January 18, 2012 by

Umbilical cord stem cells may lead to new spinal cord injury and multiple sclerosis treatments

Researchers in Florida have accomplished converting umbilical cord stem cells into other cell types. According to University of Central Florida bioengineer James Hickman, it’s the first time that non-embryonic cells have accomplished this feat. His research group published this work in the January 18th issue of ACS Chemical Neuroscience.

Two major benefits of umbilical cord-derived stem cells are that they have not been shown to cause adverse immune system reactions and they pose no ethical issues since they come from a source that would be naturally discarded anyway.

Hedvika Davis, a post-doc researcher and lead author of the paper, had to search for the right chemical to coax the stem cells into becoming oligodendrocytes, which are cells that insulate nerves residing in the brain and spinal cord.

Other researchers had already shown that oligodendrocytes bind with a hormone called norepinephrine and Davis theorized that this could be the key. So she used norepinephrine and other growth factors to induce the cells to differentiate into oligodendrocytes. The only problem was that the cells were not sufficiently developed as they would be in the body.

So Davis devised a novel approach of approximating the body’s environment in the lab. By growing the cells on top of a slide, with another slide on top, Davis was able to simulate a 3-dimensional environment and grow mature oligodendrocytes.

Because oligodendrocytes produce myelin, researcher believe that this discovery might lead to treatments for multiple sclerosis, spinal cord injury and diabetic neuropathy.

Filed Under: Adult Stem Cells, Cord Blood Stem Cells, Multiple Sclerosis, News, Spinal Cord Injury, Stem Cell Research Tagged With: , , , , , ,
January 16, 2012 by

Blood from young mice helps older mice with multiple sclerosis

A new mouse study has shown that blood from young mice helps old mice to heal damage caused by MS.

MS causes myelin, which insulates nerve cells electrically, to become damaged. Stem cells can produce myelin but they lose efficiency in older patients.

Researchers in the UK have found a way to reverse this age-related efficiency loss. By linking the bloodstreams of young mice to old mice with myelin damage, the older stem cells were reactivated and boosted myelin production.

White blood cells from the young mice called macrophages were found at myelin damage sites in the old mice. These cells engulf and destroy pathogens and debris, including destroyed myelin.

Amy Wagers, from Harvard University says, “We know this debris inhibits regeneration, so clearing it up is important.”

Filed Under: Multiple Sclerosis, News, Stem Cell Research Tagged With: , , , , ,
January 15, 2012 by

Stem Cell Therapy For Spinal Cord Injury and A Layman’s Guide To Adipose Stem Cell Therapy – Stem Cell Institute Seminar in Gilbert, AZ

The Treatment of Human Diseases with Adult Stem Cells

 

We are proud to present and discuss the latest in adult stem cell treatments for diseases. Join us for informational presentations by:

Jorge Paz Rodriguez, MDA Layman’s Guide to Adipose Stem Cell Therapy

Neil Riordan, PhDAdult Stem Cell Therapy for Spinal Cord Injury

Patients will be on hand to discuss their experiences.

 

April 21, 2011
Saturday
12:30 pm – 4:00 pm

Legato Hotel
San Tan Elegante Conference Center
Gilbert, AZ 85296

Register at www.cellmedicine.eventbrite.com

(800) 980-STEM (7836)

clinic@cellmedicine.com

Filed Under: Adult Stem Cells, News, Spinal Cord Injury, Spinal Cord Injury, Stem Cell Research, Stem Cell Therapy Tagged With: , , , ,
January 12, 2012 by

Excerpts from Interview with Dr. Amit Patel, Director of Regenerative Medicine, University of Utah by Thomas Ichim, Ph.D, CEO of Medistem Inc

www.thelatestwith.com

Ichim: Which one was the first stem cell trial for cardiac conditions?

Patel: It is like one of those questions like who did the first heart operation. There is a lot of debate as to what was the first to use cells plus therapy and there have been a number of trials. Myoblasts were performed in 2000, the Chinese reported work performed in 1999 or 2000, and the Ralfstock guys in Germany 2000s. So there are a number of trials, including ours, all in the 2000-2003 period that where being conducted almost simultaneously.

