On Feb. 2, Naomi Ng 16 donated peripheral blood stem cells at an outpatient clinic as part of the Be The Match donor program. She was matched after registering for Be The Match through the Andy Talley Bone Marrow Foundation.

You swab your cheek and you might save someones life, Ng said. Its so easy to register to be a donor that you dont think about the impact.

Ng was informed of the potential match in the fall of 2016 and completed initial blood work. Having graduated in May with a degree in Environmental Studies, she had just begun working for Amtrak in D.C. as senior service planner. She was not contacted again until mid-December, and completed the non-surgical procedure several weeks later.

The Andy Talley Bone Marrow Foundation, a non-profit created in 2010 by the recently retired head football coach. Talley began promoting awareness about bone marrow donation in 1992 by hosting testing opportunities on campus. In 2008, he partnered with Be The Match to form the Get in the Game. Save a Life initiative. The foundation has now enlisted over 78 college football programs to participate in the foundations mission, registering young, healthy college students with the Be the Match registry to increase the chances of finding a bone marrow match for patients diagnosed with blood cancer.

Like many University students Ng registered at one of Talleys on campus testing drives. She swabbed her cheek, filled out the paperwork and doubted that she would ever get a call. I kind of forget that I had registered for it, Ng said. I had hoped obviously, because I wouldnt have registered if I didnt want to do it. Its just such a slim chance.

The donation of peripheral blood stem cells is one of two methods for collecting the blood-forming cells that recipients need. For five days before the procedure, Ng was given injections of filgrastim to increase the number of stem cells in her blood. On the day of the procedure she was connected to a machine via a needle in one arm and her blood was run through the machine and returned to her body through the other arm.

Although the filgrastim injections were painful, Ng described the procedure as pretty non-invasive, saying, I actually slept through the procedure. When I woke up I was like, thats it? I can leave now?

Ngs match is a 66-year old man, but his age and gender are the only things she knows about him. A year after the procedure, Be The Match will help to facilitate contact between the two if desired by donor and recipient.

Its a really emotional experience, Ng said. Ive never met this guy. I dont know his name. I dont know anything about him, but I feel like I have an emotional connection to him now. I dont know yet, but I might have saved his life.

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Senior Becomes the Match to donate bone marrow and saves life - Villanovan (subscription)

Bone Marrow Stem Cells Comments Off on Senior Becomes the Match to donate bone marrow and saves life – Villanovan (subscription) | February 15th, 2017

When three Southern Arkansas University nursing students started organizing this weeks stem cell registry drive more than three months ago, they were not aware that a member of the Mulerider family is one of more than 1,400 whose life could be saved.

The stem cell/bone marrow registry drive is scheduled for 9 a.m.-3:30 p.m. on Tuesday and Wednesday both in the Reynolds Center Rotunda and the SAU Baptist Collegiate Ministry.

For more information, contact Dr. Becky Parnell at (870)235-4365 or at bbparnell@saumag.edu .

The SAU BSN students initially behind the project are Renee Langley, Tabitha Elliott and Courtney Owens. Parnell explained that while attending the Arkansas Student Nurses Association annual meeting in Little Rock, the students were introduced to the need for bone marrow donors. They even registered to be possible donors themselves.

Parnell said they realized this project was a perfect example of how nurses can impact the care of people outside the normal hospitalized patient.

They recognized how many people this could potentially impact and wanted to recruit more people (to register), said Parnell. I have seen the bone marrow process it is truly a life-saving intervention for many people that are devastated by leukemia.

When Parnell began promoting the registry event on campus, it was brought to her attention that Sydney Galway, the daughter of a Magnolia native, 1984 SAU alum and Board of Governors Chair Beth Galway, is suffering with acute myeloid leukemia.

Sydney Galway is in dire need of a bone marrow transplant.

When Sydney was diagnosed with acute myeloid leukemia, the doctors told us that Sydneys only cure would come from a bone marrow transplant. The doctors were, and are, confident of the success of her treatment due to the fact that she has a high chance to find a perfect bone marrow donor, said Galway.

Her increased chance of finding a match, Galway explained, is simply because she is a Caucasian female which has one of the highest bone marrow donor rates. She has a 97 percent chance to find a donor.

Of course, the first donor they looked at was her sister. A sibling has only a 25 percent chance to be a match; a parent even less. Sydneys sister was not a match, said Galway.

Donor matches are generally based on race. With todays diverse community, the need for bone marrow donors from minority and mixed race groups is high. An African American patient has only a 66 percent chance to find a match.

The doctors and nurses that I have talked to indicate that the need is huge for African Americans as well as donors from India, said Galway.

She said that the treatment for Sydney, who is a sophomore in college, is now in phase 3. Her next step is a bone marrow transplant.

We hope to have a perfect match for her and pray that the donor will be willing to do all that is necessary for providing the blood or bone marrow needed for the transplant, said Galway.

The drive is being sponsored by SAUs Department of Nursing and University Health Services. Junior and senior BSN students will also be assisting in the bone marrow drive as a professional development activity.

Becoming a member of a stem cell/bone marrow registry only requires that you provide a swab of the cells inside your cheek. To register is a painless and fast way to possibly save a life.

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Stem cell registry drive at SAU seeks to connect potential donors with people who need help - Magnoliareporter

Bone Marrow Stem Cells Comments Off on Stem cell registry drive at SAU seeks to connect potential donors with people who need help – Magnoliareporter | February 14th, 2017

This post was originally published on this site New Facility at Sunnybrook Part of Plan to Expand Care for People with Blood Diseases

Ontario is investing in a new facility at Sunnybrook Health Sciences Centre that will offer specialized treatment for people with blood cancers such as leukemia.

Premier Kathleen Wynne was at Sunnybrook in Toronto Tuesday to announce the governments support for a new Complex Malignant Haematology (CMH) site. Sunnybrook will become the second hospital in the Greater Toronto Area along with Princess Margaret Cancer Care to provide a full range of potentially life-saving CMH services, including stem cell transplants.

Ontario is also improving treatment for people with blood diseases by:

Investing to improve care for people with blood cancers and disorders is part of our plan to build a better Ontario by providing patients with faster access to the right health care.

Kathleen Wynne: Premier of Ontario

Stem cell transplants can help lessen the terrible toll that cancer takes on families. We are providing support so hospitals can offer more patients access to a life-saving treatment and the chance for a new lease on life.

Dr. Eric Hoskins: Minister of Health and Long-Term Care

Today marks a major milestone for Ontario patients needing stem cell transplants. With this investment, patients will have better access to timely service and state-of-the-art treatment, but most importantly, more patients will be able to receive stem cell transplants right here in Ontario.

Dr. Barry McLellan: President and CEO, Sunnybrook Health Sciences Centre

This is a life-saving investment. We are grateful to the Ontario government for the funding to provide care and build a new state-of-the-art facility for patients who are afflicted with this serious illness.

