National Research (NASDAQ:NRC) and US Stem Cell (OTCMKTS:USRM) are both small-cap business services companies, but which is the superior business? We will compare the two businesses based on the strength of their earnings, dividends, risk, institutional ownership, profitability, analyst recommendations and valuation.

Volatility & Risk

National Research has a beta of 0.77, indicating that its share price is 23% less volatile than the S&P 500. Comparatively, US Stem Cell has a beta of 5.08, indicating that its share price is 408% more volatile than the S&P 500.

Earnings and Valuation

This table compares National Research and US Stem Cells revenue, earnings per share and valuation.

National Research has higher revenue and earnings than US Stem Cell.

Analyst Ratings

This is a summary of recent recommendations and price targets for National Research and US Stem Cell, as reported by MarketBeat.com.

Insider and Institutional Ownership

39.6% of National Research shares are held by institutional investors. 4.5% of National Research shares are held by insiders. Comparatively, 16.7% of US Stem Cell shares are held by insiders. Strong institutional ownership is an indication that endowments, hedge funds and large money managers believe a stock is poised for long-term growth.

Profitability

This table compares National Research and US Stem Cells net margins, return on equity and return on assets.

Summary

National Research beats US Stem Cell on 7 of the 9 factors compared between the two stocks.

National Research Company Profile

National Research Corporation (NRC) is a provider of analytics and insights that facilitate revenue growth, patient, employee and customer retention and patient engagement for healthcare providers, payers and other healthcare organizations. The Companys portfolio of subscription-based solutions provides information and analysis to healthcare organizations and payers across a range of mission-critical, constituent-related elements, including patient experience and satisfaction, community population health risks, workforce engagement, community perceptions, and physician engagement. The Companys clients range from acute care hospitals and post-acute providers, such as home health, long term care and hospice, to numerous payer organizations. The Company derives its revenue from its annually renewable services, which include performance measurement and improvement services, healthcare analytics and governance education services.

US Stem Cell Company Profile

U.S. Stem Cell, Inc., a biotechnology company, focuses on the discovery, development, and commercialization of autologous cellular therapies for the treatment of chronic and acute heart damage, and vascular and autoimmune diseases in the United States and internationally. Its lead product candidates include MyoCell, a clinical therapy designed to populate regions of scar tissue within a patient's heart with autologous muscle cells or cells from a patient's body for enhancing cardiac function in chronic heart failure patients; and AdipoCell, a patient-derived cell therapy for the treatment of acute myocardial infarction, chronic heart ischemia, and lower limb ischemia. The company's product development pipeline includes MyoCell SDF-1, an autologous muscle-derived cellular therapy for improving cardiac function in chronic heart failure patients. It is also developing MyoCath, a deflecting tip needle injection catheter that is used to inject cells into cardiac tissue in therapeutic procedures to treat chronic heart ischemia and congestive heart failure. In addition, the company provides physician and patient based regenerative medicine/cell therapy training, cell collection, and cell storage services; and cell collection and treatment kits for humans and animals, as well operates a cell therapy clinic. The company was formerly known as Bioheart, Inc. and changed its name to U.S. Stem Cell, Inc. in October 2015. U.S. Stem Cell, Inc. was founded in 1999 and is headquartered in Sunrise, Florida.

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Reviewing US Stem Cell (OTCMKTS:USRM) & National Research (OTCMKTS:NRC) - Riverton Roll

Cardiac Stem Cells Comments Off on Reviewing US Stem Cell (OTCMKTS:USRM) & National Research (OTCMKTS:NRC) – Riverton Roll | February 8th, 2020

The recent outbreak of the coronavirus has shown us that our global health system is only as strong as its weakest link.

The key to stemming the spread of such illnesses lies in bolstering connectivity and communication between health bodies and thats precisely the theme here at Arab Health 2020.

Artificial intelligence means medical bodies can link up their data and act quickly in a crisis.

"As emergency physicians and practitioners were often on the frontline. But Ill give you an example of how technology and AI may help outbreaks, not just Coronavirus, but for seasonal influenza," says Dr Jacques Kobersy, emergency medicine institute chair, Cleveland Hospital Abu Dhabi.

"When you have an organisation like WHO who are alerted to the fact that there is some new virus circulating, Artificial intelligence might give us the opportunity to flag that those unusual symptoms are occurring way before human clinicians and departments of health realize it. And help us get ahead of these sort of pandemics maybe a month or so ahead of time before they really fester."

55,000 attendees from 159 countries have touched down in Dubai to showcase and learn about the life-changing and groundbreaking technologies poised to transform healthcare as we know it.

Autonomous ambulances

Soon, AI could make autonomous ambulances that automatically arrive at a patients house as soon as somethings wrong.

"We call it a smart ambulance. The high-risk patient, they will start to wear wearable devices. Let's say something happened to that patient. These devices will start to send all the vital data to the system and the hospital. So the physician, he can monitor all the data and monitor the patient 24 hour," says Dr Rashid al Hashimi - youth council member, UAE ministry of health (mohap).

In the future, the ambulance will be auto-drive. So it will go directly to the patient. While they are moving all these signals will be green for them.

When the patient enters the ambulance, there will be some high-resolution cameras. They will detect the patient's face and will give all the data which is very important for the rescuers to help the patient.

While they are going to the hospital, there will be like a virtual doctor inside the ambulance.

AI implants

AI is already powering implants that can monitor patients vitals around the clock.

"We can put devices under the skin and telemonitor heart patients even at home. We have put this device on 30 patients," says Dr Noor al Muhairi, head of medical services, hospital dept (mohap).

"One of them was in London. And we saw that we have an abnormality in his heart. And we called them directly and told him, go to the nearest hospital and this saved him."

And unprecedented advancements in stem-cell research mean damaged heart cells can now be regrown.

"In treatment, we collaborated with Osaka University, where they have done a study on stem cells that have been generated to cardiac cells. You can bring stem cells to make the heart cells regenerate," says Dr Muhairi.

"So this is one of the latest technology in heart treatment and in collaboration with Japan, we are going to do a clinical study here in the Ministry of Health."

Analysing wounds

Meanwhile, image analysis of wounds using machine learning can now prevent amputations caused by diseases like diabetes.

"This machine is checking the healing process for the diabetic foot. It will give us the results within 30 seconds. We are just scanning for the wound.2

"There is information going back 15 years in this machine. So it will check with other types of wound and it will analyze for us exactly the problem. We can prevent amputations from the complication of diabetes," says Dr Halima el Shehhi, the emergency department unit manager at the ministry of health and prevention, UAE.

Whether it's artificial intelligence, new equipment, new abilities to analyze patients and treat them, things that we could only imagine a few years ago now have come to fruition.

Soon the days of treating illnesses after they occur will give way to an age of truly preventative healthcare.

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AI is transforming healthcare as we know it: Arab Health 2020 - Euronews

Cardiac Stem Cells Comments Off on AI is transforming healthcare as we know it: Arab Health 2020 – Euronews | February 7th, 2020

Like most medical students, I struggled to memorize the Krebs cycle, the complex energy-producing process that takes place in the body's mitochondria. Rote learning of Sir Hans Krebs' eponymous cascade of reactions persists and has been cited as a waste of time in modern medical education. However, it looks like that specialized knowledge about mitochondrial structure and function may finally come in handy in the clinic.

Advances in genetics have contributed to improved diagnostic accuracy of a diverse spectrum of mitochondrial disorders. Respiratory chain, nuclear gene, and mitochondrial proteome mutations can lead to multisystem or organ-specific dysfunction.

A new potential treatment for mitochondrial disorders, elamipretide, has received orphan drug designation from the US Food and Drug Administration (FDA) and is in clinical trials sponsored by Stealth Biotherapeutics. [Dr Wilner has consulted for Stealth Biotherapeutics.] Recently I had the opportunity to interview Hilary Vernon, MD, PhD, associate professor of genetic medicine at Johns Hopkins University, Baltimore, Maryland, and an expert on mitochondrial disorders. Dr Vernon discussed her research on elamipretide as a treatment for Barth syndrome, a rare form of mitochondrial disease.

I am the director of the Mitochondrial Medicine Center at Johns Hopkins Hospital. I work with individuals from infancy through adulthood who have mitochondrial conditions. I became interested in this particular area when I was early in my pediatrics/genetics residency at Johns Hopkins and saw the toll that mitochondrial disorders took on patients' lives and the limited effective therapies. At that point, I decided to focus on patient care and research in this area.

Mitochondrial disorders can be difficult to recognize because of their inherent multisystem nature and variable presentations (even between affected members of the same family). However, there are several considerations that should raise a clinician's suspicion for a mitochondrial condition. Ascertaining a family history of disease inheritance through the maternal line can raise the suspicion for a mitochondrial DNA disorder. Identification of a combination of medical issues in different organ systems that are seemingly unrelated in an individual (ie, optic atrophy and muscle weakness or diabetes and hearing loss) can also raise suspicion for a mitochondrial condition.

Due to the nature of mitochondria as the major energy producers of the cells, high-energy-requiring tissues such as the brain and the muscles are often affected. Perhaps the best known mitochondrial diseases to neurologists are MELAS (mitochondrial encephalopathy, lactic acidosis, and stroke) as well as MERFF (myoclonic epilepsy with ragged red fibers). There is a nice body of literature on the effects of arginine and citrulline in modifying stroke-like episodes in MELAS, and this is a therapy that is in current practice.

Mitochondria are complex organelles whose structure and function are encoded in hundreds of genes originating from both the nucleus of the cell and the mitochondria themselves. Mitochondria have many key roles in cellular function, including energy production through the respiratory chain, coordination of apoptosis, nitrogen metabolism, fatty acid oxidation, and much more.

Various cofactors and vitamins can be employed to improve mitochondrial function for different reasons. For example, if a specific enzyme is dysfunctional, supplying the cofactor for that enzyme may improve its function (ie, pyruvate dehydrogenase and thiamine). Antioxidants have also been considered to help reduce the oxidant load that could potentially cause ongoing damage to the mitochondrial membrane resulting from respiratory chain dysfunction (ie, coenzyme Q-10).

It is important to remember that the highest number of individual mitochondrial disorders result from mutations in genes located in the nuclear DNA. For example, the TAZ gene that is abnormal in Barth syndrome is a nuclear gene located on the X chromosome. These genes are amenable to the "regular" approaches to gene therapy.

Targeting mitochondrial DNA for gene therapy requires a different set of approaches because the gene delivery has to overcome the barrier of the mitochondrial membranes. However, research is ongoing to overcome these obstacles.

Barth syndrome is a very rare genetic X-linked disorder that usually only affects males. The genetic defect leads to an abnormal composition of cardiolipin on the inner mitochondrial membrane. Cardiolipin is an important phospholipid involved in many mitochondrial functions, including organization of inner mitochondrial membrane cristae, involvement in apoptosis, and organization of the respiratory chain (which is responsible for producing ATP via the process of oxidative phosphorylation), and many of these functions are abnormal in Barth syndrome. Individuals with Barth syndrome typically have early-onset cardiomyopathy, myopathy, intermittent neutropenia, fatigue, poor early growth, among other health concerns.

