Human Movement Database
This study will collect information on the different ways people control limb and body movements. This information will be used to develop a database on normal movements and adaptive movements of people who have diseases that affect the way they move. The database will serve as a tool to improve diagnosis and treatment of patients with movement-related problems.
Volunteers over the age of 4 who have normal movement patterns or who have developed different ways to perform movement tasks may be eligible for this study. A physical therapist will screen candidates to determine their strength, flexibility and range of motion of joints.
Participants will be asked to perform movements such as walking, walking up or down stairs, standing quietly or reaching for an object. For the test, the arms and legs are wrapped with a soft, rubber-like material to which small plastic reflective balls are attached. A piece of firm material called a shell may be attached to the rubber sleeves or other areas of the body. Then the volunteer performs the specified task several times while special cameras record the movement. The cameras only record the positions of the reflective balls during movement, not the person s face or body. Electrical activity in the muscles also may be measured, using small metal electrodes attached to the surface of the skin with an adhesive bandage.
|Study Design:||Time Perspective: Prospective|
|Official Title:||A Rigid Body Database on Human Movement|
|Study Start Date:||July 1990|
The purpose of this study is to develop a database of normative and adaptive control strategies for human motion. Up to 900 volunteers will serve as subjects after they complete a neuromusculoskeletal screening exam. Subjects will be asked to perform one or more tasks related to the execution of activities of daily living such as: walking on the ground, walking on a treadmill, quiet and perturbed standing, stair ascent and descent, turning and jumping, cycling, elliptical training, and isolated upper and lower extremity limb movements or trunk movements. The subjects movement patterns will be recorded using a three-dimensional motion tracking system. Motion data will be analyzed using a rigid body six degree-of-freedom approach when applicable. Temporal/spatial, kinematic, kinetic, and surface electromyographic variables will be collected and calculated.
Many factors affect the ability to move. The ones we are mainly interested in investigating include muscle weakness, spasticity, and dynamic balance. To quantify strength or spasticity, a force transducer is needed such as a Biodex isokinetic dynamometer which is a standard rehabilitation assessment and training device, or a more simple handheld dynamometer can be used that the person presses against as force is recorded. For the spasticity tests, a person or a machine such as the Biodex moves a joint through an arc of motion (e.g. elbow, knee, or ankle) at a range of speeds from 5-240 degrees per second while resistance to motion is being recorded or graded subjectively. EMG and joint position may be collected simultaneously during the passive movements. The dynamic balance tests will be performed on a force plate or using a clinical balance testing device, the Equitest, by Neurcom. To determine if electrical stimulation (ES) improves limb movement, walking, and balance, a device such as the WalkAide may be used in patients who have some dysfunction in their lower extremities. Only persons with central nervous system injuries who have a foot drop gait pattern will be given the opportunity to use this device for 3-6 months. The WalkAide is worn below the knee and delivers individually programmed ES to aid in muscle function of the ankle.
Patient groups will be identified clinically or statistically. Group means and standard deviations will then be computed. It is hoped the database developed may serve as a tool by which individual patient data may be compared in order to facilitate the diagnosis and optimize the treatment and clinical outcome of patients with movement related problems.
An over ground harness system may be used for some of the over ground or instrumented gait and balance assessments if there is concern that the patient is too weak or unbalanced and therefore may trip or fall during the activity, or to help facilitate more normal patterns by decreasing the load borne by the trunk and/or legs.
Please refer to this study by its ClinicalTrials.gov identifier: NCT00001252
|Contact: Sara F Sadeghi||(301) firstname.lastname@example.org|
|Contact: Diane L Damiano, Ph.D.||(301) email@example.com|
|United States, Maryland|
|National Institutes of Health Clinical Center, 9000 Rockville Pike||Recruiting|
|Bethesda, Maryland, United States, 20892|
|Contact: For more information at the NIH Clinical Center contact Patient Recruitment and Public Liaison Office (PRPL) 800-411-1222 ext TTY8664111010 firstname.lastname@example.org|
|Principal Investigator:||Diane L Damiano, Ph.D.||National Institutes of Health Clinical Center (CC)|