Systems and methods for airway management are provided. The airway management devices may be configured to align the oropharyngeal, laryngeal and tracheal axes of a person's head and/or support a neck region and chin and posterior mandibular region of a person. The airway management devices may provide forces similar to forces provided by a conventional head tilt chin lift maneuver and a conventional jaw thrust maneuver.

An airway support device is provided having a head support pillow with a bottom surface and an opposing top surface adapted to contact and support a side of a patient's head. A chin support is adapted to be positioned adjacent to the pillow where the chin support positions and supports a chin of the patient to provide an unobstructed airway.

A helmet for anesthesia, adapted to keep confined anesthetic gases and to administer them in a non-invasive fashion to a patient laying on an operating table, allowing to provide oxygen and/or anesthetic gases through tubes and fast access to the patient's head in case of emergency is described. The helmet has a lower half-shell and an upper half-shell, the lower half-shell being anatomically shaped to receive and support the nape and the neck of the laying patient, the upper half-shell and the lower half-shell having fastening means for fastening one to the other and being configured to be fitted one to the other and to the neck or torso of the patient to form a substantially airtight enclosure for enclosing head of the patient, at least one inlet port for gas supply and at least one outlet port for gas evacuation being on the lower half-shell and/or the upper half-shell.

A patient bed is provided in a healthcare facility having a network including a real time locating system (RTLS) and an electronic medical records (EMR) computer. The patient bed includes bed control circuitry that is configured to receive at least one protocol messages from the EMR computer and, in response to the at least one protocol message, enables at least one bed safety protocol in which at least one bed condition is monitored by the bed control circuitry. The bed control circuitry generates an alert in response to the at least one bed condition being in an undesirable state and no caregiver being present in the patient room as determined by the RTLS and communicated to the bed circuitry. The bed control circuitry suspends monitoring the at least one bed condition in response to the RTLS indicating to the bed control circuitry that at least one caregiver is present in the patient room.

A patient bed is provided in a healthcare facility having a network including a real time locating system (RTLS) and an electronic medical records (EMR) computer. The patient bed includes bed control circuitry that is configured to receive at least one protocol messages from the EMR computer and, in response to the at least one protocol message, enables at least one bed safety protocol in which at least one bed condition is monitored by the bed control circuitry. The bed control circuitry generates an alert in response to the at least one bed condition being in an undesirable state and no caregiver being present in the patient room as determined by the RTLS and communicated to the bed circuitry. The bed control circuitry suspends monitoring the at least one bed condition in response to the RTLS indicating to the bed control circuitry that at least one caregiver is present in the patient room.

A device and method that facilitates performance of a jaw thrust maneuver. A base connected to a rack and pinion mechanism including at least one pinion rotatably attached to the base and at least two racks slidably attached to the base and engaged with the pinion to move in opposite directions upon rotation of at least one pinion. A pair of arms, each pivotably coupled to one of the racks to allow rotational freedom of motion. A patient's head is placed in supine position and a pair of arms slides towards the patient's head in synchrony to position the arms to clear the patient's airways.

A patient bed is provided in a healthcare facility having a network including a real time locating system (RTLS) and an electronic medical records (EMR) computer. The patient bed includes bed control circuitry that is configured to receive at least one protocol messages from the EMR computer and, in response to the at least one protocol message, enables at least one bed safety protocol in which at least one bed condition is monitored by the bed control circuitry. The bed control circuitry generates an alert in response to the at least one bed condition being in an undesirable state and no caregiver being present in the patient room as determined by the RTLS and communicated to the bed circuitry. The bed control circuitry suspends monitoring the at least one bed condition in response to the RTLS indicating to the bed control circuitry that at least one caregiver is present in the patient room.

An articulated chin rest is assembly is provided for supporting the chin of a patient under monitored anesthesia care, sedation, general anesthesia, or other medical procedure to ensure that their airway is unobscured. The assembly may comprise a clamp adaptable to grip a variety of structures, a first and a second length of rigid material sequentially and rotatably connected to the clamp, and a chin rest finally rotatably connected to the second length of rigid material. Means for rotatably linking the clamp, first and second lengths of rigid material, and chin rest allow each element to rotate in three dimensional space so that the assembly mechanically mimics, and is ultimately usable in place of, an anesthesiologist's hand for tilting the patient's head and securely supporting the patient's chin.

An inflatable pillow is invented to provide an effective and efficient method to improve the oral intubation procedure in the pre-hospital setting, both in the ground and air ambulances along with emergency rooms in hospitals to eliminate intubation failures. The inflatable pillow comprises a bladder body and an air valve. The air valve is distally positioned on the body so that the air valve is not in the way when a user is positioning a patient's head on the pillow. Thus, the inflatable pillow can be positioned or moved more towards the patient's neck and shoulder area for a better head position or view of the vocal cords. Additionally, the inflatable pillow can be used to adjust the height of the patient's head by inflating and/or deflating the pillow through the air valve prior to and/or during the first pass intubation procedure, thus, making the intubation procedure more reliable.

Devices, systems, and/or methods for immobilizing a patient's head and simultaneously providing emergency respiration for the patient includes, in some embodiments, a head immobilizer, a bag valve mask (BVM), an endotracheal tube (ET) bracket, and/or an oxygen face mask. In some embodiments where head immobilization is not needed, a cardiopulmonary resuscitation (CPR) board may be used in lieu of the head immobilizer. Each such embodiment is configured to require reduced manual intervention by a caregiver without reducing the effectiveness of each medical device and/or system. An adjustable BVM holder integrated into the head immobilizer secures the BVM on the patient. In embodiments with a BVM, only a single hand is necessary to provide emergency respiration, freeing the caregiver's other hand for other caregiving tasks. Such a head immobilizer may secure an ET bracket and/or face mask to a patient, allowing for hands-free operation during patient treatment, movement, and transportation.