Early in my post-residency career, I followed several patients with Barth syndrome and was quickly welcomed into the Barth syndrome community by the families and the Barth Syndrome Foundation. From there, I founded the only interdisciplinary Barth syndrome clinic in the US and began to focus a significant amount of my clinical and laboratory research on this condition.

Most commonly, these individuals come to medical attention because of cardiomyopathy, but a minority of patients do come to attention due to repeated infections and neutropenia. Patients were identified for study participation through the Barth Syndrome Foundation or because they were already patients of my study team.

All participants were known to have Barth syndrome prior to study entry, and all had confirmatory genetic testing showing a pathogenic mutation in the TAZ gene.

By binding to cardiolipin in the inner mitochondrial membrane, elamipretide is believed to stabilize cristae architecture and electron transport chain structure during oxidative stress. I thought it would be great if this could help to stabilize the abnormal cardiolipin components on the inner mitochondrial membrane in Barth syndrome.

We observed improvements in several areas across the study population in the open-label extension part of the study. This includes a significant improvement in exercise performance (as measured by the 6-minute walk test, with an average improvement of 95.9 meters at 36 weeks) and a significant improvement in muscle strength. We also observed a potential improvement in cardiac stroke volume. Most of the adverse events were local injection-site reactions and were mild to moderate in nature.

The TAZPOWER trial has an ongoing open-label extension with the same endpoints as the placebo-controlled portion evaluated on an ongoing basis. In addition, in my laboratory, we are using induced pluripotent stem cells to learn more about how cardiolipin abnormalities affect different cell types in an effort to understand the tissue specificity of disease. This will help us to understand whether different aspects of Barth syndrome would necessitate individual management or clinical monitoring strategies.

Mitochondrial inner membrane dysfunction is increasingly recognized as a major aspect of the pathology of a wide range of mitochondrial conditions. Therefore, based on the role of stabilizing mitochondrial membrane components, elamipretide has a potential role in many disorders of the mitochondria.

Yes, this is what we would call "secondary mitochondrial dysfunction" (meant to differentiate from "primary mitochondrial disease," which is caused by defects in genes that encode for mitochondrial structure and function). Approaches intended to protect the mitochondria from further damage, such as antioxidants or strategies that can bypass the mitochondria for ATP production, could overlap as treatment for primary mitochondrial disease and secondary mitochondrial dysfunction.

This is something that is much discussed as a newer consideration for families who are affected by disorders of the mitochondrial DNA, but not something I have experience with firsthand.

Yes. The United Mitochondrial Disease Foundation and the Mitochondrial Medicine Society collaborated to develop the Mito Care Network, with 19 sites identified as Mitochondrial Medicine Centers across the US.

Andrew Wilner is an associate professor of neurology at the University of Tennessee Health Science Center in Memphis, a health journalist, and an avid SCUBA diver. His latest book is The Locum Life: A Physician's Guide to Locum Tenens.

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Maybe Memorizing the Krebs Cycle Was Worthwhile After All - Medscape

Cardiac Stem Cells Comments Off on Maybe Memorizing the Krebs Cycle Was Worthwhile After All – Medscape | February 7th, 2020

Stem Cell Therapy Market: Snapshot

Of late, there has been an increasing awareness regarding the therapeutic potential of stem cells for management of diseases which is boosting the growth of the stem cell therapy market. The development of advanced genome based cell analysis techniques, identification of new stem cell lines, increasing investments in research and development as well as infrastructure development for the processing and banking of stem cell are encouraging the growth of the global stem cell therapy market.

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One of the key factors boosting the growth of this market is the limitations of traditional organ transplantation such as the risk of infection, rejection, and immunosuppression risk. Another drawback of conventional organ transplantation is that doctors have to depend on organ donors completely. All these issues can be eliminated, by the application of stem cell therapy. Another factor which is helping the growth in this market is the growing pipeline and development of drugs for emerging applications. Increased research studies aiming to widen the scope of stem cell will also fuel the growth of the market. Scientists are constantly engaged in trying to find out novel methods for creating human stem cells in response to the growing demand for stem cell production to be used for disease management.

It is estimated that the dermatology application will contribute significantly the growth of the global stem cell therapy market. This is because stem cell therapy can help decrease the after effects of general treatments for burns such as infections, scars, and adhesion. The increasing number of patients suffering from diabetes and growing cases of trauma surgery will fuel the adoption of stem cell therapy in the dermatology segment.

Global Stem Cell Therapy Market: Overview

Also called regenerative medicine, stem cell therapy encourages the reparative response of damaged, diseased, or dysfunctional tissue via the use of stem cells and their derivatives. Replacing the practice of organ transplantations, stem cell therapies have eliminated the dependence on availability of donors. Bone marrow transplant is perhaps the most commonly employed stem cell therapy.

Osteoarthritis, cerebral palsy, heart failure, multiple sclerosis and even hearing loss could be treated using stem cell therapies. Doctors have successfully performed stem cell transplants that significantly aid patients fight cancers such as leukemia and other blood-related diseases.

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Global Stem Cell Therapy Market: Key Trends

The key factors influencing the growth of the global stem cell therapy market are increasing funds in the development of new stem lines, the advent of advanced genomic procedures used in stem cell analysis, and greater emphasis on human embryonic stem cells. As the traditional organ transplantations are associated with limitations such as infection, rejection, and immunosuppression along with high reliance on organ donors, the demand for stem cell therapy is likely to soar. The growing deployment of stem cells in the treatment of wounds and damaged skin, scarring, and grafts is another prominent catalyst of the market.

On the contrary, inadequate infrastructural facilities coupled with ethical issues related to embryonic stem cells might impede the growth of the market. However, the ongoing research for the manipulation of stem cells from cord blood cells, bone marrow, and skin for the treatment of ailments including cardiovascular and diabetes will open up new doors for the advancement of the market.

Global Stem Cell Therapy Market: Market Potential

A number of new studies, research projects, and development of novel therapies have come forth in the global market for stem cell therapy. Several of these treatments are in the pipeline, while many others have received approvals by regulatory bodies.

In March 2017, Belgian biotech company TiGenix announced that its cardiac stem cell therapy, AlloCSC-01 has successfully reached its phase I/II with positive results. Subsequently, it has been approved by the U.S. FDA. If this therapy is well- received by the market, nearly 1.9 million AMI patients could be treated through this stem cell therapy.

Another significant development is the granting of a patent to Israel-based Kadimastem Ltd. for its novel stem-cell based technology to be used in the treatment of multiple sclerosis (MS) and other similar conditions of the nervous system. The companys technology used for producing supporting cells in the central nervous system, taken from human stem cells such as myelin-producing cells is also covered in the patent.

Global Stem Cell Therapy Market: Regional Outlook

The global market for stem cell therapy can be segmented into Asia Pacific, North America, Latin America, Europe, and the Middle East and Africa. North America emerged as the leading regional market, triggered by the rising incidence of chronic health conditions and government support. Europe also displays significant growth potential, as the benefits of this therapy are increasingly acknowledged.

Asia Pacific is slated for maximum growth, thanks to the massive patient pool, bulk of investments in stem cell therapy projects, and the increasing recognition of growth opportunities in countries such as China, Japan, and India by the leading market players.

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Global Stem Cell Therapy Market: Competitive Analysis

Several firms are adopting strategies such as mergers and acquisitions, collaborations, and partnerships, apart from product development with a view to attain a strong foothold in the global market for stem cell therapy.

Some of the major companies operating in the global market for stem cell therapy are RTI Surgical, Inc., MEDIPOST Co., Ltd., Osiris Therapeutics, Inc., NuVasive, Inc., Pharmicell Co., Ltd., Anterogen Co., Ltd., JCR Pharmaceuticals Co., Ltd., and Holostem Terapie Avanzate S.r.l.

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Stem Cell Therapy Market Trends and Growth, Outlook, Research, Trends and Forecast to 2025 - Instant Tech News

Cardiac Stem Cells Comments Off on Stem Cell Therapy Market Trends and Growth, Outlook, Research, Trends and Forecast to 2025 – Instant Tech News | February 6th, 2020

Hyperbaric oxygen therapy (HBOT) can improve heart functionality in healthy aging humans, according to a study by the Sagol Center for Hyperbaric Medicine and Research at Shamir Medical Center in Beer Yaacov.In this study, director of the Sagol Center for Hyperbaric Medicine and Research at Shamir Medical Center Prof. Shai Efrati and Dr. Marina Leitman, head of the Echocardiography Unit and Noninvasive Cardiology Service at Shamir Medical Center, turned their attention to HBOTs impact on cardiac function.According to the center, the study of HBOT for cardiac function has been limited, mostly evaluating patients during and after short-term exposures. However, for the first time, the study was conducted in humans and it demonstrated that repetitive HBOT protocols have a sustained effect on heart function.Healthy patients receiving HBOT to improve cognitive function underwent a 60-session treatment course using the Sagol Centers regenerative HBOT protocols. Using a high-resolution echocardiography, 31 patients were evaluated before HBOT was administered and three weeks after treatment concluded to identify the sustained effect of the treatment.HBOT includes the inhalation of 100% oxygen at pressures exceeding one atmosphere absolute [ATA], which is the average atmospheric pressure exerted at sea level, in order to increase the amount of oxygen dissolved in the body tissues, Efrati told The Jerusalem Post.Efrati, who has been pioneering new approaches for the application of HBOT treatments that specifically focus on HBOTs ability to trigger regeneration in the body, said that in the past HBOT was used mostly to treat chronic non-healing wounds.In recent years, there is growing evidence on the regenerative effects of HBOT, he said. We have now realized that the combined action of both hyperoxia (an excess of oxygen in the body) and hyperbaric pressure, leads to significant improvement in tissue oxygenation while targeting both oxygen and pressure sensitive genes, resulting in improved mitochondrial metabolism with anti-apoptotic (anti-cell death) and anti-inflammatory effects.According to Efrati, the newly developed protocols used in this study, which includes the intermittent increasing and decreasing of oxygen concentration, induces what is known as the Hyperoxic Hypoxic Paradox.This, he said induces stem cells proliferation and mobilization, leading to the generation of new blood vessels (angiogenesis) and tissue regeneration.Efrati said that during the first studies they conducted at the Sagol Center, they evaluated the beneficial effects of HBOT in treating traumatic brain injury and stroke. However, in this study we evaluated for the first time the effect of these new regenerative HBOT protocols on the normal aging heart. For the first time in humans we have demonstrated that HBOT can improve cardiac function.Efrati said for the last 12 years his team has developed an ongoing research program that investigates the regenerative effects of HBOT on different issues and degrees of damage. At the beginning we were focused on non-healing peripheral wounds. Then, we turned our focus to certain types of brain injuries.However, once the researchers found that HBOT induced many of the essential elements crucial to repairing almost any mechanism, we initiated a complementary research program that targets other organs such as the heart and other elements related to expected age-related functional decline.Along with normal aging, there is typically a decrease in cardiac function particularly in the mitochondrial cells of the heart, Efrati said.The mitochondria are the powerhouse of the cell [and] this is where we create energy, he said. HBOTs ability to improve mitochondrial function may explain the beneficial effects that we saw in the cardiac function of this normal aging population.By exposing the mitochondria to the fluctuations in oxygen by the use of HBOT, the team observed an improvement in contractility function of the heart meaning, the heart muscle contracted more efficiency over the course of the 60-session protocol.Efrati said the effect was particularly evident in the left ventricle, which is the chamber responsible for pumping oxygenated blood to the rest of the body.This is only the beginning of our understanding of the impact of HBOT on cardiac function in a normally aging population, and a larger and more diverse cohort will be required to further evaluate our initial findings, he said.Asked whether this treatment could also be used on people who are predisposed to heart conditions, Efrati said the short answer is yes, but he stressed that more research is needed.As far as we know, we are the first to identify HBOTs ability to improve cardiac function, Efrati said. Our study was on a group of 31 asymptomatic normal aging heart patients.We believe it is important to expand the scope of this study to a larger group, with both symptomatic and asymptomatic patients to understand the possibilities for HBOT as a treatment for patients with heart-related diseases, he said.The Sagol Center has also been studying the impact of HBOT on a variety of cognitive conditions.We have also conducted studies which showed positive results for the treatment of post-concussion syndrome as a result of traumatic brain injury, post-stroke recovery, fibromyalgia, Efrati said, adding that today, medical professionals understand that fibromyalgia is linked to issues in the brain center responsible for pain interpretation.Not every patient will benefit from HBOT, which is why patient selection should be done very carefully based on the damage seen in brain imaging assessments, he said.For example, if someone has a stroke, some of the tissue at the core of the stroke will die we will not be able to recover this tissue, Efrati said. But, other tissue that is damaged but not fully dead... is where HBOT can help.This damaged tissue, known as the metabolic dysfunction tissue (penumbra), is where we can have an impact and help recover lost function, he said.On the time line as to when using HBOT protocols may be put into effect on healthy aging patients in Israel, Efrati said these studies are already ongoing.I cant speak too much about this, as we are in the process of developing the results of the first study for publication, he said. However, we believe HBOT can positively impact both cognitive and physical performance in aging adults based on what we have seen at this point.Efrati said they will continue pursuing this line of research as it has the ability to transform how we look at aging.A number of research collaborations are ongoing, including research on cognitive decline, fibromyalgia and PTSD, he said.In addition, we have an ongoing research program on athletic performance both in professional and amateur level athletes, which looks at how HBOT may further improve performance, he said. Finally, we are studying the impact of HBOT on healthy aging adults to understand how HBOT may improve our health and cognitive performance as we age.When you look at aging as a disease that can be measured, then it can be treated, and this is a serious area of investigation for us, Efrati said.The study, led by Dr. Marina Leitman, Dr. Shmuel Fuchs, Dr. Amir Hadanny, Dr. Zvi Vered and Efrati, was published in the International Journal of Cardiovascular Imaging.