Michael Sherar: President and CEO, Cancer Care Ontario; Co-convener, Complex Malignant Hematology Hematopoietic Cell Therapy Consultation Group

Sunnybrook Health Sciences Centre is an important and valued partner in Ontarios cancer care system. The addition of a new Complex Malignant Haematology site is a critical step in our efforts to ensure that patients receive timely access to transplant services in Ontario.

Source Government of Ontario press release

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More people to get access to life-saving stem cell transplants - Erie Media

Bone Marrow Stem Cells Comments Off on More people to get access to life-saving stem cell transplants – Erie Media | February 9th, 2017

The 2017 Australian of the Year award went to Professor Alan Mackay-Sim for his significant career in stem cell science.

The prize was linked to barbeque-stopping headlines equating his achievements to the scientific equivalent of the moon landing and paving the road to recovery for people with spinal cord injuries.

Such claims in the media imply that there is now a scientifically proven stem cell treatment for spinal cord injury. This is not the case.

For now, any clinic or headline claiming miracle cures should be viewed with caution, as they are likely to be trading on peoples hope.

Why stem cells for spinal cord injury?

Put simply, injury to the spinal cord causes damage to the nerve cells that transmit information between the brain and the rest of the body.

Depending on which part of the spine is involved, the injury can affect the nerves that control the muscles in our legs and arms; those that control bowel and bladder function and how we regulate body temperature and blood pressure; and those that carry the sensation of being touched. This occurs in part because injury and subsequent scarring affect not just the nerves but also the insulation that surrounds and protects them. The insulation the myelin sheath is damaged and the body cannot usually completely replace or regenerate this covering.

Stem cells can self-reproduce and grow into hundreds of different cell types, including nerves and the cells that make myelin. So the blue-sky vision is that stem cells could restore some nerve function by replacing missing or faulty cells, or prevent further damage caused by scarring.

Studies in animals have applied stem cells derived from sources including brain tissue, the lining of the nasal cavity, tooth pulp, and embryos (known as embryonic stem cells).

Dramatic improvements have been shown on some occasions, such as rats and mice regaining bladder control or the ability to walk after injury. While striking, such improvement often represents only a partial recovery. It holds significant promise, but is not direct evidence that such an approach will work in people, particularly those with more complex injuries.

What is happening now in clinical trials?

The translation of findings from basic laboratory stem cell research to effective and safe treatments in the clinic involves many steps and challenges. It needs a firm scientific basis from animal studies and then careful evaluation in humans.

Many clinical studies examining stem cells for spinal repair are currently underway. The approaches fit broadly into two categories:

using stem cells as a source of cells to replace those damaged as a result of injury

applying cells to act on the bodys own cells to accelerate repair or prevent further damage.

One study that has attracted significant interest involves the injection of myelin-producing cells made from human embryonic stem cells. Researchers hoped that these cells, once injected into the spinal cord, would mature and form a new coating on the nerve cells, restoring the ability of signals to cross the spinal cord injury site. Preliminary results seem to show that the cells are safe; studies are ongoing.

Other clinical trials use cells from patients own bone marrow or adipose tissue (fat), or from donated cord blood or nerves from fetal tissue. The scientific rationale is based on the possibility that when transplanted into the injured spinal cord, these cells may provide surrounding tissue with protective factors which help to re-establish some of the connections important for the network of nerves that carry information around the body.

The field as it stands combines years of research, and tens of millions of dollars of investment. However, the development of stem cell therapies for spinal cord injury remains a long way from translating laboratory promise into proven and effective bedside treatments.

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Yes There's Hope, But Treating Spinal Injuries With Stem Cells Is Not A Reality Yet - IFLScience

Bone Marrow Stem Cells Comments Off on Yes There’s Hope, But Treating Spinal Injuries With Stem Cells Is Not A Reality Yet – IFLScience | February 9th, 2017

Physicians at the Johns Hopkins Kimmel Cancer Center report they have successfully treated 16 patients with a rare and lethal form of bone marrow failure called severe aplastic anemia using partially matched bone marrow transplants followed by two high doses of a common chemotherapy drug. In a report on the new transplant-chemo regimen, published online Dec. 22, 2016, in Biology of Blood and Marrow Transplantation, the Johns Hopkins team says that more than a year after their transplants, all of the patients have stopped taking immunosuppressive drugs commonly used to treat the disorder and have no evidence of the disease.

"Our findings have the potential to greatly widen treatment options for the vast majority of severe aplastic anemia patients," according to Robert Brodsky, M.D., professor of medicine and oncology at the Johns Hopkins Kimmel Cancer Center and an author of the report.

Results of the small clinical trial have already prompted the organization of a larger national trial being led by Amy DeZern, M.D., an assistant professor of oncology and medicine at the Johns Hopkins Kimmel Cancer Center, with plans to involve patients at 25 medical centers across the country.

Diagnosed in about one in 250,000 people each year, aplastic anemia occurs when one's own immune system damages blood-making bone marrow cells, which gradually stop producing red and white blood cells and platelets.

Patients must receive frequent blood transfusions, take multiple medicines to suppress the autoimmune response that damages the marrow, take other drugs to prevent infections, and limit contact with the outside world to avoid infection and even minor injury. Over the long term, most patients eventually die of infections.

When immunosuppressive therapy fails to keep the disease in check -- in as many as 30 to 40 percent of patients -- doctors usually prescribe a drug called eltrombopag, which is used in a variety of blood disorders to increase platelets. The drug, according to the Johns Hopkins experts, works only in about 30 percent of patients and usually leads to a partial, not complete, response.

Brodsky and DeZern say that the only curative treatment is a bone marrow transplant, but few patients have donors who are "fully matched" -- sharing the same collection of immune-stimulating proteins that decorate every cell in the body.

In an effort to overcome the donor shortage and offer transplant to more patients, DeZern, Brodsky and their colleagues enrolled 16 patients between 11 and 69 years of age in this study from July 2011 through August 2016.

Each of the patients had failed to respond to immunosuppressive therapy or other drug treatments. None had access to a related fully matched bone marrow donor but did have an available and willing donor who was a half match. Three patients used unrelated donors.

After administering a cocktail of drugs designed to suppress their immune system and prevent rejection of the donor marrow, the patients received half-matched bone marrow transplants, some from siblings or parents, and others from unrelated donors.

Three and four days after their transplants, the patients received high doses of the chemotherapy drug cyclophosphamide. For the next year, or slightly longer, they remained on immunosuppressive medications, including tacrolimus, then stopped taking them.

Within weeks of their transplants, tests showed that each of the patients' red and white blood cell and platelet counts had returned to normal levels without the need for blood transfusions. Once immunosuppressive therapy was stopped, none of the patients required further treatment related to their disease, the Johns Hopkins team reported.

