Category Archives: Stem Cell Videos

BERKELEY One of the top suspects behind killer vascular diseases is the victim of mistaken identity, according to researchers from the University of California, Berkeley, who used genetic tracing to help hunt down the real culprit. The guilty party is not the smooth muscle cells within blood vessel walls, which for decades was thought to combine with cholesterol and fat that can clog arteries. Blocked vessels can eventually lead to heart attacks and strokes, which account for one in three deaths in the United States.

Instead, a previously unknown type of stem cell a multipotent vascular stem cell is to blame, and it should now be the focus in the search for new treatments, the scientists report in a new study appearing today (June 6) in the journal Nature Communications.

"For the first time, we are showing evidence that vascular diseases are actually a kind of stem cell disease," said principal investigator Song Li, professor of bioengineering and a researcher at the Berkeley Stem Cell Center. "This work should revolutionize therapies for vascular diseases because we now know that stem cells rather than smooth muscle cells are the correct therapeutic target."

The finding that a stem cell population contributes to artery-hardening diseases, such as atherosclerosis, provides a promising new direction for future research, the study authors said.

"This is groundbreaking and provocative work, as it challenges existing dogma," said Dr. Deepak Srivastava, who directs cardiovascular and stem cell research at the Gladstone Institutes in San Francisco, and who provided some of the mouse vascular tissues used by the researchers. "Targeting the vascular stem cells rather than the existing smooth muscle in the vessel wall might be much more effective in treating vascular disease."

It is generally accepted that the buildup of artery-blocking plaque stems from the body's immune response to vessel damage caused by low-density lipoproteins, the bad cholesterol many people try to eliminate from their diets. Such damage attracts legions of white blood cells and can spur the formation of fibrous scar tissue that accumulates within the vessel, narrowing the blood flow.

However, no experiments published have directly demonstrated this de-differentiation process, so Li and his research team remained skeptical. They turned to transgenic mice with a gene that caused their mature smooth muscle cells to glow green under a microscope.

In analyzing the cells from cross sections of the blood vessels, they found that more than 90 percent of the cells in the blood vessels were mature smooth muscle cells. They then isolated and cultured the cells taken from the middle layer of the mouse blood vessels.

After one month of cell expansion, the researchers saw a threefold increase in the size of the cell nucleus and the spreading area, along with an increase in stress fibers. Notably, none of the new, proliferating cells glowed green, which meant that their lineage could not be traced back to the mature smooth muscle cells originally isolated from the blood vessels.

"Not only was there a lack of green markers in the cell cultures, but we noticed that another type of cell isolated from the blood vessels exhibited progenitor traits for different types of tissue, not just smooth muscle cells," said Zhenyu Tang, co-lead author of the study and a Ph.D. student in the UC Berkeley-UCSF Graduate Program in Bioengineering.

Originally posted here:
Stem cells real culprit behind hardened arteries

One of the top suspects behind killer vascular diseases is the victim of mistaken identity, according to researchers from the University of California, Berkeley, who used genetic tracing to help hunt down the real culprit.

The guilty party is not the smooth muscle cells within blood vessel walls, which for decades was thought to combine with cholesterol and fat that can clog arteries. Blocked vessels can eventually lead to heart attacks and strokes, which account for one in three deaths in the United States.

Instead, a previously unknown type of stem cell a multipotent vascular stem cell is to blame, and it should now be the focus in the search for new treatments, the scientists report in a new study appearing June 6 in the journal Nature Communications.

"For the first time, we are showing evidence that vascular diseases are actually a kind of stem cell disease," said principal investigator Song Li, professor of bioengineering and a researcher at the Berkeley Stem Cell Center. "This work should revolutionize therapies for vascular diseases because we now know that stem cells rather than smooth muscle cells are the correct therapeutic target."

The finding that a stem cell population contributes to artery-hardening diseases, such as atherosclerosis, provides a promising new direction for future research, the study authors said.

"This is groundbreaking and provocative work, as it challenges existing dogma," said Dr. Deepak Srivastava, director of the Gladstone Institute of Cardiovascular Disease at UC San Francisco, who provided some of the mouse vascular tissues used by the researchers. "Targeting the vascular stem cells rather than the existing smooth muscle in the vessel wall might be much more effective in treating vascular disease."

It is generally accepted that the buildup of artery-blocking plaque stems from the body's immune response to vessel damage caused by low-density lipoproteins, the bad cholesterol many people try to eliminate from their diets.

Such damage attracts legions of white blood cells and can spur the formation of fibrous scar tissue that accumulates within the vessel, narrowing the blood flow.

The scar tissue, known as neointima, has certain characteristics of smooth muscle, the dominant type of tissue in the blood vessel wall.