Ichim: Pardon me for asking because I should really know this, which one was yours?

Patel: The original CABG plus cells, which was performed in South America and India.

Ichim: Lets talk about Phase 2 trials in cardiac, we all have seen the excellent co-development deal between Cephalon and Mesoblast that happened in December of last year and we are all interested in how far are they?

Patel: The Cephalon-Mesoblast work is interesting. They are doing a 60 patient randomized trial here in the US in patients with Class II-IV heart failure. From the data thus far released there is a significant reduction in treatment group in terms of adverse events as compared to the placebo control group, they have not reported any efficacy data in terms of ejection fraction and the like.

Something unique from the data they presented was that they showed up to 2/3 of the control group were class III heart failure and 2/3 of the treatment group were class II. The early data was very interesting and promising. The safety of the data was very eloquent and reproducible. One thing that was very unique was Erik Dukker’s European large animal acute MI data which was the best in terms of scar reduction for any allogeneic MSC that I have seen to date. That data, if it pans out, in humans will be very interesting.

Ichim: How did Mesoblast administer their cells? Did they use balloon catheter in the heart failure patients?

Patel: They used NOGA mapping and administration, in chronic heart failure, both ischemic and non-ischemia. They did not do acute myocardial infarction in this trial.

Their trial had similarities with our Phase II Aastrom, which also uses NOGA administration in treatment of patients with ischemic and non ischemic heart failure. It is different in that we were looking only at class III/IV heart failure.

Ichim: How is that trial coming along?

Patel: Ours is completed from the patient recruitment and treatment perspective.

We are waiting 6 month data. Our trial was a three center trial between myself, Tim Henry and Mark O’Costa. These three centers were heavy enrollers. We had low adverse events so far. This study involves patient’s own bone marrow stem cells expanded for 12 days using Aastrom’s proprietary bioreactor system.

Ichim: Lets go back to my question about Mesoblast. Remember we were chatting at the meeting about this. There seems to be a lot of different players in this field that are all using bone marrow derived stem cells. Obviously I believe endometrial derived stem cells possess numerous advantages. But there is Osiris’s mesenchymals, there is Athersys who are using Catherine Verfaille’s cells that seem to be like mesenchymal stem cells except for their smaller size. What is the cell that Mesoblast is using? Are they just another type of mesenchymal stem cell?

Patel: By name they call them the cells mesenchymal precursors. The Mesoblast cells are unique in that they express STRO-1 and VLA-4.

In my opinion everyone’s stem cells have unique properties and surface markers be they Osiris, Mesoblast, Athersys, Allocure, and a couple other products that are bone marrow based.

What is unique to see will be the IP landscape, are they same cells or cousins? This may be a situation like the CD133 versus CD34. In this field we know that all mesenchymal stem cells are not the same but the question will be how similar or different are they when you apply them clinically?

Ichim: Did we forget to mention any other ones?

Patel: I am sure that we did, but not for want to miss them but just because they have not made enough noise. Actually the one trial we forgot to discuss was the Athersys phase I which Warren Sherman from Columbia presented using the Cricket catheter, which is adventitial delivery, that was a very safe trial. It will be interesting to see how they do in the next generation for their phase II AMI study.

Ichim: That was very interesting. That was the one with the bizarre catheter that actually had a couple of needles in it?

Patel: That catheter had one needle, it causes a microperforation to allow for perivascular injection. This is a very innovative concept since people that use the standard intracoronary delivery techniques seem to have a lot of washout of the cells.

Ichim: I don’t get it. So they are making a small hole in the blood vessel, why is it that there is no bleeding or damage?

Patel: The microperforation is way too small. You do not perforate into the pericardium. It only barely perforates. However it does require a well highly trained skill set to manipulate that catheter. If you had been listening to Dr. Sherman’s presentation you would have seen that there were no catheter-related injuries.

Ichim: (Laughing). OK, what about the large Brazilian data? That was also a session that I didn’t listen through in entirety.

