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Regenetech
Kyle Shanks, President
17045 El Camino Real
Suite 101
Houston, TX 77058
Office (281) 480-8899
Cell (832) 414-9520
Fax (281) 480-4998
Copyright
2011©
All Rights Reserved
|
How
Does Space, Gravity and Bio Science Affect Stem Cell Research?
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Date:
04.15.2004
Description:
Biomedical research offers hope for a variety of medical problems,
from diabetes to the replacement of damaged bone and tissues. Bioreactors,
which are used to grow cells and tissue cultures, play a major role
in such research and production efforts. Anchorage dependent cells
on STS-95 will be grown on beads similar to these cells produced
during previous investigations. Recombinant proteins may offer the
possibility of reducing or eliminating transplant rejections. Research
by Synthecon, Inc. using the BioDyn Bioreactor will focus on the
preliminary process for growing a proprietary recombinant protein
that can decrease rejection of transplanted tissue. The cells producing
this protein are anchorage dependent, meaning that they must attach
to something to grow. These cells will be cultured in the bioreactor
in a medium containing polymer microbeads. Synthecon hopes that
the data from this mission will lead to the development of a commercial
protein that will aid in prevention of transplant rejection.
Date:
07.02.2002
Description:
Diagram depicts the importance of cell-cell communication as central
to the understanding of cancer growth and progression, the focus
of the NASA bioreactor demonstration system (BDS-05) investigation.
Microgravity studies will allow us to unravel the signaling and
communication between these cells with the host and potential development
of therapies for the treatment of cancer metastasis. The NASA Bioreactor
provides a low turbulence culture environment which promotes the
formation of large, three-dimensional cell clusters. Due to their
high level of cellular organization and specialization, samples
constructed in the bioreactor more closely resemble the original
tumor or tissue found in the body. The Bioreactor is rotated to
provide gentle mixing of fresh and spent nutrient without inducing
shear forces that would damage the cells. The work is sponsored
by NASA's Office of Biological and Physical Research. The bioreactor
is managed by the Biotechnology Cell Science Program at NASA's Johnson
Space Center (JSC). NASA-sponsored bioreactor research has been
instrumental in helping scientists to better understand normal and
cancerous tissue development. In cooperation with the medical community,
the bioreactor design is being used to prepare better models of
human colon, prostate, breast and ovarian tumors. Cartilage, bone
marrow, heart muscle, skeletal muscle, pancreatic islet cells, liver
and kidney are just a few of the normal tissues being cultured in
rotating bioreactors by investigators. Credit: Emory University.
Title: Breast Cancer Research at NASA
Description:
High magnification of view of tumor cells aggregate on microcarrier
beads, illustrting breast cells with intercellular boundaires on
bead surface and aggregates of cells achieving 3-deminstional growth
outward from bead after 56 days of culture in a NASA Bioreactor.
NASA's Marshall Space Flight Center (MSFC) is sponsoring research
with Bioreactors, rotating wall vessels designed to grow tissue
samples in space, to understand how breast cancer works. This ground-based
work studies the growth and assembly of human mammary epithelial
cell (HMEC) from breast cancer susceptible tissue. Radiation can
make the cells cancerous, thus allowing better comparisons of healthy
vs. tunorous tissue. Credit: Dr. Jearne Becker, University of South
Florida.
Date:
06.01.2001
Description:
Cells cultured on Earth (left) typically settle quickly on the bottom
of culture vessels due to gravity. In microgravity (right), cells
remain suspended and aggregate to form three-dimensional tissue.
The NASA Bioreactor provides a low turbulence culture environment
which promotes the formation of large, three-dimensional cell clusters.
The Bioreactor is rotated to provide gentle mixing of fresh and
spent nutrient without inducing shear forces that would damage the
cells. Due to their high level of cellular organization and specialization,
samples constructed in the bioreactor more closely resemble the
original tumor or tissue found in the body. The work is sponsored
by NASA's Office of Biological and Physical Research. The bioreactor
is managed by the Biotechnology Cell Science Program at NASA's Johnson
Space Center (JSC). NASA-sponsored bioreactor research has been
instrumental in helping scientists to better understand normal and
cancerous tissue development. In cooperation with the medical community,
the bioreactor design is being used to prepare better models of
human colon, prostate, breast and ovarian tumors. Cartilage, bone
marrow, heart muscle, skeletal muscle, pancreatic islet cells, liver
and kidney are just a few of the normal tissues being cultured in
rotating bioreactors by investigators.
