Abstract: The disclosed infection control systems and devices can be easily and quickly deployed by clinicians and staff in emergent and routine medical environments to provide adequate protection from bio-aerosolized and droplet material while allowing appropriate access to and visibility of the patient during such procedures. The infection control devices may include a base member and a frame disposed on the base member. The frame may be configured to move between a collapsed state and an expanded state with respect to the base member. The frame may include a first support member and a second support member configured to extend vertically from the base member when in the expanded state. The devices may include an enclosure member that is disposed on the frame and the base member and configured to define an enclosure above the base member. The devices may also include access member(s) configured to provide access to the enclosure.

Abstract: The disclosed infection control systems and devices can be easily and quickly deployed by clinicians and staff in emergent and routine medical environments to provide adequate protection from bio-aerosolized and droplet material while allowing appropriate access to and visibility of the patient during such procedures. The infection control devices may include a base member and a frame disposed on the base member. The frame may be configured to move between a collapsed state and an expanded state with respect to the base member. The frame may include a first support member and a second support member configured to extend vertically from the base member when in the expanded state. The devices may include an enclosure member that is disposed on the frame and the base member and configured to define an enclosure above the base member. The devices may also include access member(s) configured to provide access to the enclosure.

Abstract: Methods and systems relate to determining sensory motor performance based on user non-postural movements within a generated dynamic virtual environment. The generated environment requires users to: (i) utilize primary sensor inputs (e.g., vision, vestibular sensation and somatosensation); (ii) assess the dynamic virtual environment; and (iii) integrate and translate those inputs into movement to control the dynamic virtual environment. The methods may include receiving non-postural user input with respect to a state of one or more attributes of a dynamic virtual environment provided on a user interface for one or more sessions, the one or more attributes including a control object and a target which moves with respect to the control object; determining performance information based on the user input and the state of the one or more attributes for the one or more sessions; and determining sensory motor performance information from the performance information.

Abstract: Methods and systems relate to determining sensory motor performance based on user non-postural movements within a generated dynamic virtual environment. The generated environment requires users to: (i) utilize primary sensor inputs (e.g., vision, vestibular sensation and somatosensation); (ii) assess the dynamic virtual environment; and (iii) integrate and translate those inputs into movement to control the dynamic virtual environment. The methods may include receiving non-postural user input with respect to a state of one or more attributes of a dynamic virtual environment provided on a user interface for one or more sessions, the one or more attributes including a control object and a target which moves with respect to the control object; determining performance information based on the user input and the state of the one or more attributes for the one or more sessions; and determining sensory motor performance information from the performance information.