Although 13 patients were able to discontinue immunosuppressive drugs a year after their transplant, three developed mild graft-versus-host disease (GVHD), a common complication of bone marrow transplants that occurs when immune cells in the transplant attack the newly transplanted cells. Two patients had mild GVHD that appeared on their skin, and one patient's GVHD occurred in the mouth and skin. After a few extra months of immunosuppressive therapy, their GVHD subsided, and they also were able to stop taking these medications.

Ending all therapy related to their disease has been life-changing for the patients, says DeZern. "It's like night and day," she says. "They go from not knowing if they have a future to hoping for what they'd hoped for before they got sick. It's that transformative."

Successful transplants using partial match donors, Brodsky says, open up the transplant option to nearly all patients with this condition, especially minority patients. Seven of the 16 patients treated at Johns Hopkins self-identified as nonwhite.

A full sibling only has a 25 percent chance of being a full match. However, 100 percent of parents and 50 percent of siblings or half-siblings are half matches, regardless of ethnicity. The average person in the United States has about four half matches or better. "Now, a therapy that used to be available to 25 to 30 percent of patients with severe aplastic anemia is potentially available to more than 95 percent," says Brodsky.

The idea of using cyclophosphamide after a partial-match transplant was first pioneered decades ago by Johns Hopkins Kimmel Cancer Center experts. Brodsky says the drug destroys patient's diseased immune system cells but does not harm the donor's blood stem cells, which create new disease-free blood cells in the patient.

Bone marrow transplants are costly -- sometimes exceeding more than $300,000. However, Brodsky and DeZern say that full and half-matched transplants are life-saving for many, and there is cost-saving potential when aplastic anemia patients can avoid a lifetime of immunosuppressive therapy, hospitalizations, medications and blood transfusions.

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16 aplastic anemia patients free of disease after bone marrow transplant and chemo - Science Daily

Bone Marrow Stem Cells Comments Off on 16 aplastic anemia patients free of disease after bone marrow transplant and chemo – Science Daily | February 7th, 2017

A New Delhi clinic that has claimed to help paralyzed Canadians walk again by injecting them with stem cells now says it can use the same treatment to make children with Down syndrome almost near normal.

Nutech Mediworld says it has treated up to 16 newborns, toddlers and older children with Down syndrome. According to its medical director, Geeta Shroff, we have seen that patients actually start improving clinically they become almost at par for their age.

Canadian experts say the bold claim risks raising false expectations and public confusion, much like the now-discredited Liberation therapy for multiple sclerosis, and that its playing off the over-hyped belief stem cells have the potential to cure almost anything.

Its also the latest controversy over stem cell tourism, and the growing number of clinics worldwide marketing pricey, unregulated and unproven treatments.

Nutech Mediworld charges US$5,000 to $6,000 per week for its stem cell-based therapies. The clinic says it has treated such incurable conditions as spinal cord injury and cerebral palsy. Around 20 Canadians have sought treatment at the clinic for paralyzing spinal cord injuries, spending upwards of $US48,000 each. Shroff says some of her patients have regained the ability to walk with walkers.

More recently, she began working with Down syndrome, one of the most common chromosomal disorders worldwide.

Most cases are caused by a random error in cell division. The child ends up with three copies of chromosome 21, instead of the usual two.

That extra copy causes abnormal neuronal development and changes in the central nervous system, Shroff says, leading to persistent developmental delays.

Human embryonic stem cells injected into a childs muscles and bloodstreamcan regenerate and repair that damaged brain, she says. They also work at the genetic level, she claims.

In a single case published last year, Shroff reported treating a two-month-old baby boy in September 2014 diagnosed with Down syndrome at birth. The infant had delayed milestones, lack of speech, subnormal understanding and subnormal motor skills, she wrote.

After two stem cell therapy sessions, the baby started babbling and crawling, she reported. He had improved muscle tone. He was social and was able to recognize near ones.

The child became almost as near normal as possible cognitively

The child became almost as near normal as possible cognitively, Shroff told the Post in an interview. Today, hes talking; hes walking. He was at par with normal children on analysis.

The former infertility specialist uses embryonic stem cells developed from a single fertilized egg donated by an IVF patient 17 years ago. According to Shroff, We have witnessed no adverse events at all.

The Down syndrome treatments, reported by New Scientist, have raised skepticism and alarm. Its not at all clear what cells shes actually putting in patients, says renowned developmental biologist Janet Rossant, senior scientist at the Hospital for Sick Children Research Institute in Toronto.

By just putting them into the bloodstream theres no way to imagine they could contribute to the right tissues.

Embryonic stem cells can also form teratomas benign tumours and masses composed of lung cells, tufts of hair, teeth, bone and other tissues.

The gold standard for any therapy would be a clinical trial comparing treated with untreated children and vetted through proper regulatory systems that clearly she is not going through, Rossant says.

The Ottawa Hospitals Dr. Duncan Stewart, who is leading the first trial in the world of a genetically enhanced stem cell therapy for heart attack, says theres a remote chance embryonic stem cells could help with Down syndrome. But its a stretch. The injected cells would also likely be rejected and die off with days, he believes. If the cells are disappearing within days, how are they working?

This is a very vulnerable population Theyre very vulnerable to people who are selling hope and have no basis for it

This is a very vulnerable population, Stewart adds. Theyre very vulnerable to people who are selling hope and have no basis for it.

But stem cells have taken on almost mystical appeal.

Theyve become a pop culture phenomenon, says healthy policy expert Timothy Caulfield, of the University of Alberta. The field itself is guilty of making breathless announcements about breakthroughs and cutting edge, he says. And people can market that kind of language.

This kind of nonsense doesnt help.

Email: jskirkey@postmedia.com | Twitter:

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From Down syndrome to 'near normal'? New Delhi clinic makes stem cell claims that worry experts - National Post

Spinal Cord Stem Cells Comments Off on From Down syndrome to ‘near normal’? New Delhi clinic makes stem cell claims that worry experts – National Post | February 7th, 2017

Stem cells have tremendous promise to help us understand and treat a range of diseases, injuries and other health-related conditions. Their potential is evident in the use of blood stem cells to treat diseases of the blood, a therapy that has saved the lives of thousands of children with leukemia; and can be seen in the use of stem cells for tissue grafts to treat diseases or injury to the bone, skin and surface of the eye. Important clinical trials involving stem cells are underway for many other conditions and researchers continue to explore new avenues using stem cells in medicine.

There is still a lot to learn about stem cells, however, and their current applications as treatments are sometimes exaggerated by the media and other parties who do not fully understand the science and current limitations, and also by clinics looking to capitalize on the hype by selling treatments to chronically ill or seriously injured patients. The information on this page is intended to help you understand both the potential and the limitations of stem cells at this point in time, and to help you spot some of the misinformation that is widely circulated by clinics offering unproven treatments.

It is important to discuss these Nine Things to Know and any research or information you gather with your primary care physician and other trusted members of your healthcare team in deciding what is right for you.