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Hyperbaric oxygen therapy can improve cardiac function in healthy, aging - The Jerusalem Post

Cardiac Stem Cells Comments Off on Hyperbaric oxygen therapy can improve cardiac function in healthy, aging – The Jerusalem Post | February 4th, 2020

When the tech VCs at Andreessen Horowitz entered biotech 4.5 years ago with the $200 million bio fund I, the idea was simple and hubristic: Were not going to do biotech, Vijay Pande said at the time, keeping a16zs longtime stance. Instead, the bio fund is really about funding software companies in the bio space.

In the near-half decade since, they havent softened their rhetoric. Pande and general partner Jorge Condes frequent blog posts often have the tone ofBurning Man technofuturists. Talking of a foundational shift in biology, bio-revolution, and the meaning of life, and dropping koans like what is medicine? has turned them into the well-financed New Age mystics of an AI-driven and bioengineered future.

Today, Andreessen Horowitz is launching bio fund III and putting $750 million behind it more than funds I and II combined. Theyve added new partners, as they did before fund I and II, picking up technologist and entrepreneur Julie Yoo and Vineeta Agarwala, a GV and Broad Institute alumn. Itll take much of the same tack as the earlier funds, investing early and occasionally up to Series B, and pouring funds not only into therapeutics, but also diagnostics, synthetic biology and startups bringing biological advances into other sectors, such as agriculture.

But Conde tells Endpoints News that the group has learned a thing or two since fund I. Pande had talked about extending Moores law to biology through digital therapeutics but they were wrong. It wasnt just about software and artificial intelligence. It was about the long list of ways how biology was done, how drugs were discovered and how the whole healthcare system functions. It was biotechs that worked both with machine learning and wet labs, and founders conversant in both.

Since then, theyve invested in companies like Insitro that integrate AI as a core but not sole part of a drug development chain and Asimov, which is trying to use AI and other tech systems to design a genome from scratch. They even invested in EQRx, Alexander Boriseys startup trying to use me-too drugs to change pricing.

In October, Conde, Pande and Yoo published their most soaring blog post yet: Biology is Eating the World: A Manifesto. They wrote: We are at the beginning of a new era, where biology has shifted from an empirical science to an engineering discipline.

Before the funds launch, though, Conde told Endpoints were at the end of the beginning for that era.

He talked about what theyve learned since bio I, where biology and biotech is headed and how well know when the convergence between engineering and biology hes been prophesizing has arrived.

You called this the end of the beginning for a new era. What does that mean?

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Striving for higher res imaging of cells, Harvard team debuts startup with backing from ARCH, Northpond - Endpoints News

Cardiac Stem Cells Comments Off on Striving for higher res imaging of cells, Harvard team debuts startup with backing from ARCH, Northpond – Endpoints News | February 4th, 2020

RESEARCH TRIANGLE PARK, N.C. , Feb. 04, 2020 (GLOBE NEWSWIRE) -- Asklepios BioPharmaceutical (AskBio), a clinical-stage adeno-associated virus (AAV) gene therapy company, and its NanoCor Therapeutics subsidiary today announced that the first patient has been dosed in a Phase 1 clinical trial of NAN-101. NAN-101 is a gene therapy that aims to activate protein phosphatase inhibitor 1 (I-1c) to inhibit the activity of protein phosphatase 1 (PP1), a substance that plays an important role in the development of heart failure.

Congestive heart failure (CHF) is a condition in which the heart is unable to supply sufficient blood and oxygen to the body and can result from conditions that weaken the heart muscle, cause stiffening of the heart muscles, or increase oxygen demand by the body tissues beyond the hearts capability.

"Dosing the first patient using gene therapy to target I-1c to improve heart function is a tremendous milestone not only for the AskBio and NanoCor teams but, more importantly, for patients whose quality of life is negatively affected by CHF, said Jude Samulski, PhD, Chief Scientific Officer and co-founder of AskBio. We initially developed this gene therapy as treatment for late-stage Duchenne muscular dystrophy patients who typically die from cardiomyopathy. Following preclinical studies, we observed that heart function improved, which led us to investigate treatment for all types of heart failure.

Were excited to be involved in this novel approach for patients with Class III heart failure, said Timothy Henry, MD, FACC, MSCAI, Lindner Family Distinguished Chair in Clinical Research and Medical Director of The Carl and Edyth Lindner Center for Research at The Christ Hospital in Cincinnati, Ohio, and principal investigator for the study. These patients currently have no other options besides transplant and left ventricular assist devices (LVAD). Today, we started to explore the potential of gene therapy to change their outcomes.

Heart disease is the leading cause of death worldwide, with CHF affecting an estimated 1% of the Western world, including over six million Americans. There is no cure, and medications and surgical treatments only seek to relieve symptoms and slow further damage.

Research by many investigators around the world has been trying to understand what exactly goes wrong in the heart and weakens its pumping activity until it finally fails, said Evangelia (Litsa) Kranias, PhD, FAHA, Hanna Professor, Distinguished University Research Professor and Director of Cardiovascular Biology at the University of Cincinnati College of Medicine. The aim has been to identify potential therapeutic targets to restore function or prevent further deterioration of the failing heart. Along these lines, research on the role of I-1c started over two decades ago, and it moved from the lab bench to small and large animal models of heart failure. The therapeutic benefits at all levels were impressive. It is thrilling to see I-1c moving into clinical trials with the hope that it also improves heart function in patients with CHF.

About the NAN-101 Clinical Trial NAN-CS101 is a Phase 1 open-label, dose-escalation trial of NAN-101 in subjects with NYHA Class III heart failure. NAN-101 is administered directly to the heart via an intracoronary infusion by cardiac catheterization in a process similar to coronary angioplasty, commonly used to deliver treatments such as stem cells to patients with heart disease. The primary objective of the study is to assess the safety of NAN-101 for the treatment of NYHA Class III heart failure, as well as assess the impact of this treatment on patient health as measured by changes in exercise capacity, heart function and other factors including quality of life.

AskBio is actively enrolling patients with NYHA Class III heart failure to assess three doses of NAN-101. Please refer to clinicaltrials.gov for additional clinical trial information.

Would you like to receive our AskFirst patient engagement program newsletter? Sign up at https://www.askbio.com/patient-advocacy.

About The Christ Hospital Health Network The Christ Hospital Health Network is an acute care hospital located in Mt. Auburn with six ambulatory centers and dozens of offices conveniently located throughout the region. More than 1,200 talented physicians and 6,100 dedicated employees support the Network. Its mission is to improve the health of the community and to create patient value by providing exceptional outcomes, the finest experiences, all in an affordable way. The Network has been recognized by Forbes Magazine as the 24th best large employer in the nation in the magazines Americas 500 Best Large Employers listing and by National Consumer Research as the regions Most Preferred Hospital for more than 22 consecutive years. The Network is dedicated to transforming care by delivering integrated, personalized healthcare through its comprehensive, multi-specialty physician network. The Christ Hospital is among only eight percent of hospitals in the nation to be awarded Magnet recognition for nursing excellence and among the top five percent of hospitals in the country for patient satisfaction. For more than 125 years, The Christ Hospital has provided compassionate care to those it serves.

About AskBioFounded in 2001, Asklepios BioPharmaceutical, Inc. (AskBio) is a privately held, clinical-stage gene therapy company dedicated to improving the lives of children and adults with genetic disorders. AskBios gene therapy platform includes an industry-leading proprietary cell line manufacturing process called Pro10 and an extensive AAV capsid and promoter library. Based in Research Triangle Park, North Carolina, the company has generated hundreds of proprietary third-generation AAV capsids and promoters, several of which have entered clinical testing. An early innovator in the space, the company holds more than 500 patents in areas such as AAV production and chimeric and self-complementary capsids. AskBio maintains a portfolio of clinical programs across a range of neurodegenerative and neuromuscular indications with a current clinical pipeline that includes therapeutics for Pompe disease, limb-girdle muscular dystrophy type 2i/R9 and congestive heart failure, as well as out-licensed clinical indications for hemophilia (Chatham Therapeutics acquired by Takeda) and Duchenne muscular dystrophy (Bamboo Therapeutics acquired by Pfizer). For more information, visit https://www.askbio.com or follow us on LinkedIn.