Patel: That data was 10 year follow-up on several Brazilian studies. The work was initially performed in heart failure using NOGA by Hans Doneman, then they had Emerson Perin and Jim Willerson. We also had our work which involved CABG. That was groundbreaking work that set the foundations for a lot of the cardiac cell therapy that is being performed today. We are still waiting to hear the outcomes of the studies that were funded by the government of Brazil including the work on Chagas, dilated cardiomyopathy, and CABG.

Ichim: Speaking of South America, what did Jorge Tuma present?

Patel: This was incredible data that had patients who have been followed for 8 years. Cell administration was performed via the retrograde technique which we developed with him. The original experiments involved bone marrow mononuclear cells isolated by ficoll, heap-starch, CD34, etc, he is now using the Harvest system for autologous bone marrow mononuclear cell collection. He presented data on ten patients treated with this.

Ichim: This is what I love about interviews, I can ask all sorts of questions about things that I should know but I don’t. What exactly is this “retrograde technique”? I have heard you mention it several times.

Patel: We access the venous system of the heart. We occlude the outflow and deliver the biologic into the heart. What is unique is that the venous system does not get the same atherosclerosis as the arterial system. This procedure has been around since 1898..its been around from back then…the idea was can we give oxygenated blood back to the heart. It was in the 50s and 60s when Illahi started to implement this. I use this in my heart operations to give chemicals and nutrients into the heart backwards during open heart operations…so I said how

Administration of cells using the retrograde technique takes me half hour to do. This appears to be a safe and cost efficient means to deliver a biologic to the heart on incredibly sick patients.

Ichim: To put in things in perspective regarding cell administration. I know that NOGA is expensive and not too many centers have it. But how long does it take to do a NOGA administration of stem cells into the heart?

Patel: 1-2.5 hours, usually 90 minutes at best, you are manipulating the inside of the heart so there is a risk of irregular rhtyums, also low risk of perforation

Ichim: I still don’t really understand this retrograde technique. How is it that the cells actually enter the heart? Do they actually cross into the tissue?

Patel: You block the outflow of the heart and under pressure you push the cells into the venous system. So you have created a column of cells. You have antegrade blood flow and retrograde stop flow, so the cells either go into the tissue or perforate the sinus…perforate the sinus is very rare, less than 1 % in over a couple hundred patients. These are microperforations in the venous system so it doesn’t require emergent surgery…all of the patients in which this has occurred have done well.

Juventas presented some data in large animals in which the SDF plasmid showed a significant uprgulation using retrograde techniques in contrast to other means of delivery.

Ichim: To switch topics I saw you on CNN about spraying stem cells on poor patients with bad burns, how do the cells go inside of the tissue?

Patel: We add calcium and thrombin, it looks like jello if you were to spray it into the petri disue, so you have retention by tissue adhesion and the mechanical properties of the collagen, thrombin and calcium, so you are creating a matrix for your biologic. So it really is spray on and it actually sticks there.

Ichim: I remember you now based in Utah, what ever happened to that company in your neck of the woods Allocure? How are they doing these days?

Patel: The last I heard they completed Phase I trial here in Utah, they were giving at the time of heart surgery for renal production. They have a bone marrow mesenchymal cell product. The trial is completed, we are looking to see what their next study will be. Will the stick to renal protection or will they follow other companies by entering CLI, heart failure, etc.

Ichim: You know, I was impressed by that company C3 or something like that, they were using differentiated cells for heart?

Patel: That was a Phase I/II trial by Joseph Bartnak where they have a bone marrow mesenchymal cell that was cultured in a procardiac cocktail. It was administered by noga or endocardial mapping. And again the data looked interesting…we look forward to their next trial and when they come to US

Ichim: What they were doing was really new in my humble opinion. It seems to me like everyone in this field is administering undifferentiated cells based on the belief or hope that the damaged tissue will program the undifferentiated stem cell to become a cardiomyocyte. To your knowledge are there other people using differentiated or semi-differentiated cells?