Date:
06.01.2001
Date:
05.31.2001
Date:
05.15.2001
Description:
These photos compare the results of colon carcinoma cells grown
in a NASA Bioreactor flown on the STS-70 Space Shuttle in 1995 flight
and ground control experiments. The cells grown in microgravity
(left) have aggregated to form masses that are larger and more similar
to tissue found in the body than the cells cultured on the ground
(right). The principal investigator is Milburn Jessup of the University
of Texas M. D. Anderson Cancer Center. The NASA Bioreactor provides
a low turbulence culture environment which promotes the formation
of large, three-dimensional cell clusters. Due to their high level
of cellular organization and specialization, samples constructed
in the bioreactor more closely resemble the original tumor or tissue
found in the body. NASA-sponsored bioreactor research has been instrumental
in helping scientists to better understand normal and cancerous
tissue development. In cooperation with the medical community, the
bioreactor design is being used to prepare better models of human
colon, prostate, breast and ovarian tumors. Cartilage, bone marrow,
heart muscle, skeletal muscle, pancreatic islet cells, liver and
kidney are just a few of the normal tissues being cultured in rotating
bioreactors by investigators. Cell constructs grown in a rotating
bioreactor on Earth (left) eventually become too large to stay suspended
in the nutrient media. In the microgravity of orbit, the cells stay
suspended. Rotation then is needed for gentle stirring to replenish
the media around the cells. The work is sponsored by NASA's Office
of Biological and Physical Research. The bioreactor is managed by
the Biotechnology Cell Science Program at NASA's Johnson Space Center
(JSC). Credit: NASA and University of Texas M. D. Anderson Cancer
Center.
Date:
05.15.2001
Description:
Lisa Freed and Gordana Vunjak-Novakovic, both of the Massachusetts
Institute of Technology (MIT), have taken the first steps toward
engineering heart muscle tissue that could one day be used to patch
damaged human hearts. Cells isolated from very young animals are
attached to a three-dimensional polymer scaffold, then placed in
a NASA bioreactor. The cells do not divide, but after about a week
start to cornect to form a functional piece of tissue. Here, a transmission
electron micrograph of engineered tissue shows a number of important
landmarks present in functional heart tissue: (A) well-organized
myofilaments (Mfl), z-lines (Z), and abundant glycogen granules
(Gly); and (D) intercalcated disc (ID) and desmosomes (DES). The
NASA Bioreactor provides a low turbulence culture environment which
promotes the formation of large, three-dimensional cell clusters.
The Bioreactor is rotated to provide gentle mixing of fresh and
spent nutrient without inducing shear forces that would damage the
cells. Due to their high level of cellular organization and specialization,
samples constructed in the bioreactor more closely resemble the
original tumor or tissue found in the body. NASA-sponsored bioreactor
research has been instrumental in helping scientists to better understand
normal and cancerous tissue development. In cooperation with the
medical community, the bioreactor design is being used to prepare
better models of human colon, prostate, breast and ovarian tumors.
Cartilage, bone marrow, heart muscle, skeletal muscle, pancreatic
islet cells, liver and kidney are just a few of the normal tissues
being cultured in rotating bioreactors by investigators. The work
is sponsored by NASA's Office of Biological and Physical Research.
The bioreactor is managed by the Biotechnology Cell Science Program
at NASA's Johnson Space Center (JSC). Credit: MIT
Date:
05.15.2001
Description:
This prostate cancer construct was grown during NASA-sponsored bioreactor
studies on Earth. Cells are attached to a biodegradable plastic
lattice that gives them a head start in growth. Prostate tumor cells
are to be grown in a NASA-sponsored Bioreactor experiment aboard
the STS-107 Research-1 mission in 2002. Dr. Leland Chung of the
University of Virginia is the principal investigator. The NASA Bioreactor
provides a low turbulence culture environment which promotes the
formation of large, three-dimensional cell clusters. Due to their
high level of cellular organization and specialization, samples
constructed in the bioreactor more closely resemble the original
tumor or tissue found in the body. The Bioreactor is rotated to
provide gentle mixing of fresh and spent nutrient without inducing
shear forces that would damage the cells. The work is sponsored
by NASA's Office of Biological and Physical Research. The bioreactor
is managed by the Biotechnology Cell Science Program at NASA's Johnson
Space Center (JSC). NASA-sponsored bioreactor research has been
instrumental in helping scientists to better understand normal and
cancerous tissue development. In cooperation with the medical community,
the bioreactor design is being used to prepare better models of
human colon, prostate, breast and ovarian tumors. Cartilage, bone
marrow, heart muscle, skeletal muscle, pancreatic islet cells, liver
and kidney are just a few of the normal tissues being cultured in
rotating bioreactors by investigators. Credit: NASA and the University
of Virginia.