Link:
AskBio Announces First Patient Dosed in Phase 1 Trial Using AAV Gene Therapy for Congestive Heart Failure - BioSpace

Cardiac Stem Cells Comments Off on AskBio Announces First Patient Dosed in Phase 1 Trial Using AAV Gene Therapy for Congestive Heart Failure – BioSpace | February 4th, 2020

Pune, Feb. 03, 2020 (GLOBE NEWSWIRE) -- The global Mobility Devices Market size is projected to reach USD 14.86 billion by 2026, exhibiting a CAGR of 6.9% during the forecast period. Staggering rate of growth of geriatric population across the globe will be one of the crucial factors driving this market in the upcoming decade. Old age entails a plethora of disorders that generally restrict mobility in aged individuals and render them helpless. Given the rate at which the world population is ageing, the demand for devices aiding mobility is likely to spike. According the UNs Population Division, DESA, people at or above 60 years of age are currently numbered at 962 million. In the next three decades, the global geriatric population will reach 2.1 billion, predicts the DESA. Furthermore, old people are more susceptible to accidents associated deteriorating motor functions. For instance, the National Council of Aging estimates about 2.8 million aged Americans are rushed to hospital emergency rooms annually as a result of falling. Thus, a combination of aging and mishaps associated with the process will fuel the Mobility Devices Market trends during the forecast period.

For more information in the analysis of this report, visit: https://www.fortunebusinessinsights.com/industry-reports/mobility-devices-market-100520

Fortune Business Insights shares the above and other valuable market information in its recent report, titled Mobility Devices Market Size, Share & Industry Analysis, By Product (Wheelchairs, Mobility Scooters, Walking Aids, and Others); By End-user (Personal Users and Institutional Users); and Regional Forecast, 2019-2026, which states that the value of this market was at USD 8.75 billion in 2018. The report also provides:

Growing Aging Population and Rise in Mobility Impairment Disorders to Drive the Market

The older population around the globe is continuously growing at an unprecedented rate. Aging decreases the ability to move and reduces the ability to perform physical tasks to maintain independent functioning among the elderly population. The growing older population count is likely to increase the percentage usage of mobile devices during the forecast period. According to the World Health Organization (WHO), in 2017, the global population aged 60 years or over was around 962 million and is projected to reach about 2.1 billion by 2050. Rising prevalence of chronic conditions such as arthritis, cerebral palsy, and muscular dystrophy among every age group is expected to increase the demand for highly advanced mobility aid devices during the forecast period.

Request a Sample Copy of the Research Report: https://www.fortunebusinessinsights.com/enquiry/request-sample-pdf/mobility-devices-market-100520

North America to Lead the Pack; Europe to Follow Closely

Among regions, North America is set to dominate the Mobility Devices Market share owing to the rising prevalence mobility-related disorders in the region. Coupled with this is the increasing number of aged people in the region, which will propel the regional market.

Europe is anticipated to be the second most dominant region in this market on account of high proportion of aged people with mobility impairment. Asia-Pacific is touted to be the most promising region as geriatric population in the region is growing, while unmet needs of the people in Latin America, the Middle East, and Africa will create lucrative market opportunities.

Focus on Patient Safety and Comfort to Drive Innovation Among Players

Strengthening market position is expected to be the primary focus of key players in this market, says one of our lead analysts. One of the leading strategies adopted is increasing investment in innovation to come up with novel solutions, keeping patient comfort and safety in mind. Some players are also expanding their global presence through collaborations and acquisitions.

Industry Developments:

List of Top Players Profiled in the Mobility Devices Market Report:

Have Any Query? Ask Our Experts: https://www.fortunebusinessinsights.com/enquiry/speak-to-analyst/mobility-devices-market-100520

Detailed Table of Content:

TOC Continued.!

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Mobility Devices Market to Reach $14.86 Billion by 2026; Rising Incidence of Physical Disabilities Worldwide to Favor Growth of the Market: Fortune...

Cardiac Stem Cells Comments Off on Mobility Devices Market to Reach $14.86 Billion by 2026; Rising Incidence of Physical Disabilities Worldwide to Favor Growth of the Market: Fortune… | February 3rd, 2020

UAB Magazine

Written by Charles Buchanan, Brett Bralley and Jay Taylor with editorial contributions from Matt Windsor and UAB Public Relations. Images from UAB Archives, Rachel Hendrix, Andrea Mabry, Sarah Parcak, Steve Wood and Getty Images. Web design by Tyler Bryant. Reprinted by permission of UAB Magazine.

UABs birth was like a ray of sunlight punching through the smog.

In 1969 the newly independent university, uniting a pioneering academic medical center and a growing extension center, brought the promise of a brighter future to a city eager for change.

Birmingham is better because of UAB. So are Alabama, America, and the world. In the following pages, discover some of the many ways that UAB has fulfilled its promiseby saving lives, solving problems, expanding knowledge, and opening doorsover 50 years.

1

Best of the best

UABs accolades shine a global spotlight on Birmingham and Alabama:

2

A way to retrain the brain

Most scientists once believed that neuroplasticitythe brains ability to grow or repair itselfended in childhood. But research by UAB neuroscientist Edward Taub, Ph.D., contributed to a shift in thinking, and in the 1990s he developed constraint-induced (CI) therapy for stroke patients with poorly functioning limbs. As the intensive training helps patients learn to accomplish tasks with their affected limbs, the brain adapts by strengthening communication with those parts of the body. And the results have been remarkable: Most patients see a clinically significant level of improvement in their ability to use their affected limbs, and brain scans have shown an increase in gray matter. Taub and UAB clinical psychologist Gitendra Uswatte, Ph.D., have used CI therapy to help thousands of stroke patientsand adapted it for patients impacted by cerebral palsy, traumatic brain injury, multiple sclerosis, and spinal cord injury. Today CI therapy is in use worldwide.

3

Discoveries on ice

UAB scientists conduct a lot of research in the fieldbut none may go as far afield as James McClintock, Ph.D.; Charles Amsler, Ph.D.; and Maggie Amsler. Their investigations take place at Palmer Station, Antarctica6,898 miles from their campus offices. For two decades, the biologists have led teams that dive into the frigid waters surrounding the icy continent to study the chemical ecology of the unique marine algae and invertebrates living there. What theyve discovered could aid the search for new drugs to help humans. The group also chronicles the dramatic impact of climate change, such as ocean acidification, on Antarctic marine life. You can see climate change happening there like no other place on earth, says McClintock.

4

A pinch of prevention

UAB endocrinologist Constance Pittman, M.D., turned her research passioniodines impact on thyroid functioninto a global mission. In the 1990s and 2000s, she teamed up with Kiwanis International and UNICEF to help eradicate iodine deficiency disorders (IDD), a prevalent cause of cognitive disabilities. Pittman traveled the world to convince companies to add iodine to table saltthe simplest solution for preventing IDD. And her work helped make a lasting impact.

5

Target: Diabetes

In 1973, UAB opened the nations first public diabetes hospitaland the first linked with an academic medical center. Today physicians on the front lines of the diabetes epidemic have an exciting new option to help their patients, thanks to breakthrough research from UABs Comprehensive Diabetes Center.

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Sharing stories that matter

WBHM 90.3 FM radio went on the air in 1976 as the 200th National Public Radio (NPR)-affiliated station. A member-supported service of UAB, WBHM provides global news and award-winning local coverage to Birmingham and the surrounding region. The station also recently welcomed StoryCorps, an NPR-affiliated initiative, to collect stories from the Birmingham community that will be housed at the Library of Congress in Washington, D.C.

7

Book of Life

Its tough to find a physician anywhere in the world who hasnt learned a few things from Tinsley Harrison, M.D. The legendary School of Medicine cardiologist and dean created and edited Harrisons Principles of Internal Medicine, which has been reprinted 20 times, translated into 14 languages, and become arguably the most recognized book in all of medicine, according to the Journal of the American Medical Association.

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Foresight

The School of Optometry has been a pioneer since it opened in 1969 as the nations first optometry school associated with an academic medical center. Three years later, it became the first optometry teaching program affiliated with a Veterans Administration (VA) hospital, establishing a national model. Today more than 2,500 optometry staff and students from various schools work in the VA system nationwide.

9

Helping our hometown

Living and working in the heart of the city, UAB students, faculty, and staff cant help but feel a connection to Birmingham. Here are just a few ways Blazers have volunteered to support their neighbors:

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A whole new ball game

Gene Bartow Mens basketball coach1977-1996

UAB started a winning tradition in 1977 when it hired coach Gene Bartow away from powerhouse UCLA to start a mens basketball program. He created a legendary team able to topple top rivals and reach the NCAA Tournament in just its third seasonthe first of 15 NCAA Tournament and 12 National Invitational Tournament appearances on its record. As UABs first athletic director, Bartow also helped UAB compete in other arenas. Today student-athletes in 18 sports give Birmingham reasons to cheer. Take a spin through some of the Blazers most memorable moments:

11

New views of history

Its as if Indiana Jones and Google Earth had a love child. Thats how UAB anthropology faculty member and National Geographic fellow Sarah Parcak, Ph.D., described space archaeology to Stephen Colbert on The Late Show in 2016. She has pioneered the use of high-resolution satellite imagery to search for the buried remains of lost civilizations. And her discoveries have thrilled people worldwide, including Colbert. She was even mentioned in a Jeopardy! answer earlier this year.

12

Defense team

UAB immunologists have been among the first to shed light on the mechanisms powering our bodys defenses:

13

Game changers

Future football helmets may better protect athletes thanks to mechanical engineering professor Dean Sicking, Ph.D. (Before coming to UAB, he developed the lifesaving SAFER barriers used on NASCAR and IndyCar courses.) Analyzing data from thousands of helmet-to-helmet impacts in football, Sicking has developed designs for a new helmet that could address concussionsabsorbing as much energy of the impact as possible so that the athlete has less risk of brain injury.

14

The dividends of discovery

In 2018-2019, UAB received $602 million in research grants and awardsjust one year after surpassing the $500-million milestone for the first time. We are aiming high and exceeding our goals, and it is a testament to the UAB research communitys great ideas, hard work, and will to succeed, says Christopher Brown, Ph.D., vice president for research. A rise in research funding means more opportunities to explore the frontiers of knowledgebut it also enables UAB to attract top minds from around the country in health care, engineering, the sciences, and more, plus create new jobs that boost the local economy. Want to ensure that UAB continues its upward trajectory? Philanthropic support helps position the university to attain competitive research grants.

15

Giant leaps

Space is the place for UAB people and technology:

Researcher Larry DeLucas, O.D., Ph.D., became the first optometrist in orbit with a 1992 mission aboard the shuttle Columbia. There he conducted experiments to grow protein crystals, which give scientists a 3D view of protein structuresand a greater understanding of the roles they play in disease. DeLucas also served as chief scientist for the International Space Station in 1994-1995.

Astrophysicist Thomas Wdowiak, Ph.D., passed away in 2013, but his name lives onon Mars. The Red Planets Wdowiak Ridge honors the physics faculty members role in NASAs Mars Exploration Project. Wdowiak was in charge of operating the Mossbauer spectrometers onboard the Spirit and Opportunity rovers that helped uncover firm evidence that water once existed on Mars.

