A patient litter basket spin control assembly for use on a patient litter basket is provided. The assembly comprises thruster unit for discharging an air stream and is mounted on the patient litter basket. At least one sensor is associated with the thruster unit for sensing rotational movement or spin of the patient litter basket, and a power source is provided for powering the thruster unit and the sensor. A clamp member mounts on the patient litter basket and releasably receives the thruster unit. The sensors modulate the force of the air stream from the thruster unit so that the air stream counters the rotational movement of the patient litter basket to stabilize the patient litter basket by preventing the spin.

A patient litter basket spin control assembly for use on a patient litter basket is provided. The assembly comprises thruster unit for discharging an air stream and is mounted on the patient litter basket. At least one sensor is associated with the thruster unit for sensing rotational movement or spin of the patient litter basket, and a power source is provided for powering the thruster unit and the sensor. A clamp member mounts on the patient litter basket and releasably receives the thruster unit. The sensors modulate the force of the air stream from the thruster unit so that the air stream counters the rotational movement of the patient litter basket to stabilize the patient litter basket by preventing the spin.

A wheelchair securement system includes a first anchoring mechanism and a second anchoring mechanism. The first anchoring mechanism includes a first bar, a first set of seat track anchors, and a first set of adjustable strap anchors. The first bar extends between the first set of seat track anchors and is secured thereto. The first set of adjustable strap anchors is secured to the first bar, and the first set of adjustable strap anchors is configured to be securable to a wheelchair. The second anchoring mechanism includes a second bar, a second set of seat track anchors, and a second set of adjustable strap anchors. The second bar extends between the second set of seat track anchors and is secured thereto. The second set of adjustable strap anchors is secured to the second bar, and the second set of adjustable strap anchors is configured to be securable to the wheelchair.

A lift for aircraft, such as a passenger lift, facilitates the entry of disabled passengers and/or items into the cabins of aircraft and their exit from the cabins of the aircraft. The lift may be stowed and used from within the cabin of the aircraft. Methods accessing a cabin of an aircraft and methods for facilitating the introduction of passengers and/or items into the cabin and their removal from the cabin are also disclosed.

A patient isolation unit (PIU) for use in marine rescues. The PIU of this invention is useful to safely transport personnel exposed to, or potentially exposed to, an identified and/or known infectious agent or chemical warfare agent (CWA) on marine vessels and/or aircraft such as Coast Guard boasts, cutters and aircraft. The PIU has a generally tapered tubular shape compatible with wire rescue baskets conforming in shape to the human body and into which an injured, sick, or disabled person can be safely strapped, such as the Stokes litter rescue basket for hoisting and fit in rotary wing aircraft.

Embodiments provide an aeromedical bio-containment module for use in a cargo plane. The aeromedical bio-containment module includes a fully integrated pallet system allowing for the module to roll onto the cargo plane. An integrated set of lugs allows the module to be locked into the cargo plane floor without the use of chains or other pallets. The aeromedical bio-containment module features a ward area for safe treatment of patients, an anteroom, and an office area for personnel. The aeromedical bio-containment module operates under a negative pressure system, and includes a full air filtration system to remove pathogens, particulates, and other airborne contaminants.

A mobile apparatus with an integrated stretcher apparatus for patients has a base having rotatably mounted wheels on a bottom side for moving the base on the ground, a frame which is fastened to a top side of the base and which is open at least on one side, and a stretcher apparatus having segments which are mounted pivotably relative to one another, wherein the segments are configured for folding the stretcher apparatus into a first form, in which all the segments adjoin one another in a plane, and for folding said stretcher apparatus into a second form, in which the stretcher apparatus is packed down, and wherein the stretcher apparatus and the frame are configured to be complementary to one another such that the stretcher apparatus in the second form can be completely introduced into the frame.

A patient litter basket spin control assembly includes a first gyroscope and a motion sensor for sensing an angular acceleration of a patient litter basket. The first gyroscope generates a counter torque to the litter basket to slow the angular acceleration of the litter basket to provide stabilization. The first gyroscope and a second gyroscope may be configured as a pair and located at opposite ends of the litter basket.

A method for providing medical services to a patient, including: receiving a medical service request associated with a patient location; selecting an aircraft, located at an initial location, from a plurality of aircraft based on the patient location and the initial location; determining a flight plan for flying the aircraft to a region containing the patient location; at a sensor of the aircraft, sampling a first set of flight data; at a processor of the aircraft, autonomously controlling the aircraft to fly based on the flight plan and the set of flight data; selecting a landing location within the region; and landing the aircraft at the landing location, including: sampling a set of landing location data; determining a safety status of the landing location based on the set of landing location data; outputting a landing warning observable at the landing location; at the sensor, sampling a second set of flight data; and in response to determining the safety status and outputting the landing warning, autonomously controlling the aircraft to land at the landing location based on the second set of flight data.

An end-effector for a hoist includes a drive and an articulating arm. The articulating arm includes support disks, control cables extending through the support disks, and a hoist cable extending through the support disks. The drive includes an actuator connected to one of the control cables. The actuator deploys and retracts the control cables, thereby displacing the articulating arm from an end-effector axis. The drive also includes a stabilizer mounted on a drive housing, the stabilizer generates a stabilizing moment in response to the articulating arm displacing from the end-effector axis.