| Exercise Countermeasures Project Mission Statement: | |||||
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ECL at NASA Glenn Research Center serves the NASA Exercise Countermeasures Project (ECP) and exercise community as a whole by providing a ground-based laboratory for simulating in-flight (0-g) and surface (fractional-g) exercise ˆ to advance the health and safety of the next generation of space explorers. | ||||
About the Project |
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 In the next 50 years, NASA
plans to send astronauts to the Moon and Mars. These astronauts will
need to perform a variety of physical tasks to accomplish their missions.
However, they may be physically unable to do these tasks if some of
the health effects of space flight are not prevented. The  effects include
decreases in bone and muscle mass, strength, sensory-motor function
(i.e. balance), and the ability to perform aerobic exercise. Exercise
will play an essential role in lowering the risks from these effects.
The Exercise Countermeasures Project (ECP) will develop a new set of
exercise countermeasures and determine the types and amounts of exercise
needed for long-duration space missions. The ECP team are personnel
at NASA’s Johnson Space Center (JSC) and Glenn Research Center (GRC),
and experts in various scientific disciplines at the National Space
Biomedical Research Institute (NSBRI) and at colleges and universities.
Collaborations between these groups make the most of existing expertise
and resources to develop exercise systems for astronauts to use during
exploration space missions. |
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Goals |
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| • Develop prescriptions for exercise countermeasures
that efficiently reduce the negative effects of zero and partial gravity
and meet the medical needs of astronauts • Establish the requirements for exercise equipment that will provide the prescribed exercise countermeasures within the constraints imposed by the space exploration vehicle and the astronauts’ habitat on the Moon or Mars • Develop a set of exercise devices for space flight that are effective, dependable, and lightweight, and require minimal maintenance |
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Exercise on the International Space Station (ISS) |
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Resistive Exercise |
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| Resistive exercise, or strength training, is performed against a weight. During space flight, resistance exercise is completed by securing the astronaut to a strength device that imparts load on the body. In environments with low gravity, the resistance device simulates weight bearing on the body. Resistance is varied to provide the weight load needed for each exercise. Current capabilities of load range from 0 - 300 lbs. Resistive exercise is designed to prevent weakening of the major muscle groups by maintaining strength and endurance, as well as minimizing bone loss. | |||||
Treadmill Exercise |
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| Treadmill exercise includes walking, running, deep knee bends, and some resistive exercises. This exercise is used to stimulate bone mass, cardiovascular fitness, muscle endurance, and the neurophysiologic pathways and reflexes required for walking on Earth or other planetary surfaces. Treadmill exercise can be performed in either a motorized (active) or non-motorized (passive) mode. The active mode provides the astronaut with speed control adjustable from 0 to 10 miles/hour in increments of 0.1 mile/hour. Passive mode allows the astronaut to drive the tread belt with variable mechanical resistance without the use of a motor. The astronaut is restrained to the treadmill by a subject restraint system, including a harness worn about the shoulders and hips. | |||||
Cycle Ergometry |
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Cycle ergometer
exercise in space consists of pedaling a recumbent cycle. This exercise
provides general aerobic and cardiovascular conditioning as well as
improved muscular endurance. Cycle ergometry is an important aspect
of  physical conditioning for doing ISS tasks such as space walks,
and to exercise during the prebreathe period before a space walk.
Cycle ergometry can be performed in either a manual mode, where cycling
workload is controlled manually by the astronaut, or an electronic
mode, where the workload is varied by an electronic controller. The
workload on the device being used on the ISS can be set at a maximum
of 350 watts for pedal speeds up to 120 rpm. |
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The Future |
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 The
ECP will build on the successful features of previous space exercise
equipment and eliminate features that were less than optimal. Project
personnel will work with designers of exploration vehicles and habitats
to determine the requirements that an exercise device must meet for
use in lunar and Mars environments. Equipment will be tested extensively
with humans (“man-in-the-loop” testing) to uncover engineering problems
that may not be apparent under mechanical testing conditions. The ISS
will provide an excellent inflight platform on which to validate candidate
equipment for exercise countermeasures. Data from testing countermeasures
for extended periods on the ISS will lead to improvements in the performance
of exercise countermeasures. To determine the optimal exercise prescriptions
for crewmembers, the ECP will use current ground-based analogs of weightlessness
(bed rest, zero-gravity aircraft) and will develop and validate partial-gravity
test models and facilities (mimicking Moon and Mars surface operations).
