Introduced are methods and systems for monitoring a person's sleeping patterns, and detecting episodes of sleeping disorders such as snoring and sleep apnea. In one embodiment, a sensor strip attached to the mattress monitors the user's breathing, and detects signature frequencies corresponding to snoring and sleep apnea. Once a sleeping disorder is detected, a notification can be sent to a device associated with the user, or the user's bed can be automatically adjusted to alleviate the sleeping disorder.

Embodiments provide a person support system including support pads having cooling features. According to one embodiment, a person support system may include a longitudinal frame comprising at least one side rail. A support pad may be positioned on the longitudinal frame. The support pad may comprise a thermally conductive core portion comprising a support matrix and at least one thermally conductive element. A cooling source may be thermally coupled to the thermally conductive core portion through the side rail with a connector comprising thermally conductive fibers. The cooling source may draw heat from the thermally conductive core portion through the at least one thermally conductive element and the thermally conductive fibers of the connector thereby cooling at least the thermally conductive core portion of the support pad.

A patient support is provided. The patient support may include a plurality of inflatable members. The plurality of inflatable members may include a core including a resilient material. The patient support may be controlled with a first controller positioned within an envelope of the patient support. The patient support may include a detector to detect when an external controller is coupled to the patient support, the patient support being controlled by the second controller when the second controller is present.

The described apparatuses, devices, and mechanisms are configured to measure the temperature of one or more Abreu brain thermal tunnel (ABTT) terminuses. In addition, some embodiments are configured to provide treatment for the diagnosed conditions and diseases.

A system includes a patient support apparatus that has one or more therapies. The therapies are optionally available depending on the acuity of the patient. A request for enablement of a therapy is transferred to a service provider for approval and, when approved, the therapy is enabled by the service provider. The patient support apparatus may be in communication with a server that is in communication with multiple patient support apparatuses so that the server is operable to selectively enable therapies on various patient support apparatuses.

A surgical head support device. A head cushion supports the patient's head while the patient is lying in the prone position during surgery. An air conditioning unit is adjacent to the head cushion and provides temperature control to the head cushion. A camera is positioned for viewing the patient's face as the patient is lying in the prone position on the head cushion. A secretion container is positioned to collect discharge from the patient's nose and mouth as the patient is lying in the prone position on the head cushion. A support platform is positioned under the head cushion and provides support for the head cushion, the camera and the secretion container. A height adjustment device is positioned under the support platform and is utilized to adjust the height of the head cushion for the safety and comfort of the patient.

A thermoelectric device includes an elongated panel, formed of a thermally insulating material, and having a plurality of thermoelectric elements formed from compacted conductors inside the insulating material and expanded conductors outside the insulating material wherein the thermoelectric elements run substantially parallel to or at an acute angle relative to the long dimension of the panel. The thermoelectric device may be integrated into a variety of surfaces or enclosures needing heating or cooling with controls and configurations to optimize the application.

A climate-conditioned bed includes an upper portion having at least a first climate zone and at least one fluid module associated with such a first climate zone. The fluid module comprises a fluid transfer device for selectively moving a fluid and a thermoelectric device for selectively heating or cooling a fluid. The bed additionally includes one or more control modules configured to regulate the operation of the fluid module, at least one input device configured to allow an occupant to select a setting or mode associated with the first climate zone and at least a first temperature sensor configured to detect a temperature associated with the first climate zone of the thermally-conditioned bed. In some embodiments, the fluid module is operatively connected to the control module. The control module is configured to adjust at least one operational parameter of the fluid module based on, at least in part, the setting or mode selected by an occupant using the at least one input device, and the temperature detected by the first temperature sensor.

A microclimate system includes an air box, a disposable incontinence pad, and a mattress. The incontinence pad serves as an incontinent event detector. The disposable incontinence pad may be configured to conduct air along an interface of the disposable incontinence pad to withdraw heat and moisture from a patient and cools and dries the patient's skin in order to reduce the risk of bed sore formation. The mattress may include a microclimate management layer that provides conditioned air to withdraw heat and moisture from the disposable incontinence pad thereby keeping the patient's skin cool and dry in order to reduce the risk of bed sore formation.

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.