Patel: Yes of course. There is Capricor, Eduardo Marban’s company. They are taking a biopsy of the patient’s own heart, grow up the cells and put them back in. They don’t put the cardiospheres back in because they are too large but put in some cells derived from cardiosphere grown in vitro. One of the issues they are facing is that their procedure is very much dependent on the starting material. They were able to do biopsy but because there was large variability in the weight of the starting tissue, it is important to figure out how to get enough

Ichim: Conceptually it seems counter-intuative to take out heart from a patient with heart failure !

Patel: People do right heart biopsy in transplant patients, doing native heart biopsy you are always concerned about damaging the valve. Raj who was doing the procedure for them is a great interventionalist, but have to make sure that the procedure is designed so that other interventionalists who may not have his skill set can do it. The concept is great but manufacturing and reproducibility is important.

Filed Under: News Tagged With: , , , , , , ,
January 10, 2012 by

The Key to Better Health May Lie in Adult Stem Cells

One of the oldest people in the world, Sarah Knauss (119 years old), might have had more than just “good genes.” “Adult stem cells – known for their healing and regenerative properties – might hold the key to a long and healthy life,” says Wayne Marasco, MD, PhD, of Dana-Farber at the recent International Vatican Conference on Adult Stem Cells in Vatican City, Italy.

“We have learned in the past 10 years that there are all kinds of stem cells that circulate in the blood – they aren’t just found in bone marrow,” said Marasco, of Dana-Farber’s Department of Cancer Immunology and AIDS. “There are dozens of studies that support the fact that this is a large and dynamic population of cells that might help us keep our bodies healthy for a longer period of time.”

Stem cells are assigned to specialized zones in the body and called into action when the body faces stress or even a minor injury. For example, when someone has a heart attack or stroke, an agent is released into the blood, recruiting stem cells and directing them to the damaged tissue.

In addition to their healing powers, stem cell levels are also an indicator of future health. Studies have shown that a person’s level of endothelial progenitor cells, stem cells that form the tissues that line blood vessels, can predict whether or not a patient who has a heart attack will die or need major hospitalization.

Since stem cell levels can be modified through diet, lifestyle changes, or drugs, monitoring stem cells could prevent certain health risks and delay disease from occurring.

“The bottom line is that stem cells may be a better indicator of health and aging than the regular annual blood test, which was developed 50 years ago,” Marasco says. “Now that we know more about adult stem cells, this should be part of a routine test.”

Stem cell therapy may not be too far off in the future. Marasco says that doctors will soon be able to check stem cell levels in a drop of blood, using a finger-prick test much like those used by diabetics. Studies are also beginning to show the benefits of an FDA-approved molecule that improves the healing powers of stem cells, and the NIH has launched a new program that may lead to discoveries of already approved drugs that can boost adult stem cells.

“We can age gracefully, but we can also keep the body revitalized,” Marasco said. “The whole purpose of monitoring is to replenish our stem cells so that we can get more healthy years out of them.”

Filed Under: Adult Stem Cells, News, Stem Cell Research Tagged With: , , ,
January 6, 2012 by

Stem Cells May Reverse Age-Related Multiple Sclerosis Effects

Proof-of-principle study provides hope for stimulating remyelination

Scientists at Joslin Diabetes Center, Harvard University, and the University of Cambridge have found that the age-related impairment of the body’s ability to replace protective myelin sheaths, which normally surround nerve fibers and allow them to send signals properly, may be reversible, offering new hope that therapeutic strategies aimed at restoring efficient regeneration can be effective in the central nervous system throughout life.

In a proof-of-principle study published in the journal Cell Stem Cell, the researchers report that defects in the regeneration of the myelin sheaths surrounding nerves, which are lost in diseases such as multiple sclerosis may be at least partially corrected following exposure of an old animal to the circulatory system of a young animal. Myelin is a fatty substance that protects nerves and aids in the quick transmission of signals between nerve cells.

