105-Day Mars Simulation: U.S. Studies Focus on Improving Work Performance

HOUSTON, July 13 /PRNewswire-USNewswire/ -- From March 31 to July 14, a
six-man international crew called an isolation chamber in Moscow their home.
The crew, composed of four Russians and two Europeans, simulated a 105-day
Mars mission full of experiments and realistic mission scenarios, including
emergency situations and 20-minute communications delays.

U.S. participation in the mission consisted of three research teams with
experiments evaluating solutions to conditions that impact work performance.
The projects evaluated lighting interventions to counter sleep disruption due
to shift work or long hours, tested two objective methods of measuring the
impact of stress and fatigue on performance, and assessed interactions between
crew members and mission control. The three projects were funded by the
Houston-based National Space Biomedical Research Institute (NSBRI). 

"The mission allowed us to look at the feasibility of certain technologies
developed for improving performance by deploying them in an extremely
demanding work environment. In this realistic setting, will crews use the
technologies and will we get good data?" said Dr. David F. Dinges, leader of
the NSBRI group funded from University of Pennsylvania School of Medicine and
Rutgers. "Additional goals were to see how different mission situations
affected the various performance measures and to evaluate whether the
interventions could indeed improve performance."

The 105-Day Mars Mission, a partnership between the Russia's Institute of
Biomedical Problems and the European Space Agency, is the precursor to a
520-Day mission scheduled for 2010.  The isolation facility consists of
several interconnected, modules containing medical and scientific research
areas, living quarters, a kitchen, greenhouse and exercise facility.

For researchers, the opportunity to run experiments in this type of
environment was invaluable. "We've done experiments in the sleep lab to test
the efficacy of lighting interventions, but that is a highly controlled
environment," said Dr. Charles A. Czeisler, leader of the NSBRI project funded
from Harvard Medical School, Brigham and Women's Hospital, and University of
Colorado. "By transitioning studies into an operational environment, like the
105-Day Mission, we have the opportunity to learn how to best deploy
interventions in a realistic mission setting. This analog is a great
intermediate step before implementation on an actual spaceflight."

Participation from the crew and mission controllers was excellent. All three
NSBRI projects received data throughout the mission. Final data will be
received in the coming weeks, and the teams will begin detailed data analysis.


"These tests and interventions have an impact beyond the space program,"
Dinges said. "Many people work night shifts and in high-stress, confined
environments that require alertness, such as power plant control rooms,
railroad systems, hospitals, military operations, and fire and rescue
situations. The things that we are learning here about how to enhance
performance will be useful in many work environments."

NSBRI Project Overviews

Lighting Intervention Study (Dr. Charles A. Czeisler, lead investigator): The
study compared two different wavelengths of light (in the green spectrum)
during night-shift work with a control lighting condition (in the red
spectrum). Crew members and mission control personnel participated. The
experiment, which replicated studies done in sleep laboratories, examined
whether exposure to green-enriched light will help sustain job performance in
the middle of the night and when participants have been awake for a long time.
The study looked at the impact of the light on melatonin, the body's
sleep-promoting hormone. Additional data were collected for the study with
participants taking performance tests, wearing watch-like devices that track
sleep/wake periods, completing sleep and work logs, and submitting urine and
saliva samples.

"Based on previous laboratory studies, we anticipate that during exposure to
the shorter wavelength green light that melatonin will be significantly
suppressed, resulting in better performance during overnight work," Czeisler
said. "The findings will have direct application to night-shift workers."

Monitoring the Impact of Fatigue and Stress on Work Performance (Dr. David F.
Dinges, lead investigator):  The project tested two novel, unobtrusive,
objective methods for monitoring impact of fatigue and stress on work
performance. Crew members and mission control personnel participated. One test
involved the feasibility of "reading the face" through use of an optical
computer recognition system that monitored facial expressions, tracking the
shape and movements of the face in three dimensions. Video was taken during
brief cognitive tests, to detect the presence of stress, fatigue and negative
affect, and will be used to determine the extent to which this approach was
feasible during the mission.

The second performance measure used 3- and 10-minute laptop-based Psychomotor
Vigilance Tests to detect changes in basic performance involving attention,
response speed and impulsivity. The tests require the user to watch for a
visual signal and respond quickly and accurately when it appears. Participants
took the tests twice daily during day and night work. The tests have been
validated in other settings for sensitivity to reduced alertness caused by a
variety of factors in spaceflight (e.g., restricted sleep, night-shift work).

Crew Interactions and Autonomy (Dr. Nick Kanas, lead investigator): The study
evaluated the mood, interpersonal interactions and performance of crew members
and mission control personnel. The groups were studied under two conditions:
low crew autonomy (where the work schedule was planned by mission control) and
high crew autonomy (where the crew plan and troubleshoot their own work
schedule). Through the use of a weekly questionnaire, the project will
evaluate the experiment's impact on mission control and on the crew-ground
relationship.

"The data gathered on the relative benefits of high versus low autonomy
conditions during manned space missions will have relevance not only for
future expeditions to the moon and Mars, but also to current on-orbit
International Space Station missions," said Dr. Nick Kanas, leader of the
NSBRI group funded at University of California, San Francisco.

Detailed summaries of each project are available on NSBRI's Russian Chamber
Study Web page
(http://www.nsbri.org/Research/105-DayRussianChamberStudy.html).

NSBRI, funded by NASA, is a consortium of institutions studying the health
risks related to long-duration spaceflight. Research findings will also impact
the understanding and treatment of similar medical conditions experienced on
Earth. The Institute's science, technology and education projects take place
at more than 60 institutions across the United States. 




SOURCE  National Space Biomedical Research Institute

Kathy Major of NSBRI, +1-713-798-5893, major@bcm.edu