16

Focus on finances

Would you like to get better at saving, budgeting, or investing? Or do you dream of launching a business? The Regions Institute for Financial Education in the Collat School of Business has been helping people throughout the community develop practical, lifelong financial management skills since 2015. Some of its programs include a Money Math Camp for middle schoolers, a College Bridge Camp to prepare high schoolers for life after graduation, and for adults, a Do-It-Yourself Credit Repair Workshop.

17

Going green

Campus expansions have reshaped Birminghams Southside, and UAB works hard to be a good steward of that spaceand set a sustainable example. In 2008, UAB brought open green space into the heart of Birmingham by converting a city street into the Campus Green. Now UAB is aiming to reduce its greenhouse gas emissions by 20 percent and establish a clean energy standard of 20-percent renewable energy by 2025.

18

Ingenuity vs. Infection

Virus vanguards

Antiviral therapies are essential for treating everything from influenza to HIV. In 1977, UAB pediatrics experts Richard Whitley, M.D., and Charles Alford, M.D., helped spark the antiviral revolution by developing vidarabine, the first drug to treat encephalitis caused by the herpes simplex virus. In the 1990s, Whitley and his team transformed the herpes virus into a genetically engineered weapon against tumors.

Vaccines for everyone

The laboratory of Moon Nahm, M.D., is a national treasure, notes the National Institutes of Health. But its discoveries could help protect millions of children worldwide threatened by S. pneumoniae infections, the leading cause of pneumonia. (Nahms lab also is designated a World Health Organization Pneumococcal Reference Laboratory.) His mission is to make pneumonia vaccines more affordable for use in developing countries.

Global guardian

GeoSentinel is a worldwide network of clinics watching for potential pandemics in an increasingly interconnected world, ready to relay information quickly about new disease outbreaks and effective treatments. And it has Alabama roots. UAB travel medicine expert David Freedman, M.D., cofounded GeoSentinel, a collaboration between the International Society for Travel Medicine and the Centers for Disease Control and Prevention, in the 1990s. He also directed the network for 20 years.

19

Staying safe on the road

In 2002, UAB public health researchers unveiled the Digital Childa pioneering computer model evaluating the physical consequences of car crashes on young passengers at various stages of developmentto generate data that could lead to improved child safety devices. Shift gears to today, and researchers in UABs TRIP (Translational Research for Injury Prevention) Lab use virtual realitya first-of-its-kind SUV simulator built with Honda Manufacturing of Alabamato study distracted driving in an effort to save lives. The TRIP Lab also has a portable simulator for schools and community events to help educate students and others on the dangers of distracted driving.

20

A home for Birmingham history

Odessa WoolfolkEducator and civic leader

When Birmingham first dreamed of developing a civil rights museum and research center, UABs Odessa Woolfolk, then special assistant to the president and director of community relations, and Horace Huntley, Ph.D., a historian and first director of the African American studies program, helped lead efforts to turn that idea into a reality. The Birmingham Civil Rights Institute opened in 1992, with Woolfolk as president of its board of directors. Huntley also directed the institutes Oral History Project, which preserves the accounts of foot soldiers and other witnesses to the Birmingham campaign. Today the BCRI attracts visitors from around the world and is a key component of the Birmingham Civil Rights National Monument.

21

Invention in action

Faculty, staff, and students are designing the future for the rest of us. Preview some of their ingenious solutions:

Each year, biomedical engineering and business students develop technologies to help people overcome physical limitations. Examples include a joystick-controlled wheelchair for toddlerswhich won an international awardbuilt for the Bell Center for Early Intervention Programs, and a special scale to help wheelchair users monitor their weight, used by the Lakeshore Foundation. Another design, a mechanical umbrella to protect power wheelchair users from rainy weather, scored second place at the 2018 World Congress on Biomechanics.

Graphic design students in UABs Bloom Studio unleash their talents to support local nonprofits and underserved communities. You can spot their work on license plates and signs that promote and protect the Cahaba Riverpart of a collaboration with the Cahaba River Society.

Solution Studios pairs Honors College, engineering, and nursing students with UAB health professionals to tackle everyday problems affecting patient care. One team has designed a device prototype that could improve quality of life for patients wearing ostomy bags to expel waste. Another has focused on new, more comfortable methods of applying wires to the skin in settings such as intensive care units.

22

Spreading the word

Low literacy levels translate into increased high school dropout rates, a lower-performing workforce, and higher rates of social problems, say UAB School of Education experts. For years UABs Maryann Manning, Ed.D., led the charge to improve literacy across Alabama, launching programs such as a conference that attracted thousands of local schoolchildren to share their writing with authors and illustrators. Today the Maryann Manning Family Literacy Center continues her legacy, providing enrichment activities in reading, writing, math, arts, and science for children and helping teachers across Alabama learn innovative strategies to foster literacy skills in their classrooms.

23

The heart of innovation

John Kirklin, M.D.Surgery superstar

John Kirklin, M.D., helped put Birmingham on the medical map when he was recruited in 1966 to chair the Department of Surgery. He already was a superstar at the Mayo Clinic, where he had revolutionized cardiovascular surgery by improving the heart-lung machine and performing the first operations for a variety of congenital heart malformations. At UAB he continued to pursue new methods and techniques, such as the development of a computerized intensive care unit with continuous monitoring of vital functions, which became a model for ICUs worldwide.

When Kirklin passed away in 2004, colleagues estimated his medical innovations had saved millions of lives. And his legacy thrives in other ways: UAB is a world-class medical center in part because of Kirklins work behind the scenes, where he championed the combination of public and private investments to foster growth. His textbook, Cardiac Surgery, remains a must-read for anyone in the field. His name lives on in The Kirklin Clinic of UAB Hospital, which opened in 1992. And his son, cardiothoracic surgeon James Kirklin, M.D., directs UABs James and John Kirklin Institute for Research in Surgical Outcomes.

24

Birthplace of new businesses

UABs ideas and energy are an engine for entrepreneurship. The university was a founder of Birminghams Innovation Depot, where start-up companiessome born from UAB research breakthroughsfind the resources they need to grow. Today Innovation Depot is the Southeasts largest high-tech business incubator, home to more than 100 companies.

25

University of opportunity

In the fall of 2019, underrepresented students made up nearly 42 percent of UABs enrollment, and 20.5 percent of undergraduates were first-generation students. UAB has a long history of widening access to higher educationand potential careers in science and health careamong diverse students. Back in 1978, the Minority High School Research Apprentice Program began matching local students with faculty members for summer research experiences. Today, initiatives such as the Department of Surgerys Pre-College Internship for Students from Minority Backgrounds and the Neuroscience Roadmap Scholars program offer similar opportunities for students along their educational journeys.

26

Successful careers begin here

More than 135,000 alumni call UAB their alma mater. Today youll find them across the United States and around the world, working as leaders in health care, science, business, art, engineering, government, education, and other fields. Many stay connected with UAB through the National Alumni Society, which was established in 1979 and has 63 chapters in locations ranging from Washington, D.C., to Taiwan.

27

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UAB: 50 years of Improving Birmingham, Alabama and the World - Birmingham Times

Cardiac Stem Cells Comments Off on UAB: 50 years of Improving Birmingham, Alabama and the World – Birmingham Times | February 3rd, 2020

By the time Bill Beatty made it to the Emergency Department in Howard County, he was already several hours into a major heart attack. His physicians performed a series of emergency treatments that included an intra-aortic balloon pump, but the 57-year-old engineers blood pressure remained dangerously low. The cardiologist called for a helicopter to transfer him to Johns Hopkins.

It was fortuitous timing: Beatty was an ideal candidate for a clinical trial and soon received an infusion of stem cells derived from his own heart tissue, making him the second patient in the world to undergo the procedure.

Of all the attempts to harness the promise of stem cell therapy, few have garnered more hope than the bid to repair damaged hearts. Previous trials with other stem cells have shown conflicting results. But this new trial, conducted jointly with cardiologist Eduardo Marbn at Cedars-Sinai Medical Center in Los Angeles, is the first time stem cells come from the patients own heart.

Cardiologist Jeffrey Brinker, M.D., a member of the Hopkins team, thinks the new protocol could be a game-changer. That's based partly on recent animal studies in which scientists at both institutions isolated stem cells from the injured animals hearts and infused them back into the hearts of those same animals. The stem cells formed new heart muscle and blood vessel cells. In fact, says Brinker, the new cells have a pre-determined cardiac fate. Even in the culture dish, he says, theyre a beating mass of cells.

Whats more, according to Gary Gerstenblith, M.D., J.D., the animals in these studies showed a significant decrease in relative infarct size, shrinking by about 25 percent. Based on those and earlier findings, investigators were cleared by the FDA and Hopkins Institutional Review Board to move forward with a human trial.

In Beattys case, Hopkins heart failure chief extracted a small sample of heart tissue and shipped it to Cedars Sinai, where stem cells were isolated, cultured and expanded to large numbers. Hopkins cardiologist Peter Johnston, M.D., says cardiac tissue is robust in its ability to generate stem cells, typically yielding several million transplantable cells within two months.

When ready, the cells were returned to Baltimore and infused back into Beatty through a balloon catheter placed in his damaged artery, ensuring target-specific delivery. Then the watching and waiting began. For the Hopkins team, Beattys infarct size will be tracked by imaging chief Joao Lima, M.D., M.B.A.,and his associates using MRI scans.

Now back home and still struggling with episodes of compromised stamina and shortness of breath, Beatty says his Hopkins cardiologists were fairly cautious in their prognosis, but hell be happy for any improvement.

Nurse coordinator Elayne Breton says Beatty is scheduled for follow-up visits at six months and 12 months, when they hope to find an improvement in his hearts function. But at least one member of the Hopkins team was willing acknowledge a certain optimism. The excitement here, says Brinker, is huge.

The trial is expected to be completed within one to two years.

--by Ramsey Flynn

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A New Path for Cardiac Stem Cells - hopkinsmedicine.org

Cardiac Stem Cells Comments Off on A New Path for Cardiac Stem Cells – hopkinsmedicine.org | February 2nd, 2020

Comparing between SARS, MERS and 2019-nCOv

The Wuhan coronavirus or novel 2019 nCoV, has spread like a wildfire across China and reached the shores of 22 countries as of now. In a bid to stem the spread of the disease, countries have resorted to various preventive and arresting measures. Many laboratories are in the process of formulating a vaccine. However, combating this new pathogen is proving to be a global challenge.

A new study by researchers from the University of Minnesota suggests that understanding the Severe acute respiratory syndrome virus (SARS) or SARS-CoV, which caused global panic in 2002-2003 may help combat the new coronavirus.

After a structural study that lasted for ten years, the researchers have been able to demonstrate the manner of interaction between the SARS-CoV and animals, and human hosts that lead to infection in them. The scientists suggest that the mechanism of infection of the Wuhan coronavirus exhibits similarities to the SARS-CoV, which also is a coronavirus.

Using the data and information acquired from multiple strains of SARS-CoV from diverse hosts from different years, and studying the angiotensin-converting enzyme-2 (ACE2) receptors from various species of host animals, the scientists modelled predictions for the Wuhan coronavirus. Normally, the enzyme is associated with the regulation of cardiac functions. However, both these viruses have been found to gain entry into healthy cells by using ACE2.