Using a surgical technique, the researchers introduced an experimental demyelinating injury in the spinal cord of an old mouse, creating small areas of myelin loss, and then exposed those areas to cells found the blood of a young mouse. By doing so, they found that the influx of certain immune cells, called macrophages, from the young mouse helped resident stem cells restore effective remyelination in the old mouse’s spinal cord. This “rejuvenating” effect of young immune cells was mediated in part by the greater efficiency of the young cells in clearing away myelin debris created by the demyelinating injury. Prior studies have shown that this debris impedes the regeneration of myelin.

“Aging impairs regenerative potential in the central nervous system,” says author Amy J. Wagers, PhD, an associate professor of stem cell and regenerative biology at Harvard University and Joslin, who co-led the study with Professor Robin Franklin, director of the MS Society’s Cambridge Centre for Myelin Repair at the University of Cambridge. “This impairment can be reversed, however, suggesting that the eventual development of cell-based or drug-based interventions that mimic the rejuvenation signals found in our study could be used therapeutically.”

This could be particularly useful, she adds, in treating MS, which typically spans many decades of life, and thus is likely to be influenced by age-dependent reductions in the ability of myelin to regenerate. In MS, the body’s own immune system attacks the myelin sheath and prevents nerve fibers in the brain from sending signals properly, which can cause mild symptoms such as limb numbness or more serious ones like losing the ability to walk or speak. As people with MS age, remyelination decreases significantly, eventually causing permanent loss of nerve fibers.

“For MS sufferers,” says Franklin, “this means that, in theory, regenerative therapies will work throughout the duration of the disease. Specifically, it means that remyelination therapies do not need to be based on stem cell transplantation since the stem cells already present in the brain and spinal cord can be made to regenerate myelin, regardless of a person’s age.”

Other Joslin co-authors of the study were Tata Nageswara Rao and Jennifer L. Shadrach.

About Joslin Diabetes Center
Joslin Diabetes Center, located in Boston, Massachusetts, is the world’s preeminent diabetes research and clinical care organization. Joslin is dedicated to ensuring that people with diabetes live long, healthy lives and offers real hope and progress toward diabetes prevention and a cure. Joslin is an independent, nonprofit institution affiliated with Harvard Medical School.

Filed Under: Multiple Sclerosis, Multiple Sclerosis, News, Stem Cell Research, Stem Cell Therapy Tagged With: , , , , , , , , ,
December 8, 2011 by

Adult Stem Cell Clinical Trials Showing Success

A Number of Clinical Trials Using Adult Stem Cells Are Showing Early Success

Dozens of adult stem cell treatments are moving through clinical trials and showing early success, raising hopes that some could reach the market within five years. ‘It will only take a few successes to really change the field,’ said Gil Van Bokkelen, chief executive of Athersys and chairman of the Alliance for Regenerative Medicine. ‘As you see things getting closer and closer to that tipping point, you’re going to see a frenzy of activity take place.’ Many of the trials focus on heart disease and inflammatory conditions, some of the biggest markets in medicine. The cells used are derived from adult tissue such as fat, or bone marrow, thereby circumventing the ethical concerns raised by the use of cells derived from embryos.

Data for the most part remains early, but as more results emerge, pharmaceutical companies are beginning to take note. ‘A lot of big companies are looking to place bets on some Phase II products once that data has been confirmed,’ said Paul Schmitt, managing partner at Novitas Capital. ‘Even now they’re attending all the medical meetings and talking to all the stem cell companies.’ Steven Martin, from Aspire Capital Partners LLC said they were willing to be patients as the benefits from treatment could be enormous. ‘My philosophy in the stem cell space is that it’s very difficult at this point to pick the winners and losers,’ he said. ‘We believe that over time there will be some very significant clinical progress, and valuations will improve, but we’re still a long way from an approved therapy.’

