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SUMMARIES OF SPACELAB-J EXPERIMENTS
The following summaries on SL-J experiments loosely adhere to a
format:
What is the purpose of this experiment?
How will it be performed?
Why is it important to science and/or industry?
Pages 2 through 24 cover Life Sciences experiments. The first
seven are sponsored by NASA; next is the ISAIAH experiment,
which is a secondary payload and is sponsored by NASA and the
Israeli Space Agency; the remaining 12 are sponsored by NASDA.
Pages 25 through 38 cover the Materials Sciences experiments.
The first two are sponsored by NASA, the remaining 22 are
sponsored by NASDA.
Fluid Therapy System: Inflight Demonstration of the Space
Station Freedom Health Maintenance Facility Fluid Therapy System
Principal Investigator: Dr. Charles W. Lloyd, NASA Johnson Space Center
The Fluid Therapy System will be used to purify and deliver intravenous
fluids in microgravity. This multipurpose unit produces sterile water
from onboard water sources, formulates and stores solutions and infuses
the appropriate solution into the patient.
The test will purify 10 liters of water with known contaminants into
sterile water, which will be formulated into solutions. To test its
operation in microgravity, the solutions then will be administered to a
mannequin's arm with simulated veins. After the flight, the quantity
and quality of the water and solutions will be analyzed.
This system has been designed as part of the Space Station Freedom
Health Maintenance Facility. The design of this equipment will be
important for emergency treatment of sick or injured astronauts in
space. It also may have implications for emergency medical care and
stabilization in remote areas on Earth.
Magnetic Resonance Imaging (MRI) After Exposure to Microgravity
Principal Investigator: Dr. Adrian LeBlanc
Baylor College of Medicine and Methodist Hospital
This study will use the noninvasive technique "Magnetic Resonance
Imaging" (MRI) to image the astronauts' bones and muscles.
MRI uses low frequency radio waves to probe the body. This technique
has no known health hazards. The experiment will be conducted on the
ground before and after the mission.
The microgravity environment of space induces muscle atrophy and bone
loss. These may limit the time that humans can remain in space. This
investigation will use recent technology developments in the field of
imaging to gain a better understanding of muscle and bone loss.
MRI forms an image by "reading" the hydrogen in the area being
scanned. The scan not only measures the quantity of hydrogen in an
area but distinguishes between the different chemical forms of the
element.
MRI allows researchers to distinguish between fat, muscle, blood,
cartilage, bone and other tissues. This sensitivity to chemical form
allows researchers to detect shifts in the chemical makeup of a region,
thereby allowing them to detect subtle changes.
The images of the astronauts will be compared to subjects undergoing a
bedrest study, to study changes in muscle, bone marrow and vertebral
discs. Researchers hope that by comparing the data from these two
groups, they will gain a better understanding of the underlying
mechanisms of muscle atrophy and the effects of reduced gravity on the
spine.
Lower Body Negative Pressure: Countermeasure for Reducing Postflight
Orthostatic Intolerance
Principal Investigator: Dr. John B. Charles, NASA Johnson Space Center
This study will determine if Lower Body Negative Pressure (LBNP) is an
effective method of preventing the orthostatic intolerance seen
post-flight. It is a condition in which the body is unable to maintain
the flow of blood to the head when in a standing position, causing
fainting or blacking out.
During space flight, the body's fluids redistribute to the head and
upper body. This is an adaptive response to weightlessness.
The LBNP device is an airtight chamber that seals around the
astronaut's waist to enclose the lower body. The pressure is reduced
in the chamber, causing the fluids that have shifted to the upper body
to be pulled to the legs and lower abdomen.
The astronaut wears the LBNP suit for 4 hours. During this time, the
subject drinks a liter of a salt water solution. Cardiac function and
blood pressure are monitored using an echocardiograph and an automatic
blood pressure device.
In ground studies, the LBNP treatment can keep plasma volume at a
preflight level and protect orthostatic function for up to 24 hours.
Therefore, to be used as a preventive measure for postflight
orthostatic intolerance, the treatment could be given 1 day before
landing.