The ECP will play an important role in the exploration of the solar
system by keeping astronauts healthy, safe, and fit for the required
mission tasks. |
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Effects of Space Flight |
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 Early
assessments of medical data from International Space Station astronauts
have revealed adverse health outcomes: loss of bone density, decreased
muscle strength and endurance, postural instability, and reductions
in aerobic capacity. These deconditioning effects are caused by the
absence of Earth’s gravity, and over time they can impair astronauts’
performance or increase their risk of injury. Maintaining health and
fitness during space missions is critical for preserving astronaut performance
during flight tasks (such as extravehicular activity and maintaining
life support systems in the vehicle) and ensuring optimal rates of recovery
on return to Earth. Exercise is necessary before, during, and after
space flight to minimize the deconditioning effects of space flight
on the human body. Exploration missions to the Moon and Mars will present
unprecedented long-duration confinement, isolation, surface space walks,
and exposure to zero and partial-gravity environments. The abrupt return
to partial gravity upon arrival on the Moon or Mars, coupled with health
issues related to space travel, could affect the ability of astronauts
to perform their tasks and may have mission- or life-threatening impacts.
The next generation of exercise countermeasures will be a key element
in the solution to these problems. |
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| For decades, NASA has researched the benefits of using exercise in space to maintain astronaut health. When designing exercise systems for exploration missions, NASA engineers and scientists must consider constraints on equipment size, exercise volume, and power consumption that are imposed by the spacecraft and surface habitats. They also must consider unique engineering factors to allow astronauts to adequately load their bodies using harnesses and restraints, and comfortably complete their prescribed exercise regimens. In addition, the exercise duration and frequency should be optimized to allow time for the other mission tasks. | |||||
The Big Picture |
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| Who’s Involved • NASA HQ • NASA Johnson Space Center (JSC) Labs: Exercise Physiology - Nutritional Biochemistry - Pharmacology - Cardiovascular - Neuroscience - HACO Core Labs, and others • NASA Glenn Research Center: Exercise Countermeasures Lab (including the enhanced zero-g locomotion simulator or “eZLS”) • Other JSC Projects: Crew Health Care Systems - Fractional Gravity - Flight Analogs - Bed Rest Research - Non-Exercise Physiological Countermeasures, and others • National Space Biomedical Research Institute • Colleges and universities Project Activities • Conduct ground analog studies to evaluate efficacy of optimized space flight exercise prescriptions and hardware • Develop exercise prescription requirements for partial gravity environments • Conduct ground-based studies to develop partial gravity environments prescriptions • Conduct physiological and hardware evaluations utilizing eZLS capabilities • Provide vehicle and habitat trade studies and preliminary requirements for exercise devices • Define requirements for exercise countermeasure and monitoring hardware for Moon and Mars vehicles and habitats • Participate in integrated studies with other types of countermeasures Project Objective Develop and provide validated exercise countermeasure prescriptions and systems for space exploration that are effective, and optimized; and meet medical, vehicle, and habitat requirements |
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| Enhanced Zero Gravity Locomotion
Simulator Videos Click on the images below to view videos |
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NASA Glenn's Enhanced Zero Gravity Locomotion Simulator (eZLS) Study promotional video | |||
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eZLS Exercise Video (Part 1) | |||
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eZLS Exercise Video (Part 2) | |||
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eZLS Exercise footage | |||
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Astronaut Don Thomas Interview | |||
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Gail Perusek Interview, Project Manager for Exercise Countermeasures | |||
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Dr. Peter Cavanagh Interview, Co-Director, Center for Space Medicine Cleveland Clinic | |||
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eZLS Exercise, additional footage | |||
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Webmaster: Tim Reckart NASA Official: Richard DeLombard Last Updated: March 21, 2007 |