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Nine Things to Know About Stem Cell Treatments

Skin Stem Cells Comments Off on Nine Things to Know About Stem Cell Treatments | February 3rd, 2017

The primary focus of the Disabled World web site is to provide up to date information via our informative articles, disability news and educational videos. In addition to stories by our in-house writers and news items by disability organizations and Government Departments, each day we manually select relevant items that we consider will be of interest to persons with disabilities, carers, and the general public. Submission of disability related information, press releases and events are welcome.

The word "disabled" is defined as having a physical or mental disability : unable to perform one or more natural activities (such as walking or seeing) because of illness, injury, etc.

The word disabled came to be used as the standard term in referring to people with physical or mental disabilities in the second half of the 20th century - and it remains the most generally accepted term in both British and US English. Lately, "Disability" and "Disabled" are terms that are undergoing change due to the disability rights movement in the U.S. and U.K. - Disability or Disabled - Which Term is Right?

"People with disabilities are the largest minority group, the only one any person can join at any time."

Disability is a subject you may read about online, or in a newspaper, but not think of as something that might actually happen to you. But your chances of becoming disabled are greater than you realize. Today more people live with a disability than ever before due to our aging societies as well as improved medical treatments helping manage long-term health problems.

Some people are born with a disability, others become disabled as a result of an illness or injury, and some people develop them as they age. At some point in our lives almost all of us will have some type of disability.

More World Disability Facts & Statistics

One of the key challenges for a person with a disability is to be seen by the public, to be portrayed in media outlets, and treated by health care professionals, as an individual with their own abilities, not just stereotyped as a "disabled person".

More Disability & Health News

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Disabled World - Disability News & Information

Spinal Cord Stem Cells Comments Off on Disabled World – Disability News & Information | January 19th, 2017

What is a bone marrow transplant?

Bone marrow transplant (BMT) is a special therapy for patients with certain cancers or other diseases. A bone marrow transplant involves taking cells that are normally found in the bone marrow (stem cells), filtering those cells, and giving them back either to the donor (patient) or to another person. The goal of BMT is to transfuse healthy bone marrow cells into a person after their own unhealthy bone marrow has been treated to kill the abnormal cells.

Bone marrow transplant has been used successfully to treat diseases such as leukemias, lymphomas, aplastic anemia, immune deficiency disorders, and some solid tumor cancers since 1968.

What is bone marrow?

Bone marrow is the soft, spongy tissue found inside bones. It is the medium for development and storage of most of the body's blood cells.

The blood cells that produce other blood cells are called stem cells. The most primitive of the stem cells is called the pluripotent stem cell, which is different than other blood cells with regards to the following properties:

It is the stem cells that are needed in bone marrow transplant.

Why is a bone marrow transplant needed?

The goal of a bone marrow transplant is to cure many diseases and types of cancer. When the doses of chemotherapy or radiation needed to cure a cancer are so high that a person's bone marrow stem cells will be permanently damaged or destroyed by the treatment, a bone marrow transplant may be needed. Bone marrow transplants may also be needed if the bone marrow has been destroyed by a disease.

A bone marrow transplant can be used to:

The risks and benefits must be weighed in a thorough discussion with your doctor and specialists in bone marrow transplants prior to procedure.

What are some diseases that may benefit from bone marrow transplant?

The following diseases are the ones that most commonly benefit from bone marrow transplant:

However, patients experience diseases differently, and bone marrow transplant may not be appropriate for everyone who suffers from these diseases.

What are the different types of bone marrow transplants?

There are different types of bone marrow transplants depending on who the donor is. The different types of BMT include the following:

How are a donor and recipient matched?

Matching involves typing human leukocyte antigen (HLA) tissue. The antigens on the surface of these special white blood cells determine the genetic makeup of a person's immune system. There are at least 100 HLA antigens; however, it is believed that there are a few major antigens that determine whether a donor and recipient match. The others are considered "minor" and their effect on a successful transplant is not as well-defined.

Medical research is still investigating the role all antigens play in the process of a bone marrow transplant. The more antigens that match, the better the engraftment of donated marrow. Engraftment of the stem cells occurs when the donated cells make their way to the marrow and begin producing new blood cells.

Most of the genes that "code" for the human immune system are on one chromosome. Since we only have two of each chromosome, one we received from each of our parents, a full sibling of a patient in need of a transplant has a one in four chance of having gotten the same set of chromosomes and being a "full match" for transplantation.

The bone marrow transplant team

The group of specialists involved in the care of patients going through transplant is often referred to as the transplant team. All individuals work together to provide the best chance for a successful transplant. The team consists of the following:

An extensive evaluation is completed by the bone marrow transplant team. The decision for you to undergo a bone marrow transplant will be based on many factors, including the following:

For a patient receiving the transplant, the following will occur in advance of the procedure:

Preparation for the donor

How are the stem cells collected?

A bone marrow transplant is done by transferring stem cells from one person to another. Stem cells can either be collected from the circulating cells in the blood (the peripheral system) or from the bone marrow.

If the donor is the person himself or herself, it is called an autologous bone marrow transplant. If an autologous transplant is planned, previously collected stem cells, from either peripheral (apheresis) or harvest, are counted, screened, and ready to infuse.

The bone marrow transplant procedure

The preparations for a bone marrow transplant vary depending on the type of transplant, the disease requiring transplant, and your tolerance for certain medications. Consider the following:

The days before transplant are counted as minus days. The day of transplant is considered day zero. Engraftment and recovery following the transplant are counted as plus days. For example, a patient may enter the hospital on day -8 for preparative regimen. The day of transplant is numbered zero. Days +1, +2, etc., will follow. There are specific events, complications, and risks associated with each day before, during, and after transplant. The days are numbered to help the patient and family understand where they are in terms of risks and discharge planning.

During infusion of bone marrow, the patient may experience the following:

After infusion, the patient may:

After leaving the hospital, the recovery process continues for several months or longer, during which time the patient cannot return to work or many previously enjoyed activities. The patient must also make frequent follow-up visits to the hospital or doctor's office.

When does engraftment occur?

Engraftment of the stem cells occurs when the donated cells make their way to the marrow and begin producing new blood cells. Depending on the type of transplant and the disease being treated, engraftment usually occurs around day +15 or +30. Blood counts will be checked frequently during the days following transplant to evaluate initiation and progress of engraftment. Platelets are generally the last blood cell to recover.

Engraftment can be delayed because of infection, medications, low donated stem cell count, or graft failure. Although the new bone marrow may begin making cells in the first 30 days following transplant, it may take months, even years, for the entire immune system to fully recover.

What complications and side effects may occur following BMT?