Because mature smooth muscle cells no longer multiply and grow, it was theorized that in the course of the inflammatory response, they revert, or de-differentiate, into an earlier state where they can proliferate and form matrices that contribute to plaque buildup.

Read this article:
HEALTH: The real culprit behind hardened arteries? Stem cells, says landmark study

04-06-2012 10:31 Although stem cells hold promise as direct therapy for human diseases, many researchers are even more enthusiastic about the opportunity to use stem cells to study disease fundamentals. Learn how clinicians and researchers are involving diabetes patients in the search for a cure by developing new stem cell lines from their DNA.

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Science Bulletins: Stem Cells: Developing New Cures - Video

(PRWEB) June 06, 2012

StemSave Science Advisor, Dr. George T.-J.Huang, DDS, MSD, DSc has accepted the position of Director of Stem Cells and Regenerative Therapies in the Department of Bioscience Research in the College of Dentistry at the University of Tennessee.

Dr. Huang previously served as the Chair and Herbert Schilder Professor in Endodontics and Director, Postgraduate Program in Endodontics of Boston Universitys Henry M. Goldman School of Dental Medicine. Dr. Huangs current research interest is in the area of stem cells and regenerative medicine with particular emphasis on the generation and characterization of induced pluripotent stem cells (iPSCs) from dental stem cells, creating an indefinite stem cell source for tissue regeneration and an invaluable tool for the study of disease.

We congratulate Dr. Huang on his well-earned advancement and anticipate the many future contributions he will make as an acknowledged leader of his field.

The era of Regenerative Medicine is now.

More here:
StemSave Science Advisor, Dr. George T.-J. Huang, Takes on Leading Role in Advancing Stem Cell Research

Public release date: 4-Jun-2012 [ | E-mail | Share ]

Contact: David Eve Celltransplantation@gmail.com Cell Transplantation Center of Excellence for Aging and Brain Repair

Tampa, Fla. (June 4, 2012) When autologous (self-donated) lung-derived mensenchymal stem cells (LMSCs) were transplanted endoscopically into 13 adult female sheep modeled with emphysema, post-transplant evaluation showed evidence of tissue regeneration with increased blood perfusion and extra cellular matrix content. Researchers concluded that their approach could represent a practical alternative to conventional stem cell-based therapy for treating emphysema.

The study is published in Cell Transplantation (21:1), now freely available on-line at http://www.ingentaconnect.com/content/cog/ct/.

"Mensenchymal stem cells are considered for transplantation because they are readily available, highly proliferative and display multi-lineage potential," said study corresponding author Dr. Edward P. Ingenito of the Brigham and Women's Hospital Division of Pulmonary and Critical Care Medicine. "Although MSCs have been isolated from various adult tissues - including fat, liver and lung tissues - cells derived from bone marrow (BM) have therapeutic utility and may be useful in treating advanced lung diseases, such as emphysema."

However, according to the authors, previous transplantation studies, many of which used an intravenous delivery method, have shown that BM-MSCs have been only marginally successful in treating lung diseases. Further, therapeutic responses in those studies have been limited to animal models of inflammatory lung diseases, such as asthma and acute lung injury.

To try and answer the questions surrounding the utility of BM-MSCs for treating advanced emphysema, a disease characterized by tissue destruction and loss of lung structural integrity, for this study the researchers isolated highly proliferative, mensenchymal cells from adult lung parenchyma (functional tissue) (LMSCs) and used an endoscopic delivery system coupled with a scaffold comprised of natural extracellular matrix components.

"LMSCs display efficient retention in the lung when delivered endobronchially and have regenerative capacity through expression of basement membrane proteins and growth factors," explained Dr. Ingenito.

However, despite the use of autologous cells, only a fraction of the LMSCs delivered to the lungs alveolar compartment appeared to engraft. Cell death likely occurred because of the failure of LMSCs to home to and bind within their niche, perhaps because the niche was modified by inflammation or fibrosis. These cells are attachment-dependent and failure to attach results in cell death."

Their findings did suggest, however, that LMSCs were capable of contributing to lung remodeling leading to documented functional improvement rather than scarring 28 days post transplantation.

Original post:
Cell transplantation of lung stem cells has beneficial impact for emphysema

PITTSBURGH (KDKA) Injecting stem cells into the brain of someone who has had a stroke is a hot button issue.

Is it safe? Can it be done?

Thats what researchers at the University of Pittsburgh are trying to find out.

Because these are cells that have not been injected into the brain before, we need to know whether it is safe to do so, UPMC neurologist Dr. Lawrence Wechsler said.

So far, at UPMC, two people have received injections of stem cells from the bone marrow of healthy adult donors.

Roger Hill is one of them.