Date:
04.01.1998
Description:
During the STS-90 shuttle flight in April 1998, cultured renal cortical
cells revealed new information about genes. Timothy Hammond, an
investigator in NASA's microgravity biotechnology program was interested
in culturing kidney tissue to study the expression of proteins useful
in the treatment of kidney diseases. Protein expression is linked
to the level of differentiation of the kidney cells, and Hammond
had difficulty maintaining differentiated cells in vitro. Intrigued
by the improvement in cell differentiation that he observed in rat
renal cells cultured in NASA's rotating wall vessel (a bioreactor
that simulates some aspects of microgravity) and during an experiment
performed on the Russian Space Station Mir, Hammond decided to sleuth
out which genes were responsible for controlling differentiation
of kidney cells. To do this, he compared the gene activity of human
renal cells in a variety of gravitational environments, including
the microgravity of the space shuttle and the high-gravity environment
of a centrifuge. Hammond found that 1,632 genes out of 10,000 analyzed
changed their activity level in microgravity, more than in any of
the other environments. These results have important implications
for kidney research as well as for understanding the basic mechanism
for controlling cell differentiation.
Date:
01.01.1998
Description:
For 5 days on the STS-70 mission, a bioreactor cultivated human
colon cancer cells, which grew to 30 times the volume of control
specimens grown on Earth. This significant result was reproduced
on STS-85 which grew mature structures that more closely match what
are found in tumors in humans. Shown here, clusters of cells slowly
spin inside a bioreactor. On Earth, the cells continually fall through
the buffer medium and never hit bottom. In space, they are naturally
suspended. Rotation ensures gentle stirring so waste is removed
and fresh nutrient and oxygen are supplied. The NASA Bioreactor
provides a low turbulence culture environment which promotes the
formation of large, three-dimensional cell clusters. Due to their
high level of cellular organization and specialization, samples
constructed in the bioreactor more closely resemble the original
tumor or tissue found in the body. The Bioreactor is rotated to
provide gentle mixing of fresh and spent nutrient without inducing
shear forces that would damage the cells. The work is sponsored
by NASA's Office of Biological and Physical Research. The bioreactor
is managed by the Biotechnology Cell Science Program at NASA's Johnson
Space Center (JSC). NASA-sponsored bioreactor research has been
instrumental in helping scientists to better understand normal and
cancerous tissue development. In cooperation with the medical community,
the bioreactor design is being used to prepare better models of
human colon, prostate, breast and ovarian tumors. Cartilage, bone
marrow, heart muscle, skeletal muscle, pancreatic islet cells, liver
and kidney are just a few of the normal tissues being cultured in
rotating bioreactors by investigators.
Date:
01.01.1998
Description:
Astronaut John Blaha replaces an exhausted media bag and filled
waste bag with fresh bags to continue a bioreactor experiment aboard
space station Mir in 1996. NASA-sponsored bioreactor research has
been instrumental in helping scientists to better understand normal
and cancerous tissue development. In cooperation with the medical
community, the bioreactor design is being used to prepare better
models of human colon, prostate, breast and ovarian tumors. Cartilage,
bone marrow, heart muscle, skeletal muscle, pancreatic islet cells,
liver and kidney are just a few of the normal tissues being cultured
in rotating bioreactors by investigators. This image is from a video
downlink. The work is sponsored by NASA's Office of Biological and
Physical Research. The bioreactor is managed by the Biotechnology
Cell Science Program at NASA's Johnson Space Center (JSC).
Date:
01.01.1998
Description:
Cells from kidneys lose some of their special features in conventional
culture but form spheres replete with specialized cell microvilli
(hair) and synthesize hormones that may be clinically useful. Ground-based
research studies have demonstrated that both normal and neoplastic
cells and tissues recreate many of the characteristics in the NASA
bioreactor that they display in vivo. Proximal kidney tubule cells
that normally have rich apically oriented microvilli with intercellular
clefts in the kidney do not form any of these structures in conventional
two-dimensional monolayer culture. However, when normal proximal
renal tubule cells are cultured in three-dimensions in the bioreactor,
both the microvilli and the intercellular clefts form. This is important
because, when the morphology is recreated, the function is more
likely also to be rejuvenated. The work is sponsored by NASA's Office
of Biological and Physical Research. The bioreactor is managed by
the Biotechnology Cell Science Program at NASA's Johnson Space Center
(JSC). |