Complications may vary, depending on the following:

The following are complications that may occur with a bone marrow transplant. However, each individual may experience symptoms differently. These complications may also occur alone, or in combination:

Long-term outlook for a bone marrow transplantation

Prognosis greatly depends on the following:

As with any procedure, in bone marrow transplant the prognosis and long-term survival can vary greatly from person to person. The number of transplants being done for an increasing number of diseases, as well as ongoing medical developments, have greatly improved the outcome for bone marrow transplant in children and adults. Continuous follow-up care is essential for the patient following a bone marrow transplant. New methods to improve treatment and to decrease complications and side effects of a bone marrow transplant are continually being discovered.

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Bone Marrow Transplantation | Hematology and Oncology

Bone Marrow Stem Cells Comments Off on Bone Marrow Transplantation | Hematology and Oncology | January 9th, 2017

It may sound like science fiction, but the research of Stephanie Willerth of the University of Victoria is proving to be anything but. A patients adult cells will be reprogrammed back into their stem cell state.....

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Septic shock is the most severe form of infection seen in intensive care units (ICUs), a sneaky and unpredictable condition according to the Ottawa Health Research Institutes Dr. Lauralyn McIntyre...

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Its been 12 years since Canada passed legislation governing research on human embryos. As it stands, the legislation has not kept pace with the science... ...

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Umbilical cord blood can be a promising source of hematopoietic stem cells (HSCs), used in treating blood diseases...

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Liver transplants save lives, plain and simple. But they also sentence recipients to a lifetime of immune-suppressive drugs, to prevent the body from rejecting the foreign addition....

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Its an exciting time for the Stem Cell Network! We have been very busy over the past few months ensuring that we are able to deliver on our mandate and see research funding and training opportunities provided for...

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Stem Cell Network

Spinal Cord Stem Cells Comments Off on Stem Cell Network | January 7th, 2017

Clinical trials using neural stem cells

Neural stem cells (mouse)

StemCell Inc In December 2010 the Swiss regulatory agency for therapeutic products gave the go-ahead for aStemCell, Inc.-SponsoredPhase I/II clinical trial on chronic spinal cord injuryat the Balgrist University Hospital in Zurich (Switzerland). This trial had been inspired by the preclinical evidence of direct oligodendrocyte cell replacement through human neural stem cell (NSC) transplants in early chronic SCI in a particular mouse model. The trial uses a type of stem cell derived from human brain tissue and can make any of the three major kinds of neural cells found in the central nervous system. A single donor can provide eough cells for several transplanted patients). A single dose (20 x 106cells) of HuCNS-SC is directly implanted through multiple injections into thethoracicspinal cord of patients with chronic thoracic (T2T11) SCI, and immune suppression administered for 9 months after transplantation. This trial had enrolled patients 312 months after complete and incomplete cord injuries. The estimated completion date of this study is March 2016 (clinicaltrials.govidentifier no. NCT01321333). Interim analysis of clinical data to May 2014, presented at the Annual Meeting of the American Spinal Injury Association in San Antonio, Texas has shown that the significant post-transplant gains in sensory function first reported in two patients have now been observed in two additional patients.

The next group of patients currently being recruited in North America (University of Calgary) as well as in Switzerland has included some with incomplete injuries (ie some retained sensory or motor function) (clinicaltrials.govidentifier no. NCT01725880).

Earlier last year, the same company completed enrollment in multicentre open-label Phase I/II clinical titled "Study of Human Central Nervous System (CNS) Stem Cell Transplantation in Cervical Spinal Cord Injury" (Pathway Study website;clinicaltrials.govidentifier no. NCT02163876). The Pathway Study is the first clinical study designed to evaluate both the safetyandefficacy of transplanting stem cells. A total of 52 patients with traumatic injury to the cervical spinal cord are enrolled in the trial. The trial will be conducted as a randomized, controlled, single blind study and efficacy will be primarily measured by assessing motor function according to the International Standards for Neurological Classification of Spinal Cord Injury (ISNCSCI). The primary efficacy outcome will focus on change in upper extremity strength as measured in the hands, arms, and shoulders. The trial will follow the patients for one year from the time of enrollment.

The hope is that when transplanted into the injured spinal cord, these cells may re-establish some of the circuitries important for the network of nerves that carry information around the body.

Neuralstem Neuralstembegan surgeries in a Phase I safety trial of its NSI-566 neural stem cells for chronic spinal cord injury (cSCI) at the University of California, San Diego School of Medicine, with support from the UC San Diego Sanford Stem Cell Clinical Center, in September 2014 (clinicaltrials.govidentifier no. NCT01772810). The FDA amended the Phase I trial protocol to include a total of four patients, as the safety of the same cells and a similar procedure were proven in Neuralstems NSI-566/ALS trials. The four cSCI patients, with thoracic spinal cord injuries (T2-T12), have an American Spinal Injury Association (AIS) grade A level of impairment one-to-two years post-injury. This means that they have no motor or sensory function in the relevant segments at or below the injury, and are considered to be completely paralysed.

All patients in the trial will receive six injections in, or around, the injury site, using the same cells and similar procedure as the companys Amyotrophic Lateral Sclerosis (ALS) trials (the first FDA-approved neural stem cell trial for the treatment of ALS). All patients will also receive physical therapy post-surgery to guide newly formed nerves to their proper connections and functionality. The patients will also receive immunosuppressive therapy, which will be for three months, as tolerated. The trial study period will end six months post-surgery of the last patient, with a one-year Phase I completion goal. An NSI-566/acute spinal cord injury Phase I/II trial is expected to commence in the first quarter of 2015 in Seoul, South Korea.

The Miami Project to Cure Paralysis The Miami Projectclinical researchers currently have several clinical trials and clinical studies available for people who have had a spinal cord injury; some are for acute injuries and some are for chronic injuries. The clinical trials are testing the safety and efficacy of different cellular, neuroprotective, reparative, or modulatory interventions. These include Phase I clinical trials with the patients own (peripheral nerve-derived) Schwann cells in bothsubacute thoracicandchronic cervical and thoracicSCIs and a multicenter Phase II clinical trial withHuCNS-SC in chronic cervical SCIs(as above). All these Miami Project cell therapy trials are recruiting patients (more info on clinicaltrials.gov).

Mesenchymal/stromal stem cellsare being investigated as possible treatments for spinal cord injuries. Clinical Trials (clinicaltrials.gov) identifies at present total of 9 trials tagged as MSC trials in spinal cord injuries. These include studies that investigate the safety and efficacy of MSCs derived from the patients own bone marrow (5), adipose tissue (fat) (3) or cord blood (1). MSCs are injected in a number of different ways in these trials - including directly into the spinal cord or the lesion itself, intravenously, or even just in the skin, in patients with chronic cervical to thoracic injuries showingASIA/ISCoS scoresbetween A (complete lack of motor and sensory function below the level of injury) and C (some muscle movement is spared below the level of injury, but 50 percent of the muscles below the level of injury cannot move against gravity).

The hope is that when transplanted into the injured spinal cord, these cells may provide tissue protective molecules/factors and help (indirectly from cell integration and differentiation) to re-establish some of the circuitries important for the network of nerves that carry information around the body.

