Micro-Grooved Surfaces Influence Stem Cell Differentiation


Martin Knight and his colleagues from the Queen Mary’s School of Engineering and Materials Science and the Institute of Bioengineering in London, UK have shown that growing adult stem cells on micro-grooved surfaces disrupts a particular biochemical pathway that specified the length of a cellular structure called the “primary cilium.” Disruption of the primary cilium ultimately controls the subsequent behavior of these stem cells.

Primary cilia are about one thousand times narrower than a human hair. They are found in most cells and even though they were thought to be irrelevant at one time, this is clearly not the case.

Primary Cilium

The primary cilium acts as a sensory structure that responds to mechanical and chemical stimuli in the environment, and then communicates that external signal to the interior of the cell.  Most of the basic research on this structure was done using a single-celled alga called Chlamydomonas.

Martin Knight and his team, however, are certain that primary cilia in adult stem cells play a definite role in controlling cell differentiation.  Knight said, “Our research shows that they [primary cilia] play a key role in stem cell differentiation.  We found it’s possible to control stem cell specialization by manipulating primary cilia elongation, and that this occurs when stem cells are grown on these special grooved surfaces.”

When mesenchymal stromal cells were grown on grooved surfaces, the tension inside the cells was altered, and this remodeled the cytoskeleton of the cells.  Cytoskeleton refers to a rigid group of protein inside of cells that act as “rebar.” for the cell.  If you have ever worked with concrete, you will know that structural use of concrete requires the use of reinforcing metal bars to prevent the concrete from crumbling under the force of its own weight.  In the same way, cytoskeletal proteins reinforce the cell, give it shape, help it move, and help it resist shear forces.  Remodeling of the cytoskeleton can greatly change the behavior of the cell.

The primary cilium is important for stem cell differentiation.  Growing mesenchymal stromal cells on micro-grooved surfaces disrupts the primary cilium and prevents stem cell differentiation.  This simple culture technique can help maintain stem cells in an undifferentiated state until they have expanded enough for therapeutic purposes.

Once again we that there are ways to milk adult stem cells for all they are worth.  Destroying embryos is simply not necessary to save the lives of patients.

Frozen Stem Cells Taken from a Cadaver Five Years Ago Vigorously Grow


It is incumbent upon regenerative medicine researchers to discover non-controversial sources of stem cells that are safe and abundant. To that end, harvesting stem cells from deceased donors might represent an innovative and potentially unlimited reservoir of different stem cells.

In this present study, tissues from the blood vessels of cadavers were used as a source of human cadaver mesenchymal stromal/stem cells (hC-MSCs). The scientists in this paper successfully isolated cells from arteries after the death of the patient and subjected them to cryogenic storage in a tissue-banking facility for at least 5 years.

After thawing, the hC-MSCs were re-isolated with high-efficiency (12 × 10[6]) and showed all the usual characteristics of mesenchymal stromal cells. They expressed all the proper markers, were able to differentiate into the right cell types, and showed the same immunosuppressive activity as mesenchymal stromal cells from living persons.

Thus the efficient procurement of stem cells from cadavers demonstrates that such cells can survive harsh conditions, low oxygen tensions, and freezing and dehydration. This paves the way for a scientific revolution where cadaver stromal/stem cells could effectively treat patients who need cell therapies.

See Sabrina Valente, and others, Human cadaver multipotent stromal/stem cells isolated from arteries stored in liquid nitrogen for 5 years.  Stem Cell Research & Therapy 2014, 5:8.

Priming Cocktail for Cardiac Stem Cell Grafts


Approximately 700,000 Americans suffer a heart attack every year and stem cells have the potential to heal the damage wrought by a heart attack. Stem cells therapy has tried to take stem cells cultured in the laboratory and apply them to damaged tissues.

In the case of the heart, transplanted stem cells do not always integrate into the heart tissue. In the words of Jeffrey Spees, Associate Professor of Medicine at the University of Vermont, “many grafts simply didn’t take. The cells would stick or would die.”

To solve this problem, Spees and his colleagues examined ways to increase the efficiency of stem cell engraftment. In his experiments, Spees and others used mesenchymal stem cells from bone marrow. Mesenchymal stem cells are also called stromal cells because they help compose the spider web-like filigree within the bone marrow known as “stroma.” Even though the stroma does not make blood cells, it supports the hematopoietic stem cells that do make all blood cells.  Here is a picture of bone marrow stroma to give you an idea of what it looks like:

Immunohistochemistry-Paraffin: Bone marrow stromal cell antigen 1 Antibody [NBP2-14363] Staining of human smooth muscle shows moderate cytoplasmic positivity in smooth muscle cells.
Immunohistochemistry-Paraffin: Bone marrow stromal cell antigen 1 Antibody [NBP2-14363] Staining of human smooth muscle shows moderate cytoplasmic positivity in smooth muscle cells.
Stromal cells are known to secrete a host of molecules that protect injured tissue, promote tissue repair, and support the growth and proliferation of stem cells.

Spees suspected that some of the molecules made by bone marrow stromal cells could enhance the engraftment of stem cells patches in the heart. To test this idea, Spees and others isolated proteins from the culture medium of bone marrow stem cells grown in the laboratory and tested their ability to improve the survival and tissue integration of stem cell patches in the heart.

Spees tenacity paid off when he and his team discovered that a protein called “Connective tissue growth factor” or CTGF plus the hormone insulin were in the culture medium of these stem cells. Furthermore, when this culture medium was injected into the heart prior to treating them with stem cells, the stem cell patches engrafted at a higher rate.

“We broke the record for engraftment,” said Spees. Spees and his co-workers called their culture medium from the bone marrow stem cells “Cell-Kro.” Cell-Kro significantly increases cell adhesion, proliferation, survival, and migration.

Spees is convinced that the presence of CTGF and insulin in Cell-Kro have something to do with its ability to enhance stem cell engraftment. “Both CTGF and insulin are protective,” said Spees. “Together they have a synergistic effect.”

Spees is continuing to examine Cell-Kro in rats, but he wants to take his work into human trials next. His goal is to use cardiac stem cells (CSCs) from humans, which already have a documented ability to heal the heart after a heart attack. See here, here, and here.

“There are about 650,000 bypass surgeries annually,” said Spees. “These patients could have cells harvested at their first surgery and banked for future application. If they return for another procedure, they could then receive a graft of their own cardiac progenitor cells, primed in Cell-Kro, and potentially re-build part of their injured heart.”