Bone Cell Growth and Mineralization in Microgravity
Principal Investigator: Dr. Nicole Partridge,St. Louis University,
School of Medicine
This study will examine the effects of microgravity on the shape,
structure, behavior and proliferation of osteoblasts. Osteoblasts are
the bone-forming cells. The effects of microgravity on the hormonal
sensitivity of the osteoblastic cells will be examined. Also, the
secretion of collagenase and its inhibitors will be quantified.
In space, bones begin to lose calcium. This appears to be due to
alterations in the function of the osteoblasts. Osteoblasts may be the
gravity responsive cell in the bones. Osteoblasts also may possess a
kind of "mechanostat" that senses changes in the gravity load and
causes an adjustment in bone mass.
It is thought that, in microgravity, the osteoblast responds to the
mechanostat by altering the osteoblast's sensitivity to hormones that
break down the bones. Changes in the level of these hormones in the
body has been observed in space.
This experiment may provide information concerning the best
countermeasures for preventing spaceflight-induced osteopenia (bone
loss), as well as the osteopenia observed in patients on Earth as a
result of immobilization or aging.
This experiment also will provide knowledge at the cellular level of
the behavior and function of the bone in microgravity, possibly
providing new information about the mechanisms causing osteopenia.
Autogenic Feedback Training Experiment: A Preventive Method for Space Motion
Sickness
Principal Investigator: Dr. Patricia S. Cowings, NASA Ames Research Center
This study will examine the effectiveness of using biofeedback and
autogenic training to counteract the symptoms of Space Motion Sickness
(SMS). Autogenic feedback training teaches the subject to control
physiological responses.
Astronauts will learn to control the responses that are part of space
motion sickness. Prior to the mission, astronauts have been trained in
the autogenic feedback techniques.
During the flight, two crewmembers will don autogenic feedback suits,
which measure pulse rate, blood pressure, skin temperature, blood
volume, skin conductivity and respiration rate.
These indicators will allow the subjects to determine their
physiological state at all times, enabling them to use their autogenic
feedback training to control these parameters. If successful,
autogenic feedback training could provide an alternative to using
medications to control SMS.
Crewmembers must be at peak performance throughout a mission to ensure
that their safety is not compromised and their work is completed. SMS
affects crew performance and occurs in over half of all astronauts and
cosmonauts. It causes disorientation, nausea, and (in severe cases)
vomiting. Also, it is similar in many ways to motion sickness
experienced on the Earth (sea sickness or car sickness).
Studies on Earth show that the physiological factors that lead to
motion sickness can be controlled without drugs through the use of
autogenic feedback training or biofeedback. Autogenic feedback
teaches people to control their "involuntary" functions like heart
rate, skin temperature and blood pressure. On Earth this training has
helped sufferers of migrane headaches and high blood pressure control
the symptoms of these problems without using medications.
The Effects of Weightlessness on the Development of Amphibian Eggs Fertilized
in Space
Principal Investigator: Mr. Kenneth A. Souza, NASA Ames Research Center
The Frog Embryology Experiment (FEE) will investigate how frog eggs
develop under microgravity conditions. This experiment will help to
answer some basic questions on the role of gravity in the fertilization
and development of animals.
The objective is to determine if gravity plays a crucial role in the
process of amphibian fertilization and embryonic development. Two
areas of development will be examined in detail: the formation of the
dorsal ventral axis and the development of the inner ear. Postflight
analysis also will examine the influence of early development in
microgravity on behavior, maturation and reproduction.
Female frogs flown aboard the shuttle will be induced to shed eggs,
which will be fertilized in space. This experiment will be the first
to fertilize eggs in space. Previous experiments fertilized eggs prior
to flight.
It is believed that the processes that are most sensitive to gravity
may occur during and just after fertilization. Fertilization in space
will allow the critical early stages and proceeding development to
occur totally under microgravity conditions.
This experiment will help determine if one gravity is required for
amphibian fertilization and normal embryonic development, and if all
developmental stages will occur independent of gravity. This study
also will determine if the gravity-sensing structures in the inner ear
will develop normally and if tadpole swimming behavior will be abnormal
in microgravity.