California based biotech Geronhad a widely reported clinical trial under way for a treatment the first of its kind involving the injection of cells derived from human embryonic stem cells. The injected cells were precursors of oligodendrocytes, the cells that form the insulating myelin sheath around axons. Researchers hoped that these cells, once injected into the spinal cord, would mature and form a new coating on the nerve cells, restoring the ability of signals to cross the spinal cord injury site.

After treating four patients with these cells in a phase one (safety) trial, and reporting no serious adverse effects, Geron announced in November 2011 it was discontinuing its stem cell programme. The company said stem cells continue to hold great promise, but cited financial reasons for shifting focus to other areas of research.

Asterias Biotherapeutics Following up on the cellular technology initially developed by Geron, Asterias Biotherapeutics has developed a program that focuses on the development of a kind of nerve cell, oligodendrocyte progenitor cells (OPCs) for spinal cord injury. These cells, known as AST-OPC1, are produced from human embryonic stem (ES) cells.

In aPhase 1 clinical trial, five patients with neurologically complete, thoracic spinal cord injury were administered two million hES cell-derived OPCs at the spinal cord injury site 7-14 days post-injury. The subjects received low levels immunosuppression for the next 60 days. Delivery of OPCs was successful in all five subjects with no serious adverse events associated with the administration of the cells or the immunosuppressive regimen. In four of the five subjects, serial MRI scans suggested reduction of the volume of injury in the spinal cord

A second follow up (dose escalation)Phase I/II trialwith AST-OPC1 in acute (14-30 days after injury) sensorimotor complete cervical spinal cord injuries (SCI) is currently recruiting participants.

The hope is that when acutely transplanted into the injured spinal cord, OPCs may remyelinate and restore lost functions.

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Spinal cord injuries: how could stem cells help ...

Spinal Cord Stem Cells Comments Off on Spinal cord injuries: how could stem cells help … | December 25th, 2016

Spinal cord injuries result from damage to the vertebrae, ligaments or disks of the spinal column or to the spinal cord itself.

A traumatic spinal cord injury may stem from a sudden, traumatic blow to your spine that fractures, dislocates, crushes, or compresses one or more of your vertebrae. It also may result from a gunshot or knife wound that penetrates and cuts your spinal cord.

Additional damage usually occurs over days or weeks because of bleeding, swelling, inflammation and fluid accumulation in and around your spinal cord.

A nontraumatic spinal cord injury may be caused by arthritis, cancer, inflammation, infections or disk degeneration of the spine.

The central nervous system comprises the brain and spinal cord. The spinal cord, made of soft tissue and surrounded by bones (vertebrae), extends downward from the base of your brain and is made up of nerve cells and groups of nerves called tracts, which go to different parts of your body.

The lower end of your spinal cord stops a little above your waist in the region called the conus medullaris. Below this region is a group of nerve roots called the cauda equina.

Tracts in your spinal cord carry messages between the brain and the rest of the body. Motor tracts carry signals from the brain to control muscle movement. Sensory tracts carry signals from body parts to the brain relating to heat, cold, pressure, pain and the position of your limbs.

Whether the cause is traumatic or nontraumatic, the damage affects the nerve fibers passing through the injured area and may impair part or all of your corresponding muscles and nerves below the injury site.

A chest (thoracic) or lower back (lumbar) injury can affect your torso, legs, bowel and bladder control, and sexual function. In addition, a neck (cervical) injury affects movements of your arms and, possibly, your ability to breathe.

The most common causes of spinal cord injuries in the United States are:

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Spinal cord injury Causes - Mayo Clinic

Spinal Cord Stem Cells Comments Off on Spinal cord injury Causes – Mayo Clinic | November 27th, 2016

The spine has different sections. The level of paralysis depends on the location of the injury.The spinal cord is made up of millions of nerve cells that send projections up and down the cord and out into other parts of the body. The information that allows us to sit, run, go to the toilet and breathe travels along these projections, called nerves.

When the spinal cord is injured, the initial trauma causes cell damage and destruction, and triggersa cascade of eventsthat spread around the injury site affecting a number of different types of cells. Axons are crushed and torn, and oligodendrocytes, the nerve cells that make up the insulating myelin sheath around axons, begin to die. Exposed axons degenerate, the connection between neurons is disrupted and the flow of information between the brain and the spinal cord is blocked.

The body cannot replace cells lost when the spinal cord is injured, and its function becomes impaired permanently. Patients may end up with severe movement and sensation disabilities. They will generally be paralyzed and without sensation from the level of the injury downwards.

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What happens when the spinal cord is injured? | Europe's ...

Spinal Cord Stem Cells Comments Off on What happens when the spinal cord is injured? | Europe’s … | November 27th, 2016

Hematopoietic stem cell transplantation (HSCT) is the transplantation of multipotent hematopoietic stem cells, usually derived from bone marrow, peripheral blood, or umbilical cord blood.[1][2] It may be autologous (the patient's own stem cells are used), allogeneic (the stem cells come from a donor) or syngeneic (from an identical twin).[1][2] It is a medical procedure in the field of hematology, most often performed for patients with certain cancers of the blood or bone marrow, such as multiple myeloma or leukemia.[2] In these cases, the recipient's immune system is usually destroyed with radiation or chemotherapy before the transplantation. Infection and graft-versus-host disease are major complications of allogeneic HSCT.[2]

Hematopoietic stem cell transplantation remains a dangerous procedure with many possible complications; it is reserved for patients with life-threatening diseases. As survival following the procedure has increased, its use has expanded beyond cancer, such as autoimmune diseases.[3][4]

Indications for stem cell transplantation are as follows:

Many recipients of HSCTs are multiple myeloma[5] or leukemia patients[6] who would not benefit from prolonged treatment with, or are already resistant to, chemotherapy. Candidates for HSCTs include pediatric cases where the patient has an inborn defect such as severe combined immunodeficiency or congenital neutropenia with defective stem cells, and also children or adults with aplastic anemia[7] who have lost their stem cells after birth. Other conditions[8] treated with stem cell transplants include sickle-cell disease, myelodysplastic syndrome, neuroblastoma, lymphoma, Ewing's sarcoma, desmoplastic small round cell tumor, chronic granulomatous disease and Hodgkin's disease. More recently non-myeloablative, "mini transplant(microtransplantation)," procedures have been developed that require smaller doses of preparative chemo and radiation. This has allowed HSCT to be conducted in the elderly and other patients who would otherwise be considered too weak to withstand a conventional treatment regimen.