"Our structural analyses confidently predict that the Wuhan coronavirus uses ACE2 as its host receptor," the researchers wrote in the study. They state that various other structural details of the new coronavirus are consistent with the ability of the SARS-CoV to recognise the ACE2 receptors to infect the cells, playing a determining role in transmission from hosts to human beings, and human to human.

The researchers also stressed that a single mutation has the ability to increase the potency with which the virus can infect humans. "Alarmingly, our data predict that a single mutation [at a specific spot in the genome] could significantly enhance [the Wuhan coronavirus's] ability to bind with human ACE2," they stated in the study.

It is because of this danger that the evolution of the Wuhan virus among patients must be monitored closely to spot novel mutations in its genomes, the scientists add. This continuous examination may help predict the possibility of an outbreak that could be far more serious than the ones being witnessed the authors stress.

"One of the long -term goals of our previous structural studies on SARS -CoV was to build an atomic -level iterative framework of virus-receptor interactions that facilitate epidemic surveillance, predict species-specific receptor usage and identify potential animal hosts and likely animal models of human diseases," highlighted the authors.

They conclude that this study provides translational and public health research communities with a reiterative framework that may help provide predictive insights enabling the better understanding and counter of the novel 2019 -nCoV.

Read the rest here:
Coronavirus is similar to SARS and causes infection through a heart regulating enzyme: Study - International Business Times, Singapore Edition

Cardiac Stem Cells Comments Off on Coronavirus is similar to SARS and causes infection through a heart regulating enzyme: Study – International Business Times, Singapore Edition | February 2nd, 2020

This weeks Round-up looks to the future, as nanoparticles and stem cell-derived cardiac muscle cells get a closer look. More good news for lovers of yogurt, and a smelly but effective treatment for atherosclerosis as well.

Using stem cells extracted from the patients own blood and skin cells, this Japanese research team completed the first-in-human transplant of cardiac muscle cells derived from pluripotent stem cells. The team achieved this by reprogramming them, reverting them to their embryonic-like pluripotent initial state. I hope that (the transplant) will become a medical technology that will save as many people as possible, as Ive seen many lives that I couldnt save, Yoshiki Sawa, a professor in the Osaka University cardiovascular surgery unit, said in apress report.

Stem Cell-Derived Heart Muscle Transplanted Into Human for First Time: Researchers

Like something from a sci-fi horror novel, this team of researcher examined the role that nanoparticles that eat dead cells and stabilize atherosclerotic plaque may be able to play in the future of atherosclerosis treatment. We found we could stimulate the macrophages to selectively eat dead and dying cells these inflammatory cells are precursor cells toatherosclerosis that are part of the cause of heart attacks, one of the authors said in press release. We could deliver a small molecule inside the macrophages to tell them to begin eating again. The authors noted that after a single-cell RNA sequencing analysis, they observed that the prophagocytic nanotubes decreased inflammatory gene expression linked to cytokine and chemokine pathways in lesional macrophages, thereby treating the cell from the inside out.

Are Nanoparticles Potential Gamechangers for Treating Clogged Arteries?

In this large analysis of more than 120,000 individuals, the authors reported multivariable-adjusted hazard ratios (95% CI for all) for mortality were reduced in regular (more than four servings per week) consumers of yogurt, and there was an inverse relationship between regular consumption and cancer mortality as well as cardiovascular-related mortality in women. In our study, regular yogurt consumption was related to lower mortality risk among women, the authors wrote. Given that no clear doseresponse relation was apparent, this result must be interpreted with caution.

Yogurt Consumption Associated with Reduced Mortality Risk (Plus a Caveat)

This research teamlooked human microphages and compared them to dying cells in a dish. They observed that macrophages reclaim arginine and other amino acids when they eat dead cells, and then use an enzyme to convert arginine to putrescine. The putrescine, in return, activates a protein (Rac1) that causes the macrophage to eat more dead cells, suggesting to the authors that the problem of atherosclerosis may be, in part, a problem of putrescine. The findings, according to the accompanying press release, suggest that the compound could be use to potentially treat conditions with chronic inflammation, such as Alzheimers disease.

The Nose Knows: Pungent Compound Associated with Improvements in Atherosclerotic Plaque

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Cardio Round-up: Nanoparticles and Stem Cells in the Spotlight - DocWire News

Cardiac Stem Cells Comments Off on Cardio Round-up: Nanoparticles and Stem Cells in the Spotlight – DocWire News | January 31st, 2020

Three-dimensional printers have now assembled candy, clothing, and even mouse ovaries. But in the next decade, specialized bioprinters could begin to build functioning human organs in space. It turns out, the minimal gravity conditions in space may provide a more ideal environment for building organs than gravity-heavy Earth.

If successful, space-printed organs could help to shorten transplant waitlists and even eliminate organ rejection. Though they still have a long way to go, researchers at the International Space Station (ISS) hope to eventually assemble organs from adult human cells, including stem cells.

The medical field has only recently embraced 3D printing in general, particularly in biomedical fields like regenerative medicine and prosthetics. So far, these printers have produced early versions of blood vessels, bones, and different types of living tissue by churning out repeated layers of bioinka substance comprised of living human cells and other tissue thats meant to mimic the natural environment that surrounds growing organs.

Recently, researchers are finding that Earth might not be the best environment for growing freestanding organs. Because gravity is constantly pushing down on these delicate structures as they grow, researchers must surround the tissues in scaffolding, which can often debilitate the delicate veins and blood vessels and prevent the soon-to-be organs from growing and functioning properly. Within microgravity, however, soft tissues hold their shape naturally, without the need for surrounding supportan observation thats driven researchers to space.

And one manufacturing lab based in Indiana thinks its tech could play a key role in space. The 3D BioFabrication Facility (BFF) is a specialized 3D printer that uses bioink to build layers several times thinner than human hair. It cost about $7 million to build and employs the smallest print tips in existence.

The brainchild of spaceflight equipment developer Techshot and 3D printer manufacturer nScrypt, the BFF headed to the ISS in July 2019 aboard the SpaceX CRS-18.

Currently, the project focuses on building increasingly thick artificial cardiac tissue and delivering it back to Earth. Once the printed cardiac tissue reaches a certain thickness, it gets harder for researchers to ensure that a printed structures layers effectively grow into one another. Ultimately, though, theyd like the organs to arrive here fully formed.

Printed organs would eventually require vasculature and nerve endings to work properly, though that technology doesnt yet exist.

The next stagetesting heart patches under microscopes and within animalscould span over the next four years. As for whole organs, Techshot claims it plans to begin production after 2025. For now, the project is still in its infancy.

If you were to look at what we printed, it looks very modest, says Techshot vice president of corporate advancement Rich Boling. Its just a cuboid-type shape, this rectangular box. Were just trying to get cells to grow one layer into the next.

Cooking organs like pancakes

Compare the manufacturing process to cooking pancakes, Boling says. The space crew first creates a custom bioink pancake mix with the cells sent from Earth, which they load with syringe-like tools into the BFF.

Researchers then insert a cassette into the BFF containing a bioreactora system that mimics the normal bodily functions essential for growing healthy tissue, like providing nutrients and flushing out waste.

Approximately 200 miles below in Greenville, Indiana, Techshot engineers connect with ISS astronauts on a NASA-enabled secure digital pathway. The linkup allows Techshot to remotely command BFF functions like pump pressure, internal temperature, lighting, and print speed.

Next, the actual printing process occurs within the bioreactor and can take anywhere from moments to hours, depending on the shapes complexity. In the final production step, the cell-culturing ADvanced Space Experiment Processor (ADSEP) cooks the theoretical pancake; essentially, the ADSEP toughens up the printed tissue for its journey back to earth. This step could take anywhere from 12 to 45 days for different tissue types. When completed and hardened, the structure heads home.

The researchers have gone through three testing processes so far, each one getting more exact. This March, theyll begin the third round of experiments.

The bioprinter space race

The BFF lab is the sole team developing this specific type of microgravity bioprinter, Boling says. Theyre not the only ones looking to print human organs in space, though.

A Russian project has also entered the bioprinting space race, however their technique highly differs. Unlike the BFFs bioink layering method, Russian biotechnology laboratory 3D Bioprinting Solutions uses magnetic nanoparticles to produce tissue. An electromagnet creates a magnetic field in which levitating tissue forms the desired structuretechnology that appears ripped from the pages of a sci-fi novel.

After their bioprinter fell victim to an October 2018 spacecraft crash, 3D Bioprinting Solutions rebounded; the team now collaborates with US and Israeli researchers at the ISS. Last month, their crew created the first space-bioprinted bone tissue. Similar to the US project, 3D Bioprinting Solutions aims to manufacture functioning human tissues and organs for transplantation and general repair.

Just because we have the technology to do it, should we do it?

If the 3D BioFabrication Facility prospers in printing working human organs, theyd be subject to thorough regulation here on Earth. The US approval process is stringent for any drug, Rich Boling says, posing a challenge for this unprecedented invention. Techshot predicts at least 10 years for space-printed organs to achieve legal approval, though its an inexact estimate.

Along with regulatory acceptance, human tissue printed in microgravity may encounter societal pushback.

Each country maintains varying laws related to medical transplants. Yet as bioengineering advances into the the final frontier, the international scientific research community may need to shape new guidelines for collaboration among the stars.

As the commercialization of low-Earth orbit continues to ramp up in the next few years, it is certainly true that were going to have to take a very close look at the regulations that apply to that, says International Space Station U.S. National Laboratory interim chief scientist Michael Roberts. And some of those regulations are going to stray into questions related to ethics: Just because we have the technology to do it, should we do it?

Niki Vermeulen, a University of Edinburgh science technology and innovation studies lecturer, has researched the social implications of 3D bioprinting experiments. Like any Earth-bound project, she urges scientists not to get peoples hopes up too early in the process; individuals seeking organ transplants could read about the BFF online and think it could soon be ready to meet their needs.

The most important thing now, I think, is expectation management, Vermeulen says. Because its really quite difficult to do this, and of course we really dont know if its going to work. If it did, it would be amazing.

Another main issue is cost. Like other cutting-edge biotechnology innovations, the organs could also pose a major affordability challenge, she says. Techshot claims that a single space-printed organ could actually cost less than one from a human donor, since some people must pay for a lifetime of anti-rejection meds and/or multiple transplants. Theres currently no telling how long the BFF process would actually take, however, compared to the conventional donor route.

Plus, theres potential health risks for recipients: Techshot chief scientist Eugene Boland says cell manipulation always presents a possibility of genetic mutation. Modified stem cells can potentially cause cancer in recipients, for example.

The team is now working to define and minimize any dangers, he says. The BFF experiment adheres to the FDAs specific regulations for human cells, tissues, and cellular and tissue-based products.

Researchers on the ground now hope to perfect human cell manipulation: Over 100 US clinical trials presently test cultured autologous human cells, and several hundred test cultured stem cells with multiple origins.

What comes next

After the next round of printing tests this March, Techshot will share the bioprinter with companies and research institutions looking to print materials like cartilage, bone, and liver tissue. Theyre currently preparing the bioprinter for these additional uses, Boling says, which could advance health care as a whole.

To speed things up for space crews, Techshot is now building a cell factory that produces multiple cell types in orbit. This technology could cut down the number of cell deliveries between Earth and space.