Aastrom Biosciences recently presented promising results from a mid-stage trial of its treatment for patients with critical limb ischemia, a disease in which blood flow to the extremities is restricted, at the American Heart Association’s annual meeting. A mid-stage trial from Australia’s Mesoblast Ltd showed its stem cell product reduced the rate of heart attacks and the need for artery clearing procedures by 78 per cent. ‘We’re actually developing products now,’ said Timothy Mayleben, chief executive of Aastrom, which is using cells derived from a patient’s own bone marrow to develop treatments for cardiovascular disease. ‘For the first time you are starting to see data being presented at major medical meetings.’ Pfizer Inc, Johnson & Johnson and Roche Holding AG are members of the Alliance for Regenerative Medicine, a nonprofit group that promotes awareness of the field. Pfizer has a regenerative medicine unit and a partnership with Athersys. But their projects are small as they want to wait to see data in hundreds of patients. The promise of stem cells, which have been used for 40 years in bone marrow transplants, lies in their ability to repair tissue, reduce inflammation, regulate the immune system, and respond to calls for help from multiple places inside the body. Stem cells are the body’s master cells – blank slates that renew themselves and mature into specific cell types in the heart, muscle and other organs.

Embryonic stem cells are uniquely capable of differentiating into every type of mature cell in the body, and were long viewed as the most promising for regenerating tissue. But harvesting stem cells from embryos requires the destruction of the embryo itself, a process opposed by conservative Christian groups. Moreover, their endless capacity to divide can lead to the formation of teratomas, or stem cell cancers. Recently, Geron Corp, the world’s leading embryonic stem cell company, said it could no longer fund its stem cell work and would focus on developing cancer drugs. It closed its trial for spinal cord injury. Unlike embryonic stem cells, adult stem cells have a more limited capacity to differentiate, but appear able to reduce inflammation and promote blood vessel formation. Furthermore, they can respond to damage in the body in a flexible and dynamic way, offering advantages over traditional drugs.
‘They seem to be preprogrammed to act some way in tissue repair, not to form an organ or a tissue,’ said Douglas Losordo, head of stem cell research at Baxter International Inc, which is developing cell therapies for heart disease. ‘The cells that we use are very effective at stimulating the formation of new blood vessels, but if I wanted to make a brain cell out of those cells they would not be very good at it.’ These are the type of stem cell treatments, delivered by infusion, injection or catheter, that are being developed today.
‘We wanted to create a product that everyone could receive and not have to match every donor to every recipient,’ said Robert Hariri, chief executive of Celgene’s Cellular Therapeutics unit.

Different types of stem cell are being used for different diseases. Cytori Therapeutics is developing a heart disease product derived from fat cells, for example, while Celgene is using placental cells for Crohn’s disease and rheumatoid arthritis therapies. Fetal cells are also being explored. Neuralstem Inc, for example, is developing treatments for neurological disorders from an aborted fetus. As cell therapies move further through clinical trials, companies will need more money, and funding is scarce.
Yet even if companies remain afloat long enough to bring a product through late-stage clinical trials, it is unclear what regulators like the Food and Drug Administration will require in order to approve them Some believe the regulatory hurdles for treatments derived from a patient’s own cells will be lower than those where the cells come from donors, since there is less risk of cell rejection. However, no clear pathway has yet been established. ‘We need a clear, consistent and rigorous regulatory framework,’ said Athersys’s Van Bokkelen. ‘The FDA is actually willing to provide lots of guidance and assistance to sponsors, if you just ask them.’

Filed Under: Adult Stem Cells, News, Stem Cell Research Tagged With: , , , , , ,
December 6, 2011 by

Stem Cell Treatments for Pemphygoid: Jane Wrede

“With such strong signs of remission and impatience with side effects, I took it upon myself to taper prednisone from 20 to 7.5mg/day and after 3 weeks at 7.5, I see no change in my healthy oral condition. All sores healed and no new blisters. I count this as successful!”

My name is Jane Wrede I have an autoimmune disease called Pemphygoid. Pemphygoid symptoms in my mouth and throat gradually improved after stem cell treatment so that my gums are firm, I feel no pain and can eat all but hot and spicy food! My eyes continue to be dry and I use sterile drops when they feel tired and sore. This is less severe than before and not until late in the day and sometimes at night. With such strong signs of remission and impatience with side effects, I took it upon myself to taper prednisone from 20 to 7.5mg/day and after 3 weeks at 7.5, I see no change in my healthy oral condition. All sores healed and not new blisters. I count this as successful!