In 2006 a total of 50,417 first hematopoietic stem cell transplants were reported as taking place worldwide, according to a global survey of 1327 centers in 71 countries conducted by the Worldwide Network for Blood and Marrow Transplantation. Of these, 28,901 (57 percent) were autologous and 21,516 (43 percent) were allogeneic (11,928 from family donors and 9,588 from unrelated donors). The main indications for transplant were lymphoproliferative disorders (54.5 percent) and leukemias (33.8 percent), and the majority took place in either Europe (48 percent) or the Americas (36 percent).[9]

In 2014, according to the World Marrow Donor Association, stem cell products provided for unrelated transplantation worldwide had increased to 20,604 (4,149 bone marrow donations, 12,506 peripheral blood stem cell donations, and 3,949 cord blood units).[10]

Autologous HSCT requires the extraction (apheresis) of haematopoietic stem cells (HSC) from the patient and storage of the harvested cells in a freezer. The patient is then treated with high-dose chemotherapy with or without radiotherapy with the intention of eradicating the patient's malignant cell population at the cost of partial or complete bone marrow ablation (destruction of patient's bone marrow's ability to grow new blood cells). The patient's own stored stem cells are then transfused into his/her bloodstream, where they replace destroyed tissue and resume the patient's normal blood cell production. Autologous transplants have the advantage of lower risk of infection during the immune-compromised portion of the treatment since the recovery of immune function is rapid. Also, the incidence of patients experiencing rejection (and graft-versus-host disease is impossible) is very rare due to the donor and recipient being the same individual. These advantages have established autologous HSCT as one of the standard second-line treatments for such diseases as lymphoma.[11]

However, for other cancers such as acute myeloid leukemia, the reduced mortality of the autogenous relative to allogeneic HSCT may be outweighed by an increased likelihood of cancer relapse and related mortality, and therefore the allogeneic treatment may be preferred for those conditions.[12] Researchers have conducted small studies using non-myeloablative hematopoietic stem cell transplantation as a possible treatment for type I (insulin dependent) diabetes in children and adults. Results have been promising; however, as of 2009[update] it was premature to speculate whether these experiments will lead to effective treatments for diabetes.[13]

Allogeneics HSCT involves two people: the (healthy) donor and the (patient) recipient. Allogeneic HSC donors must have a tissue (HLA) type that matches the recipient. Matching is performed on the basis of variability at three or more loci of the HLA gene, and a perfect match at these loci is preferred. Even if there is a good match at these critical alleles, the recipient will require immunosuppressive medications to mitigate graft-versus-host disease. Allogeneic transplant donors may be related (usually a closely HLA matched sibling), syngeneic (a monozygotic or 'identical' twin of the patient - necessarily extremely rare since few patients have an identical twin, but offering a source of perfectly HLA matched stem cells) or unrelated (donor who is not related and found to have very close degree of HLA matching). Unrelated donors may be found through a registry of bone marrow donors such as the National Marrow Donor Program. People who would like to be tested for a specific family member or friend without joining any of the bone marrow registry data banks may contact a private HLA testing laboratory and be tested with a mouth swab to see if they are a potential match.[14] A "savior sibling" may be intentionally selected by preimplantation genetic diagnosis in order to match a child both regarding HLA type and being free of any obvious inheritable disorder. Allogeneic transplants are also performed using umbilical cord blood as the source of stem cells. In general, by transfusing healthy stem cells to the recipient's bloodstream to reform a healthy immune system, allogeneic HSCTs appear to improve chances for cure or long-term remission once the immediate transplant-related complications are resolved.[15][16][17]

A compatible donor is found by doing additional HLA-testing from the blood of potential donors. The HLA genes fall in two categories (Type I and Type II). In general, mismatches of the Type-I genes (i.e. HLA-A, HLA-B, or HLA-C) increase the risk of graft rejection. A mismatch of an HLA Type II gene (i.e. HLA-DR, or HLA-DQB1) increases the risk of graft-versus-host disease. In addition a genetic mismatch as small as a single DNA base pair is significant so perfect matches require knowledge of the exact DNA sequence of these genes for both donor and recipient. Leading transplant centers currently perform testing for all five of these HLA genes before declaring that a donor and recipient are HLA-identical.

Race and ethnicity are known to play a major role in donor recruitment drives, as members of the same ethnic group are more likely to have matching genes, including the genes for HLA.[18]

As of 2013[update], there were at least two commercialized allogeneic cell therapies, Prochymal and Cartistem.[19]

To limit the risks of transplanted stem cell rejection or of severe graft-versus-host disease in allogeneic HSCT, the donor should preferably have the same human leukocyte antigens (HLA) as the recipient. About 25 to 30 percent of allogeneic HSCT recipients have an HLA-identical sibling. Even so-called "perfect matches" may have mismatched minor alleles that contribute to graft-versus-host disease.

In the case of a bone marrow transplant, the HSC are removed from a large bone of the donor, typically the pelvis, through a large needle that reaches the center of the bone. The technique is referred to as a bone marrow harvest and is performed under general anesthesia.

Peripheral blood stem cells[20] are now the most common source of stem cells for HSCT. They are collected from the blood through a process known as apheresis. The donor's blood is withdrawn through a sterile needle in one arm and passed through a machine that removes white blood cells. The red blood cells are returned to the donor. The peripheral stem cell yield is boosted with daily subcutaneous injections of Granulocyte-colony stimulating factor, serving to mobilize stem cells from the donor's bone marrow into the peripheral circulation.

It is also possible to extract stem cells from amniotic fluid for both autologous or heterologous use at the time of childbirth.

Umbilical cord blood is obtained when a mother donates her infant's umbilical cord and placenta after birth. Cord blood has a higher concentration of HSC than is normally found in adult blood. However, the small quantity of blood obtained from an Umbilical Cord (typically about 50 mL) makes it more suitable for transplantation into small children than into adults. Newer techniques using ex-vivo expansion of cord blood units or the use of two cord blood units from different donors allow cord blood transplants to be used in adults.

Cord blood can be harvested from the Umbilical Cord of a child being born after preimplantation genetic diagnosis (PGD) for human leucocyte antigen (HLA) matching (see PGD for HLA matching) in order to donate to an ill sibling requiring HSCT.

Unlike other organs, bone marrow cells can be frozen (cryopreserved) for prolonged periods without damaging too many cells. This is a necessity with autologous HSC because the cells must be harvested from the recipient months in advance of the transplant treatment. In the case of allogeneic transplants, fresh HSC are preferred in order to avoid cell loss that might occur during the freezing and thawing process. Allogeneic cord blood is stored frozen at a cord blood bank because it is only obtainable at the time of childbirth. To cryopreserve HSC, a preservative, DMSO, must be added, and the cells must be cooled very slowly in a controlled-rate freezer to prevent osmotic cellular injury during ice crystal formation. HSC may be stored for years in a cryofreezer, which typically uses liquid nitrogen.