Plant Culture Research: Gravity, Chromosomes and Organized
Development in Aseptically Cultured Plant Cells
Principal Investigator: Dr. Abraham Krikorian
State University of New York at Stony Brook
This experiment examines the effects of microgravity on plant
development. An orderly progression of cellular events both in terms
of time and geometry is involved in plant development.
Specifically examined in this experiment are the affects of
microgravity on the growth and differentiation of plant cells and on
mitosis and chromosome behavior. Microgravity may affect the pattern
and development of embryogenic cells from one critical stage to
another.
This experiment uses aseptic carrot and daylily cell cultures grown in
plant cell culture chambers provided by NASDA. The cultures will
remain undisturbed during the flight, so this experiment requires no
crew interaction.
After the flight the cells' morphology, stage of development and
chromosomes will be analyzed using electron microscopy.
This experiment will provide information on whether the critical stages
of somatic embryo development can be completed in a microgravity
environment. It also will provide information on chromosomal stability
in somatic cells grown in space.
This information will help to establish whether somatic embryos can
form and function in microgravity, a question that has implications for
future molecular biology and genetic engineering studies in space.
Israeli Space Agency Investigation About Hornets (ISAIAH)
Principal Investigator: Dr. Jacob S. Ishay, Tel-Aviv University
Israeli Space Agency
ISAIAH will examine the effects of microgravity on the orientation,
reproductive capability and social activity of 180, female Oriental
Hornets. The direction of comb-building by hornet workers in
microgravity, as well as the structural integrity of the combs, will be
examined.
The cuticle (exoskeleton) and the venom will be examined for
differences in the biochemical substances produced by hornets in space
as compared to the Earth. It is believed that there may be a
difference in the toxicity of hornet venom produced in space.
On Earth, hornets build combs in the direction of gravity. Centrifuge
studies have shown that hornets build combs in the same direction of
the resultant gravitational and centrifugal forces.
Experimentation in microgravity will offer investigators an opportunity
to study the specific effects of other environmental cues on
comb-building. Comb building ability appears to be a function of age,
with young hornets building combs faster and of better geometric
orientation.
ISAIAH will study comb-building behavior in different age groups --
juveniles and adults. It is expected that there will be changes in
comb building (orientation, cell size, density, shape and number). In
microgravity, it is believed, the geometric cues of the cages will
provide significant influence on the comb-building, especially in
adults hornets.
Studies on the Effects of Microgravity on the Ultrastructure
and Function of Cultured Mammalian Cells (L-6A)
Principal Investigator: Dr. Atsushige Sato, Tokyo Medical and
Dental University
The purpose of this experiment is to observe the arrangement of certain
structures in animal kidney cells grown in space.
These structures are called microfilaments and intermediate filaments.
They are responsible for cellular movement and mechanical support. In
a way, they provide for the cell the same sort of support as an
animal's muscles and bones.
If intermediate filaments and microfilaments are rearranged when in
microgravity, it will indicate that gravity directly affects the
organization and composition of cells.
This experiment also will study the way cells use energy by observing
the rate at which they consume nutrients and produce enzymes. This
will help determine if there is a difference in the cells' function in
microgravity.
Previous investigations of monkey kidney cells grown in space have
shown a decrease in enzyme production, which indicates a change in the
cells' metabolism.
Establishing the cell culture technique in a space laboratory is
expected to be applicable in various fields of science. It will be of
particular use to help clarify some of the basic phenomenon concerning
living things in space.
Study of the Effects of Microgravity on Cell Growth of Human
Antibody Producing Cells and Their Secretion (L-6B)
Principal Investigator: Dr. Hisayoshi Ooka, Tokyo Medical and
Dental University
This experiment will examine how the immune cells, called "B-cells,"
grow and produce antibodies in space. B-cells are a vital part of the
body's immune system. These antibodies are one of the defenses against
bacteria and other foreign substances that enter the body.
Past investigations in space have shown that the antibodies produced by
some types of immune cells are affected by microgravity.
After the flight, the amount of antibody produced and its effectiveness
will be examined. Also, the way in which B-cells use energy in space
will be examined by analyzing the medium in which the cells were
grown.