Jane Wrede

Filed Under: Autoimmune Diseases, Patient Stories, Pemphygoid Tagged With: , , , , , ,
December 6, 2011 by

Stem cell therapy for juvenile dermatomyositis: Nathan Byrd

“Nathan, my son, is only on Prednisone at 3 mg q d now. Absolutely no problems at all. No weakness. No pain. No stiffness. Rash is gone. The calcinosis is less based on a recent x-ray. Flow cytometry was normal.

“(Nathan has) Absolutely no problems at all. No weakness. No pain. No stiffness. Rash is gone.”

How can I ever express my gratitude to all of you?”

– Richard W Byrd MD

Filed Under: Autoimmune Diseases, juvenile dermatomyositis, Patient Stories Tagged With: , , , ,
December 6, 2011 by

Healing juices’ of stem cells could help treat asthma

Research suggests future use of cells in kidney, heart disease
BY BRENT WITTMEIER, EDMONTON JOURNAL DECEMBER 2, 2011

University of Alberta pediatric asthma researcher says that the medical benefits of stem cells may lie in their by-product “healing juices”.

Dr. Bernard Thébaud believes the by-products of mesenchymal stem cells – found in umbilical cord tissue and with known anti-inflammatory characteristics – could possibly heal lungs inflamed by chronic and acute asthma.

The findings, published in the American Journal of Respiratory Cell and Molecular Biology, look at the effects of what Thébaud called “healing juices” on refractory asthma, a form of the disease that is particularly difficult to treat with inhalers.

Thébaud, a neonatal pediatrician and professor of pediatrics at the University of Alberta Faculty of Medicine and Dentistry, said the cells and their juices are easily isolated and cultivated in the lab.

“We cultured the cells in the petri dish, and instead of taking the cells, we just took what the cells produced, the juice they were basically swimming in,” Thébaud said. “We compared that to control cells cultured the same way, but didn’t have that same effect.”

Thébaud’s team created asthma in lab mice, then injected the juices through their noses. The by-products opened airways, restored breathing and reduced inflammation in their lungs.

Thébaud began researching pediatric lung disease in 2002, adding the “exciting” discipline of stem-cell research two years later. The new study builds on some of Thébaud’s previous research into how stem cells work.

“Initially we thought you have to give the cells (to the patient) because they replace dead cells,” he said. “That’s not actually the case.”

Thébaud initially used the mesenchymal stem cells in a study of newborn lung injury, discovering “tremendous benefits” for the health of the lungs. But when his research team tried to see where those stem cells were, they couldn’t find them.

“Maybe they don’t replace dead cells. Maybe they sit there and produce juices, then vanish,” he said.

Although the research is still at an early stage, Thébaud said his hope is for a “super-inhaler” five to 10 years from now that would heal inflammation, boost healthy cells and aid in breathing. He hopes to live the researcher’s dream and drive the discovery from his lab into the clinic.

His goal “would be to have a puffer with stem cell by-products that would prevent those symptoms of asthma,” he said.

Thébaud is convinced it could work. But exactly which compounds or factors are doing the “healing” is hardly academic, and will likely form the next stage in the research.

“It is the question,” said Thébaud. “First, we have to know should we not give the cells, or can we just deliver the juices. Do we have to know what’s in there?”

That question could also delay clinical research by an additional five years, the time he estimates it would take to synthesize the factor pharmaceutically. He will be discussing the study with Health Canada to determine barriers to clinical research using just undifferentiated by-products.

Thébaud also believes the approach demonstrates “many therapeutic avenues” beyond asthma, which affects an estimated 300 million people worldwide. The potential of stem-cell research isn’t yet known.

“It’s up to us now to harness the healing powers of these cells,” he said.

“We know it works in a variety of lung diseases. By extension, we know it will work in kidney, or heart or brain disease as well.”

Filed Under: Adult Stem Cells, Asthma, News, Stem Cell Research Tagged With: , , , , ,
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