The ISS has taken in plenty of commercial ventures in recent years, Michael Roberts says, and its getting crowded up there. Space-based experiments ramped up between 40 and 50 years ago, though until recently they mostly prioritized satellite communications and remote observation technology. Since then, satellites have shrunk from bus-sized to smaller than a shoebox.

Roberts has witnessed the scientific areas of interest broaden over the past decade to include medicine. Organizations like the National Institutes of Health are now looking to space to improve treatments, and everything from large pharmaceutical companies to small-scale startups want in.

Theyve got something stuck on every surface up there, he says.

As the ISS runs out of space and exterior attachment points, Roberts predicts that commercial ventures will build new facilities built for specific activities like manufacturing and plant growth. He sees it as a good opportunity for further innovation, since the ISS was originally designed for far more general purposes.

Space, as a whole, may start to look quite different from the first exploration age.

Baby boomers may remember glimpsing at a grainy, black-and-white moon landing five decades ago. Within the same lifetime, they could potentially observe the introduction of space-printed organs.

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Space might be the perfect place to grow human organs - Popular Science

Cardiac Stem Cells Comments Off on Space might be the perfect place to grow human organs – Popular Science | January 31st, 2020

A team of researchers at Osaka University in Japan successfully transplanted cardiac muscle cells created from iPS into a patient, who is now recovering in the general ward of the hospital.

The team, led by Yoshiki Sawa, a professor in the university's cardiovascular surgery unit, created the cardiac muscle cells from iPS cells in a clinical trial to verify the safety and efficacy of this type of procedure. The researches want to transplant heart muscle cells into ten patients who have serious heart malfunctions because of ischemic cardiomyopathy over a three year period.

RELATED: RESEARCHERS ORGANIZE STEM CELLS BASED ON A COMPUTATIONAL MODEL

Instead of replacing the heart of patients, the researchers developed degradable sheets of heart muscle cells that were placed on the damaged areas of the heart.

To grow the heart muscle cells in the lab, the researchers turned to induced pluripotent stem cells otherwise known as iPS. Researchers are able to take those iPS cells and make them into any cell they want. In this case, it was heart muscle cells.If the clinical trials prove successful it could remove someday the need for heart transplants.

I hope that (the transplant) will become a medical technology that will save as many people as possible, as Ive seen many lives that I couldnt save, Sawa was quoted at a news conference reported the Japan Times.

As for the patient, the team plans to monitor him during the next year to ascertain how the heart muscle cells perform. According to the Japan Times, the researchers opted to conduct a clinical trial instead of a clinical study because they want approval from Japan's health ministry for clinical application as soon as possible.

The report noted that during the trial the researchers will look at risks, probabilities of cancer and the efficacy of transplanting 100 million cells for each patient that could include tumor cells.

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Heart Muscle Cells Made in the Lab Successfully Transplanted into Patient - Interesting Engineering

Cardiac Stem Cells Comments Off on Heart Muscle Cells Made in the Lab Successfully Transplanted into Patient – Interesting Engineering | January 30th, 2020

Biomedical researchers from Texas Tech University Health Sciences Center El Paso and the University of Texas at El Paso are working on a joint project to send miniature 3D bioprinted hearts to space. The research project, which has received backing from the National Science Foundation (NSF), seeks to understand how a microgravity environment affects the function of the human heart.

Bioprinting in space is a growing venture. The microgravity environment found aboard the International Space Station (ISS) provides a unique setting for bioprinted tissues and cellular structures to culture and grow. Bioprinting specialists like CELLINK and 3D Bioprinting Solutions are showcasing the potential of bioprinting in space, both for the advancement of bioprinting technologies and to understand the impact of zero-gravity on the human body.

The three-year research project conducted by the Texas-based research team falls into the latter category. The team, led by Munmun Chattopadhyay, Ph.D., TTUHSC El Paso faculty scientist, and Binata Joddar, Ph.D., UTEP biomedical engineer, wants to understand how the human heart is impacted by microgravity by testing bioprinted cardiac organoids aboard the ISS.

The cardiac organoids consist of heart-tissue structures measuring less than 1 mm in thickness which are bioprinted using human stem cells. The organoids will be sent to the ISS, where they will exposed to microgravity environments. This will provide vital insights into a condition commonly experienced by astronauts.

The condition in question is cardiac atrophy and it is caused by a weakening of heart tissue. The condition can lead to other problems, like fainting, irregular heartbeats and even heart failure. Because astronauts often suffer from cardiac atrophy after spending long stints in space, the researchers want to better understand the link.

Cardiac atrophy and a related condition, cardiac fibrosis, is a very big problem in our community, said Dr. Chattopadhyay. People suffering from diseases such as diabetes, muscular dystrophy and cancer, and conditions such as sepsis and congestive heart failure, often experience cardiac dysfunction and tissue damage.

The project, which officially started in September, is currently focused on research design. In this stage of the research, the team is developing bioprinted cardiac organoids and exploring different material compositions using cardiac cells to create heart-like tissue. The second stage of the research will be focused on preparing to launch to organoid to space. The final stage will consist of analyzing data collected during the organoids time in space, once they have returned to Earth.

Dr. Chattopadhyay expressed excitement about the ongoing research project, saying: Knowledge gathered from this study could be used to develop technologies and therapeutic strategies to better combat tissue atrophy experienced by astronauts, as well as open the doorforimproved treatmentsforpeople who suffer from serious heart issues due to illness.

The researchers also hope to engage the community with their research by offering a workshop for K-12 students about their experiments aboard the ISS. The team will also host a seminar for medical students, interns and residents about conducting research in space and on Earth.

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El Paso researchers sending bioprinted mini hearts to ISS - 3DPMN

Cardiac Stem Cells Comments Off on El Paso researchers sending bioprinted mini hearts to ISS – 3DPMN | January 30th, 2020

Two high-tech companies have teamed up to take 3D printing in space to the next level. A new 3D printer, sent to the space station on a SpaceX cargo resupply mission last July, is now officially open for business. Its goal: to print human tissue in space.

Formally known as the 3D BioFabrication Facility (or BFF), the printer will use adult human cells (like stem cells) as its feedstock. The BFF is just the first step to a much larger goal of printing human organs such as hearts or lungs in space.

The initial phase for BFF, which could last about two years, will involve creating test prints of cardiac-like tissue of increasing thickness, Techshot representatives said in a statement. (Techshot is collaborating on the project with nScrypt, a 3D bioprinter and electronic printer manufacturer.)

If all goes according to plan, the company would then graduate to printing heart patches in space. Once printed, they would be shipped back to Earth and tested in small animals (such as rats) to see how they do. The next step after that could be entire organs.

Ultimately, long-term success of BFF could lead to reducing the current shortage of donor organs and eliminate the requirement that someone must first die in order for another person to receive a new heart, other organ or tissue, Techshot said.

Imagine needing a organ and instead of having to wait on the transplant list for an one that could never come, using a bit of your own DNA, a new organ could be printed for you in space.

Researchers on Earth have celebrated some success with the 3D printing of bones and cartilage, but when it comes to soft tissues, they havent had the same luck.

Tissues collapse under their own weight due to gravity. This results in not much more than a puddle of biomaterial. But when these sames components are used in space, they retain their shape.

However, without additional conditioning, once these new tissues return to Earth, theyd collapse just like there terrestrial counterparts. Heres where BFF comes in.

In addition to launching a bioprinter, Techshot has also developed a means of curing the newly printed tissues. This way they will remain solid even after returning to Earth. The company says that the actual printing process will take less than a day, the strengthening process will take an estimated 12-45 days. It all depends on the tissue.

This could lead to less people dying as they wait on transplant lists, and it could also mean less dependency on anti-rejection medications. Assembling a whole human organ (such as a heart or lung) was once strictly science fiction. While its still a few years away, it is now a possibility.

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3D printed organs are coming to an International Space Station near you - Teslarati

Cardiac Stem Cells Comments Off on 3D printed organs are coming to an International Space Station near you – Teslarati | January 30th, 2020

In what is a world-first and potentially the dawn of a new medical technology to treat damaged hearts, scientists in Japan have succeeded in transplanting lab-grown heart cells into a human patient for the first time ever. The procedure is part of a cutting-edge clinical trial hoped to open up new avenues in regenerative medicine, with the treatment to be given to a further nine patients over the coming years.

The clinical trial harnesses the incredible potential of induced pluripotent stem cells (IPSCs), a Nobel Prize-winning technology developed at Kyoto University in 2006. These are created by first harvesting cells from donor tissues and returning them to their immature state by exposing them to a virus. From there, they can develop into essentially any cell type in the body.

Professor Yoshiki Sawa is a cardiac surgeon at Osaka University in Japan, who has been developing a technique to turn IPSCs into sheets of 100 million heart muscle cells, which can be grafted onto the heart to promote regeneration of damaged muscles. This was first tested on pigs and was shown to improve organ function, which led Japans health ministry to conditionally approve a research plan involving human subjects.

The first transplantation of these cells is a huge milestone for the researchers, with the operation taking place earlier this month and the patient now recovering in the general ward of the hospital. The sheets are biodegradable, and once implanted on the surface of the heart are designed to release growth factors that encourage new formation of healthy vessels and boost cardiac function.

The team will continue to monitor the first patient over the coming year, and over the next three years aims to carry out the procedure on a total of 10 patients suffering from ischemic cardiomyopathy, a condition caused by a heart attack or coronary disease that has left the muscles severely weakened.

I hope that [the transplant] will become a medical technology that will save as many people as possible, as Ive seen many lives that I couldnt save, Sawa said at a news conference on Tuesday, according to The Japan Times.

Source: The Japan Times

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Lab-grown heart cells implanted into human patient for the first time - New Atlas

Cardiac Stem Cells Comments Off on Lab-grown heart cells implanted into human patient for the first time – New Atlas | January 30th, 2020

Stem Cell Therapy Market: Snapshot

Of late, there has been an increasing awareness regarding the therapeutic potential of stem cells for management of diseases which is boosting the growth of the stem cell therapy market. The development of advanced genome based cell analysis techniques, identification of new stem cell lines, increasing investments in research and development as well as infrastructure development for the processing and banking of stem cell are encouraging the growth of the global stem cell therapy market.

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One of the key factors boosting the growth of this market is the limitations of traditional organ transplantation such as the risk of infection, rejection, and immunosuppression risk. Another drawback of conventional organ transplantation is that doctors have to depend on organ donors completely. All these issues can be eliminated, by the application of stem cell therapy. Another factor which is helping the growth in this market is the growing pipeline and development of drugs for emerging applications. Increased research studies aiming to widen the scope of stem cell will also fuel the growth of the market. Scientists are constantly engaged in trying to find out novel methods for creating human stem cells in response to the growing demand for stem cell production to be used for disease management.

It is estimated that the dermatology application will contribute significantly the growth of the global stem cell therapy market. This is because stem cell therapy can help decrease the after effects of general treatments for burns such as infections, scars, and adhesion. The increasing number of patients suffering from diabetes and growing cases of trauma surgery will fuel the adoption of stem cell therapy in the dermatology segment.

