Number of intervention days
Number of self-initiated intervention days performed by patient during study period
Average intervention time per intervention day
Average intervention time performed by the subject
Action Research Arm Test
Behavioral test of upper extremity motor function
Action Research Arm Test
Behavioral test of upper extremity motor function
Action Research Arm Test
Behavioral test of upper extremity motor function
Box and Blocks Test
Behavioral test of upper extremity motor function
Box and Blocks Test
Behavioral test of upper extremity motor function
Box and Blocks Test
Behavioral test of upper extremity motor function
Nine Hole Peg Test
Behavioral test of upper extremity motor function
Nine Hole Peg Test
Behavioral test of upper extremity motor function
Nine Hole Peg Test
Behavioral test of upper extremity motor function
Stroke Impact Scale - Activities of Daily Living Subscale
Fifty point subscale. Higher score = better recovery. Subscales reported individually.
Stroke Impact Scale - Activities of Daily Living Subscale
Fifty point subscale. Higher score = better recovery. Subscales reported individually.
Stroke Impact Scale - Activities of Daily Living Subscale
Fifty point subscale. Higher score = better recovery. Subscales reported individually.
Stroke Impact Scale - Hand Subscale
Twenty five point subscale. Higher score = better recovery. Subscales reported individually.
Stroke Impact Scale - Hand Subscale
Twenty five point subscale. Higher score = better recovery. Subscales reported individually.
Stroke Impact Scale - Hand Subscale
Twenty five point subscale. Higher score = better recovery. Subscales reported individually.
Stroke Impact Scale - Participation Subscale
Forty point subscale. Higher score = better recovery. Subscales reported individually.
Stroke Impact Scale - Participation Subscale
Forty point subscale. Higher score = better recovery. Subscales reported individually.
Stroke Impact Scale - Participation Subscale
Forty point subscale. Higher score = better recovery. Subscales reported individually.
Stroke Impact Scale - Recovery Subscale
One hundred point subscale. Higher score = better recovery. Subscales reported individually.
Stroke Impact Scale - Recovery Subscale
One hundred point subscale. Higher score = better recovery. Subscales reported individually.
Stroke Impact Scale - Recovery Subscale
One hundred point subscale. Higher score = better recovery. Subscales reported individually.
Hand opening/closing range of motion
Sum of maximum angular excursions of the paretic metacarpo-phalangeal (MCP), proximal inter-phalangeal(PIP) and distal inter-phalangeal joints (DIP) joints during a hand opening activity
Hand opening/closing range of motion
Sum of maximum angular excursions of the paretic metacarpo-phalangeal (MCP), proximal inter-phalangeal(PIP) and distal inter-phalangeal joints (DIP) joints during a hand opening activity
Hand opening/closing range of motion
Sum of maximum angular excursions of the paretic metacarpo-phalangeal (MCP), proximal inter-phalangeal(PIP) and distal inter-phalangeal joints (DIP) joints during a hand opening activity
Hand trace RMSE
Ability to control hand opening as subject moves a cursor tracking a sine wave. Reported as root mean square error (RMSE) comparing target position and cursor position.
Hand trace RMSE
Ability to control hand opening as subject moves a cursor tracking a sine wave. Reported as root mean square error (RMSE) comparing target position and cursor position.
Hand trace RMSE
Ability to control hand opening as subject moves a cursor tracking a sine wave. Reported as root mean square error (RMSE) comparing target position and cursor position.
Wrist Trace RMSE
Ability to control wrist flexion and extension as subject moves a cursor tracking a sine wave. Reported as root mean square error (RMSE) comparing target position and cursor position.
Wrist Trace RMSE
Ability to control wrist flexion and extension as subject moves a cursor tracking a sine wave. Reported as root mean square error (RMSE) comparing target position and cursor position.
Wrist Trace RMSE
Ability to control wrist flexion and extension as subject moves a cursor tracking a sine wave. Reported as root mean square error (RMSE) comparing target position and cursor position.
Horizontal shoulder and elbow trace RMSE
Ability to control shoulder and elbow as subject moves a cursor tracking a sine wave. Reported as root mean square error (RMSE) comparing target position and cursor position.
Horizontal shoulder and elbow trace RMSE
Ability to control shoulder and elbow as subject moves a cursor tracking a sine wave. Reported as root mean square error (RMSE) comparing target position and cursor position.
Horizontal shoulder and elbow trace RMSE
Ability to control shoulder and elbow as subject moves a cursor tracking a sine wave. Reported as root mean square error (RMSE) comparing target position and cursor position.
Twenty four hour upper limb activity magnitude ratio
Participant will wear tri-axial accelerometers on both wrists for twenty four hours and upper limb magnitude ratio will be calculated and reported as per Bailey (2015). For each second of this twenty four hour period accelerations across the three axes are combined into a single vector magnitude value. Inactive non-paretic UE is assigned a vector magnitude of -7 when paretic UE is moving alone. Inactive paretic UE is assigned a vector magnitude of 7 when non-paretic UE is moving alone. Paretic wrist vector magnitude will be divided by non-paretic wrist vector magnitude for each second. These calculated values will be transformed using a natural logarithm to prevent skewness of positive, untransformed values. Median of these values for the twenty four hour period will be reported for each individual subject.
Twenty four hour upper limb activity magnitude ratio
Participant will wear tri-axial accelerometers on both wrists for twenty four hours and upper limb magnitude ratio will be calculated and reported as per Bailey (2015). For each second of this twenty four hour period accelerations across the three axes are combined into a single vector magnitude value. Inactive non-paretic UE is assigned a vector magnitude of -7 when paretic UE is moving alone. Inactive paretic UE is assigned a vector magnitude of 7 when non-paretic UE is moving alone. Paretic wrist vector magnitude will be divided by non-paretic wrist vector magnitude for each second. These calculated values will be transformed using a natural logarithm to prevent skewness of positive, untransformed values. Median of these values for the twenty four hour period will be reported for each individual subject.
Twenty four hour upper limb activity magnitude ratio
Participant will wear tri-axial accelerometers on both wrists for twenty four hours and upper limb magnitude ratio will be calculated and reported as per Bailey (2015). For each second of this twenty four hour period accelerations across the three axes are combined into a single vector magnitude value. Inactive non-paretic UE is assigned a vector magnitude of -7 when paretic UE is moving alone. Inactive paretic UE is assigned a vector magnitude of 7 when non-paretic UE is moving alone. Paretic wrist vector magnitude will be divided by non-paretic wrist vector magnitude for each second. These calculated values will be transformed using a natural logarithm to prevent skewness of positive, untransformed values. Median of these values for the twenty four hour period will be reported for each individual subject.
Twenty four hour upper limb activity magnitude ratio
Participant will wear tri-axial accelerometers on both wrists for twenty four hours and upper limb magnitude ratio will be calculated and reported as per Bailey (2015). For each second of this twenty four hour period accelerations across the three axes are combined into a single vector magnitude value. Inactive non-paretic UE is assigned a vector magnitude of -7 when paretic UE is moving alone. Inactive paretic UE is assigned a vector magnitude of 7 when non-paretic UE is moving alone. Paretic wrist vector magnitude will be divided by non-paretic wrist vector magnitude for each second. These calculated values will be transformed using a natural logarithm to prevent skewness of positive, untransformed values. Median of these values for the twenty four hour period will be reported for each individual subject.