The information obtained from this study will be important in
identifying the effects of microgravity on cell metabolism and antibody
production. This experiment will provide information on how this part
of the immune system functions in space.
Organ Differentiation from Cultured Plant Cells Under Microgravity (L-6C)
Principal Investigator: Dr. Yasuyuki Yamada, Kyoto University
The purpose of this investigation is to establish a plant-cell culture
system under microgravity conditions. This system will allow an
examination of the effects of microgravity on plant cell division,
differentiation and growth.
Cell differentiation is the process by which the different cell types
develop from a single parent cell. All cells in an organism contain
the same genetic material but are different depending on their
function.
When a plant is growing, the genes that will make the first shoot are
"turned on." This means that only shoot cells are made. As the plant
continues to develop, the genes that produce the roots are "turned on"
and roots are formed. Both the shoot cells and the root cells contain
the same genetic material but they are very different cells.
This investigation will examine shoot formation from de- differentiated
cells; these cells show no differentiation. This experiment will
evaluate the effects of microgravity on the development and growth of
each organ.
The cells will be grown undisturbed in a semi-solid culture medium
during the flight. After the flight, the cells will be examined under
an electron microscope. Also, each cell's metabolism (rate it uses
energy) will be investigated. This experiment will allow the
researcher to gain insight into the effects of microgravity on cell
differentiation and metabolism.
The Effect of Low Gravity on Calcium Metabolism and Bone Formation (L-7)
Principal Investigator: Dr. Tatsuo Suda, Showa University
This study will investigate bone formation in chicken eggs flown aboard
the shuttle. These eggs will be at three stages of development. The
eggs will be examined after the flight for cartilage growth, bone
formation and differentiation of different types of bone cells.
This experiment will lead to further knowledge of embryonic development
in space, especially the development of bones and muscles. It will
provide insight on why bones become weaker and lose calcium under low
gravity.
The knowledge obtained by this study may be useful for preventing bone
loss in astronauts during prolonged space flight.
The skeletal system evolved under the influence of Earth's gravity. In
a microgravity environment, it appears that there are changes in the
bone and calcium levels in animals adapted to Earth's gravity.
It has been reported that bone density decreases significantly during
prolonged spaceflight. Past flights have shown that the amount of bone
loss is related to the length of spaceflight.
As part of this study, several Japanese and five U.S. investigators
will receive tissue samples of various organs for analysis. These
researchers will be examining samples of inner ear, eye, brain and
chorioallantroic membrane tissue.
Also, one of the U.S. investigators will be performing a vestibular
response test on the chicks after hatching. These investigations will
help determine if other parts of the body develop normally in space.
Circadian Rhythm of Conidiation in Neurospora Crassa (L-12)
Principal Investigator: Dr. Yasuhiro Miyoshi, Tokyo University
This experiment investigates circadian rhythms, which are patterns of
behavior that occur every 24 hours and are unaffected by constant
conditions of light and temperature.
The question is whether this behavior is determined from within the
body or caused by some geophysical factors such as atmospheric
pressure, gravity or electromagnetic radiation. This experiment will
attempt to answer this question.
The fungus used, Neurospora crassa, band A mutant, shows an obvious
circadian rhythm in its spore forming behavior on the ground. Every 24
hours spores form, while the fungus is in the dark and exposed to a
constant temperature.
A fungi growth chamber containing six growth tubes will be flown. An
identical unit will be used on the ground for a control. The fungus is
introduced into the growth medium at one end of each tube.
The chamber is kept at 3!C[?? -PEY] to stop the growth of the fungus
until after the Spacelab has been activated. The chamber is kept in
constant light for 24 hours and then are placed into the dark growth
chamber bag where they will be allowed to grow for 5 days at room
temperature.
The other chamber on the ground will receive the same treatment. The
two will be compared postflight to determine if spaceflight affected
the rhythm.
This study will help determine the affects of spaceflight on the
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of living organisms.
Neurophysiological Study on Visuo-Vestibular Control of Posture
and Movement in Fish During Adaptation to Weightlessness (L-2)
Principal Investigator: Dr. Shigeo Mori, Nagoya University
The primary o
circadian rhythms of