In August 2009, he woke up with a stroke. The first thing he noticed was his vision. He couldnt see half of his world and then his left side left him.

Something happened with my left leg. I fell down, he said. I couldnt feel my left knee.

The problem was in the brain.

A stroke most commonly happens because of a blocked artery. Part of the brain dies from a lack of oxygen and blood flow. Stroke is a leading cause of death and disability.

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Researchers Testing Stem Cells As Treatment For Stroke Recovery

President offers condolences following death of student Michael Curtis Augustin, a 33-year-old undergraduate died June 3 at Stanford University Hospital in Palo Alto, Calif. The cause of death is still being determined. (June 4, 2012)

Some stem cells can trigger tumors Adipose-derived stem cells often used in reconstructive surgeries including mastectomies can create a microenvironment suitable for more tumors to grow, researchers report. (June 4, 2012)

Analysis of maize shows genes involved in domestication Two new papers identify genes involved in domestication as well as variations and similarities between domesticated maize and its wild relatives. (June 4, 2012)

New book focuses on Frank Lloyd Wright's Freeman House Associate Professor Jeff Chusid's book 'Saving Wright: The Freeman House and the Preservation of Meaning, Materials, and Modernity' has won a prestigious award. (June 4, 2012)

Four faculty in Arts and Sciences honored The College of Arts and Sciences has awarded Appel fellowships to Lawrence McCrea and Nick Salvato, and Paul Academic Advising Awards to Alison Van Dyke and Dagmawi Woubshet. (June 4, 2012)

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Some stem cells can trigger tumors

Public release date: 4-Jun-2012 [ | E-mail | Share ]

Contact: David Eve celltransplantation@gmail.com Cell Transplantation Center of Excellence for Aging and Brain Repair

Tampa, Fla. (June 4, 2012) After carrying out a study comparing the repopulation efficiency of immature hepatic stem/progenitor cells and mature hepatocytes transplanted into liver-injured rats, a research team from Sapporo, Japan concluded that mature hepatocytes offered better repopulation efficiency than stem/progenitor cells.

Until day 14 post-transplantation, the growth of the stem/progenitor cells was faster than the mature hepatocytes, but after two weeks most of the stem/progenitor cells had died. However, the mature hepatocytes continued to survive and proliferate one year after their implantation.

The study is published in Cell Transplantation (21:1), now freely available on-line at http://www.ingentaconnect.com/content/cog/ct/.

"Cell-based therapies as an alternative to liver transplantation to treat liver disease have shown promise," said study corresponding author Dr. Toshihiro Mitaka of the Cancer Research Institute of the Sapporo Medical University School of Medicine, Sapporo, Japan. "However, the repopulation efficiency of two candidate cell sources - hepatic progenitor/stem cells and mature hepatocytes - had not been comprehensively assessed and questions concerning the efficiency of each needed to be resolved."

The researchers noted that the shortage of cell sources and the difficulties of cryopreservation have limited the clinical application of cell based therapies. Stem or progenitor cells have been considered candidate cells because they can expand in vitro and can be cryopreserved for a long time.

However, after transplantation into liver injured rats, the researchers found that stem/progenitor cells did not survive well and most of the transplanted cells had disappeared within two months. In contrast, the mature hepatocytes gradually repopulated the rat livers and continued doing so past one year.

The researchers noted that the sizes of the hepatocytes were not uniform.

"Unexpectedly, the small hepatocytes repopulated significantly less well than the larger ones," explained Dr. Mitaka. "We also found that serial transplantation did not enhance nor diminish the repopulation capacity of the cells to any significant degree."

Original post:
Mature liver cells may be better than stem cells for liver cell transplantation therapy

SOUTHAMPTON, England, June 3 (UPI) -- British physicians say some patients with osteonecrosis who need hip replacements could be treated with stem cells from their own bone marrow.

The procedure, developed by Doug Dunlop of Southampton General Hospital in England, involves mixing the stem cells with cleaned, crushed bone from another patient who has had his own hip replaced and using it to fill the hole made after damaged tissue removed from the joint, The Daily Telegraph reported.

The new stem cell therapy could prevent the need for hip replacements due to osteonecrosis, a condition where poor blood supply causes significant bone damage leading to severe arthritis, Dunlop said.

The stem cells send chemical signals to blood vessels and it's hoped the new vessels in the hip would supply nutrients to improve bone strength, Dunlop explained.

Oesteoarthrits, caused by wear and tear of the bone, results from the temporary or permanent loss of blood flow to bones.

This causes osteonecrosis -- or the bones to "die" -- and ultimately severe arthritis, but if osteonecrosis occurs at the bone joint, it can cause it to collapse and the only option is a hip replacement, Dunlop said.

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Stem cells may preclude hip replacements

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Stem cells tested for heart attack repair