Global Stem Cell Therapy Market: Overview

Also called regenerative medicine, stem cell therapy encourages the reparative response of damaged, diseased, or dysfunctional tissue via the use of stem cells and their derivatives. Replacing the practice of organ transplantations, stem cell therapies have eliminated the dependence on availability of donors. Bone marrow transplant is perhaps the most commonly employed stem cell therapy.

Osteoarthritis, cerebral palsy, heart failure, multiple sclerosis and even hearing loss could be treated using stem cell therapies. Doctors have successfully performed stem cell transplants that significantly aid patients fight cancers such as leukemia and other blood-related diseases.

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Global Stem Cell Therapy Market: Key Trends

The key factors influencing the growth of the global stem cell therapy market are increasing funds in the development of new stem lines, the advent of advanced genomic procedures used in stem cell analysis, and greater emphasis on human embryonic stem cells. As the traditional organ transplantations are associated with limitations such as infection, rejection, and immunosuppression along with high reliance on organ donors, the demand for stem cell therapy is likely to soar. The growing deployment of stem cells in the treatment of wounds and damaged skin, scarring, and grafts is another prominent catalyst of the market.

On the contrary, inadequate infrastructural facilities coupled with ethical issues related to embryonic stem cells might impede the growth of the market. However, the ongoing research for the manipulation of stem cells from cord blood cells, bone marrow, and skin for the treatment of ailments including cardiovascular and diabetes will open up new doors for the advancement of the market.

Global Stem Cell Therapy Market: Market Potential

A number of new studies, research projects, and development of novel therapies have come forth in the global market for stem cell therapy. Several of these treatments are in the pipeline, while many others have received approvals by regulatory bodies.

In March 2017, Belgian biotech company TiGenix announced that its cardiac stem cell therapy, AlloCSC-01 has successfully reached its phase I/II with positive results. Subsequently, it has been approved by the U.S. FDA. If this therapy is well- received by the market, nearly 1.9 million AMI patients could be treated through this stem cell therapy.

Another significant development is the granting of a patent to Israel-based Kadimastem Ltd. for its novel stem-cell based technology to be used in the treatment of multiple sclerosis (MS) and other similar conditions of the nervous system. The companys technology used for producing supporting cells in the central nervous system, taken from human stem cells such as myelin-producing cells is also covered in the patent.

Global Stem Cell Therapy Market: Regional Outlook

The global market for stem cell therapy can be segmented into Asia Pacific, North America, Latin America, Europe, and the Middle East and Africa. North America emerged as the leading regional market, triggered by the rising incidence of chronic health conditions and government support. Europe also displays significant growth potential, as the benefits of this therapy are increasingly acknowledged.

Asia Pacific is slated for maximum growth, thanks to the massive patient pool, bulk of investments in stem cell therapy projects, and the increasing recognition of growth opportunities in countries such as China, Japan, and India by the leading market players.

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Global Stem Cell Therapy Market: Competitive Analysis

Several firms are adopting strategies such as mergers and acquisitions, collaborations, and partnerships, apart from product development with a view to attain a strong foothold in the global market for stem cell therapy.

Some of the major companies operating in the global market for stem cell therapy are RTI Surgical, Inc., MEDIPOST Co., Ltd., Osiris Therapeutics, Inc., NuVasive, Inc., Pharmicell Co., Ltd., Anterogen Co., Ltd., JCR Pharmaceuticals Co., Ltd., and Holostem Terapie Avanzate S.r.l.

About TMR Research:

TMR Research is a premier provider of customized market research and consulting services to business entities keen on succeeding in todays supercharged economic climate. Armed with an experienced, dedicated, and dynamic team of analysts, we are redefining the way our clients conduct business by providing them with authoritative and trusted research studies in tune with the latest methodologies and market trends.

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Stem Cell Therapy Market Predicted to Accelerate the Growth by 2017-2025 - Jewish Life News

Cardiac Stem Cells Comments Off on Stem Cell Therapy Market Predicted to Accelerate the Growth by 2017-2025 – Jewish Life News | January 30th, 2020

FRESNO, California (KSEE/KGPE) After getting a breast cancer diagnosis, your heart health may be the last thing on your mind. But, if the cancer is in your left breast right over your heart treatment is more difficult. The medical director and the manager of radiation oncology at Community Cancer Institute explain a new and improved technique of radiation therapy that keeps your heart safer during treatment.

Radiation therapy is one of the most common treatments for cancer. It works by damaging genetic material within cancer cellscausing them to die. However, normal cells can also be affected by the radiation.

Alec Beach, the Manager of Radiation Oncology for Community Cancer Institute says, So Surface Guided Radiation Therapy is a new modality relatively new and new to us in the Valley, to help align patients even better and also to provide some techniquesimprovements in accuracy, alignment and also in the breathing cycle of the patient to deliver radiation therapy at the optimal time.

Surface Guided Radiation Therapy or SGRT has been particularly successful in treating breast cancer patients with cancer in the left breast.

Dr. William Silveira the Medical Director of the Department of Radiation Oncology at Community Cancer Institute says, The problem with left sided breast cancer is that the heart is very close to the breast tissue. If we can get the heart out of the way, that helps tremendously. When we monitor the surface of the patient, we can have the patient take a very deep breath, pulling the heart down and out of the way, and therefore we can treat the patient while the heart is essentially completely out of the way, out of the beams, out of harms way.

Its all about timing and the careful placement of SGRT that will minimize the dosage of radiation to the normal tissues while delivering the maximum amount to the cancerous cells.

Theres a significant reduction in the dose received by the heart with this technology. Many of our patients are now surviving, and down the road we dont want them to experience cardiac disease. Radiation therapy for left sided breast cancer can contribute to cardiac disease. So, although it has a tremendous impact on survival and local control for breast cancer, we also have this potential complication down the road. Minimizing the dose to the heart, really saves patients a lot of trouble, said Dr. Silveira.

The possible cardiac risks of radiation therapy are significantly reduced with SGRT treatment.

I think theres a lot of fear regarding radiation therapy and a lot of it has to do with heart disease. I, myself, do worry about heart disease from radiation therapy quite a bit. This technology allows us to reduce the risk of heart disease significantly by essentially taking the heart almost out of the picture. The risk to the heart would be minimalmuch less than 5 percent, Dr. Silveira said.

SGRT helps to keep the heart safe, but can also be used throughout the body.

So SGRT can be used in multiple anatomical sites head and neck treatment in particular. Obviously, were treating the head or neck, the brain or the brain stem areatheres a lot of critical structures in that area and the alignment in that area is crucial so the mm accuracy is crucial so thats a particularly good area that well be implementing this in. But, it can also be used throughout the body, the abdomen, the pelvis for GYN cancer, for example, prostate treatment, basically anything where the surface can be used to align the treatment, said Beach.

Community Cancer Institute is the only one in the Valley using this advanced technology and Beach says the program strives to be second to none.

I would hope that the patients would take away that were here to do the very best that we can for themyes, its technology, but its not just technology for technologys sake, its with an outcome in mind and I want patients to know that we might take a little extra time to treat you, but I think thats worth it, Beach said.

And Dr. Silveira says it takes a collective effort, It takes a lot to implement, however and we have a great team. Our physicist, dosimetrist and therapist all are really fantastic in putting this program together. So its technology plus people.

To learn more about how community medical centers can help you or a loved one in prevention and treatment, visit http://www.CommunityMedical.org/Cancer.

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MedWatch Today: Surface Guided Radiation Therapy Protects the Heart During Treatment - YourCentralValley.com

Cardiac Stem Cells Comments Off on MedWatch Today: Surface Guided Radiation Therapy Protects the Heart During Treatment – YourCentralValley.com | January 30th, 2020

National Research (NASDAQ:NRC) and US Stem Cell (OTCMKTS:USRM) are both small-cap business services companies, but which is the better investment? We will contrast the two businesses based on the strength of their profitability, risk, earnings, valuation, analyst recommendations, dividends and institutional ownership.

Risk & Volatility

National Research has a beta of 0.78, indicating that its stock price is 22% less volatile than the S&P 500. Comparatively, US Stem Cell has a beta of 4.87, indicating that its stock price is 387% more volatile than the S&P 500.

Insider and Institutional Ownership

39.7% of National Research shares are held by institutional investors. 4.5% of National Research shares are held by company insiders. Comparatively, 16.7% of US Stem Cell shares are held by company insiders. Strong institutional ownership is an indication that hedge funds, endowments and large money managers believe a stock is poised for long-term growth.

Valuation & Earnings

This table compares National Research and US Stem Cells top-line revenue, earnings per share (EPS) and valuation.

National Research has higher revenue and earnings than US Stem Cell.

Profitability

This table compares National Research and US Stem Cells net margins, return on equity and return on assets.

Analyst Recommendations

This is a summary of current recommendations and price targets for National Research and US Stem Cell, as provided by MarketBeat.com.

Summary

National Research beats US Stem Cell on 7 of the 9 factors compared between the two stocks.

About National Research

National Research Corporation (NRC) is a provider of analytics and insights that facilitate revenue growth, patient, employee and customer retention and patient engagement for healthcare providers, payers and other healthcare organizations. The Companys portfolio of subscription-based solutions provides information and analysis to healthcare organizations and payers across a range of mission-critical, constituent-related elements, including patient experience and satisfaction, community population health risks, workforce engagement, community perceptions, and physician engagement. The Companys clients range from acute care hospitals and post-acute providers, such as home health, long term care and hospice, to numerous payer organizations. The Company derives its revenue from its annually renewable services, which include performance measurement and improvement services, healthcare analytics and governance education services.

About US Stem Cell

U.S. Stem Cell, Inc., a biotechnology company, focuses on the discovery, development, and commercialization of autologous cellular therapies for the treatment of chronic and acute heart damage, and vascular and autoimmune diseases in the United States and internationally. Its lead product candidates include MyoCell, a clinical therapy designed to populate regions of scar tissue within a patient's heart with autologous muscle cells or cells from a patient's body for enhancing cardiac function in chronic heart failure patients; and AdipoCell, a patient-derived cell therapy for the treatment of acute myocardial infarction, chronic heart ischemia, and lower limb ischemia. The company's product development pipeline includes MyoCell SDF-1, an autologous muscle-derived cellular therapy for improving cardiac function in chronic heart failure patients. It is also developing MyoCath, a deflecting tip needle injection catheter that is used to inject cells into cardiac tissue in therapeutic procedures to treat chronic heart ischemia and congestive heart failure. In addition, the company provides physician and patient based regenerative medicine/cell therapy training, cell collection, and cell storage services; and cell collection and treatment kits for humans and animals, as well operates a cell therapy clinic. The company was formerly known as Bioheart, Inc. and changed its name to U.S. Stem Cell, Inc. in October 2015. U.S. Stem Cell, Inc. was founded in 1999 and is headquartered in Sunrise, Florida.

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Contrasting US Stem Cell (OTCMKTS:USRM) and National Research (OTCMKTS:NRC) - Riverton Roll

Cardiac Stem Cells Comments Off on Contrasting US Stem Cell (OTCMKTS:USRM) and National Research (OTCMKTS:NRC) – Riverton Roll | January 30th, 2020