vapor from an environment surrounding patient are disclosed that accomplish such removal.

A patient support system for providing improved guidance and/or troubleshooting with respect to a patient support apparatus. A user interface is configured to receive inputs from a user, and an information output device is configured to provide instructions to the user. A controller determines a guidance protocol for the user based on the inputs. The guidance protocol comprises user-performed actions to be performed by the user in response to the instructions provided to the user with the information output device. The guidance protocol may be initiated and/or determined based on a troubleshooting request and/or an uncorrelated sequence of user inputs. At least one of the user-performed actions may be configured to control operational functions of a patient support apparatus. Methods for improving patient care by providing the guidance and/or troubleshooting are also disclosed.

A patient support includes a cover defining an interior region, an air permeable first layer located in the interior region, at least one air supply coupled to the first layer to provide air flow through the first layer, a support layer located beneath the air permeable first layer, a pressure sensing layer located underneath the support layer, and a controller coupled to the air supply and to the pressure sensing layer. The controller controls air flow through the first layer in response to a signal from the pressure sensing layer.

The present disclosure relates to a patient support which can be used in a bed or flat surface and in particular to a system and method for support and offloading of the body and for turning and repositioning of a patient in a bed or on a flat surface. Features of the disclosure also relate to markings and other indicators used on the patient support which help guide caregivers in the proper use and correct patient positioning on the patient support.

A patient support includes a cover defining an interior region, an air permeable first layer located in the interior region within the cover, a first air supply coupled to the first layer to provide air flow through the first layer, air bladders including a head zone and a seat zone located beneath the first layer, a first sensing assembly located beneath the head zone, a second air supply coupled to the air bladders to selectively inflate and deflate the air bladders, and a controller. The controller is coupled to the first and second air supplies to control inflation and deflation of the air bladders and to control air flow through the permeable layer. The controller also receives a signal from the first sensing assembly, determines whether the patient support is occupied, and adjusts air flow through the first layer based on the signal from the first sensing assembly.

Mattresses and cushions, methods of making mattresses and cushions, and patient supports comprising a mattress and/or a cushion. At least some embodiments of the present mattresses and cushions comprise a body with air-impermeable material having a plurality of openings, and a cover sheet comprising air-permeable and liquid-impermeable material covering at least a portion of the plurality of openings and coupled to the body by a liquid-impermeable welded seam encircling the covered one or more openings.

A multi-layer sleeping pad, which includes an outer air cushion, an inner air cushion and a first cushion pad. The outer air cushion is provided with a first cavity. The inner air cushion is arranged in the first cavity. The first cushion pad is arranged between an inner top of the outer air cushion and an outer top of the inner air cushion.