The chemotherapy or irradiation given immediately prior to a transplant is called the conditioning regimen, the purpose of which is to help eradicate the patient's disease prior to the infusion of HSC and to suppress immune reactions. The bone marrow can be ablated (destroyed) with dose-levels that cause minimal injury to other tissues. In allogeneic transplants a combination of cyclophosphamide with total body irradiation is conventionally employed. This treatment also has an immunosuppressive effect that prevents rejection of the HSC by the recipient's immune system. The post-transplant prognosis often includes acute and chronic graft-versus-host disease that may be life-threatening. However, in certain leukemias this can coincide with protection against cancer relapse owing to the graft versus tumor effect.[21]Autologous transplants may also use similar conditioning regimens, but many other chemotherapy combinations can be used depending on the type of disease.

A newer treatment approach, non-myeloablative allogeneic transplantation, also termed reduced-intensity conditioning (RIC), uses doses of chemotherapy and radiation too low to eradicate all the bone marrow cells of the recipient.[22]:320321 Instead, non-myeloablative transplants run lower risks of serious infections and transplant-related mortality while relying upon the graft versus tumor effect to resist the inherent increased risk of cancer relapse.[23][24] Also significantly, while requiring high doses of immunosuppressive agents in the early stages of treatment, these doses are less than for conventional transplants.[25] This leads to a state of mixed chimerism early after transplant where both recipient and donor HSC coexist in the bone marrow space.

Decreasing doses of immunosuppressive therapy then allows donor T-cells to eradicate the remaining recipient HSC and to induce the graft versus tumor effect. This effect is often accompanied by mild graft-versus-host disease, the appearance of which is often a surrogate marker for the emergence of the desirable graft versus tumor effect, and also serves as a signal to establish an appropriate dosage level for sustained treatment with low levels of immunosuppressive agents.

Because of their gentler conditioning regimens, these transplants are associated with a lower risk of transplant-related mortality and therefore allow patients who are considered too high-risk for conventional allogeneic HSCT to undergo potentially curative therapy for their disease. The optimal conditioning strategy for each disease and recipient has not been fully established, but RIC can be used in elderly patients unfit for myeloablative regimens, for whom a higher risk of cancer relapse may be acceptable.[22][24]

After several weeks of growth in the bone marrow, expansion of HSC and their progeny is sufficient to normalize the blood cell counts and re-initiate the immune system. The offspring of donor-derived hematopoietic stem cells have been documented to populate many different organs of the recipient, including the heart, liver, and muscle, and these cells had been suggested to have the abilities of regenerating injured tissue in these organs. However, recent research has shown that such lineage infidelity does not occur as a normal phenomenon[citation needed].

HSCT is associated with a high treatment-related mortality in the recipient (1 percent or higher)[citation needed], which limits its use to conditions that are themselves life-threatening. Major complications are veno-occlusive disease, mucositis, infections (sepsis), graft-versus-host disease and the development of new malignancies.

Bone marrow transplantation usually requires that the recipient's own bone marrow be destroyed ("myeloablation"). Prior to "engraftment" patients may go for several weeks without appreciable numbers of white blood cells to help fight infection. This puts a patient at high risk of infections, sepsis and septic shock, despite prophylactic antibiotics. However, antiviral medications, such as acyclovir and valacyclovir, are quite effective in prevention of HSCT-related outbreak of herpetic infection in seropositive patients.[26] The immunosuppressive agents employed in allogeneic transplants for the prevention or treatment of graft-versus-host disease further increase the risk of opportunistic infection. Immunosuppressive drugs are given for a minimum of 6-months after a transplantation, or much longer if required for the treatment of graft-versus-host disease. Transplant patients lose their acquired immunity, for example immunity to childhood diseases such as measles or polio. For this reason transplant patients must be re-vaccinated with childhood vaccines once they are off immunosuppressive medications.

Severe liver injury can result from hepatic veno-occlusive disease (VOD). Elevated levels of bilirubin, hepatomegaly and fluid retention are clinical hallmarks of this condition. There is now a greater appreciation of the generalized cellular injury and obstruction in hepatic vein sinuses, and hepatic VOD has lately been referred to as sinusoidal obstruction syndrome (SOS). Severe cases of SOS are associated with a high mortality rate. Anticoagulants or defibrotide may be effective in reducing the severity of VOD but may also increase bleeding complications. Ursodiol has been shown to help prevent VOD, presumably by facilitating the flow of bile.

The injury of the mucosal lining of the mouth and throat is a common regimen-related toxicity following ablative HSCT regimens. It is usually not life-threatening but is very painful, and prevents eating and drinking. Mucositis is treated with pain medications plus intravenous infusions to prevent dehydration and malnutrition.

Graft-versus-host disease (GVHD) is an inflammatory disease that is unique to allogeneic transplantation. It is an attack of the "new" bone marrow's immune cells against the recipient's tissues. This can occur even if the donor and recipient are HLA-identical because the immune system can still recognize other differences between their tissues. It is aptly named graft-versus-host disease because bone marrow transplantation is the only transplant procedure in which the transplanted cells must accept the body rather than the body accepting the new cells.[27]

Acute graft-versus-host disease typically occurs in the first 3 months after transplantation and may involve the skin, intestine, or the liver. High-dose corticosteroids such as prednisone are a standard treatment; however this immuno-suppressive treatment often leads to deadly infections. Chronic graft-versus-host disease may also develop after allogeneic transplant. It is the major source of late treatment-related complications, although it less often results in death. In addition to inflammation, chronic graft-versus-host disease may lead to the development of fibrosis, or scar tissue, similar to scleroderma; it may cause functional disability and require prolonged immunosuppressive therapy. Graft-versus-host disease is usually mediated by T cells, which react to foreign peptides presented on the MHC of the host.[citation needed]

Graft versus tumor effect (GVT) or "graft versus leukemia" effect is the beneficial aspect of the Graft-versus-Host phenomenon. For example, HSCT patients with either acute, or in particular chronic, graft-versus-host disease after an allogeneic transplant tend to have a lower risk of cancer relapse.[28][29] This is due to a therapeutic immune reaction of the grafted donor T lymphocytes against the diseased bone marrow of the recipient. This lower rate of relapse accounts for the increased success rate of allogeneic transplants, compared to transplants from identical twins, and indicates that allogeneic HSCT is a form of immunotherapy. GVT is the major benefit of transplants that do not employ the highest immuno-suppressive regimens.

Graft versus tumor is mainly beneficial in diseases with slow progress, e.g. chronic leukemia, low-grade lymphoma, and some cases multiple myeloma. However, it is less effective in rapidly growing acute leukemias.[30]

If cancer relapses after HSCT, another transplant can be performed, infusing the patient with a greater quantity of donor white blood cells (Donor lymphocyte infusion).[30]

Patients after HSCT are at a higher risk for oral carcinoma. Post-HSCT oral cancer may have more aggressive behavior with poorer prognosis, when compared to oral cancer in non-HSCT patients.[31]

Prognosis in HSCT varies widely dependent upon disease type, stage, stem cell source, HLA-matched status (for allogeneic HSCT) and conditioning regimen. A transplant offers a chance for cure or long-term remission if the inherent complications of graft versus host disease, immuno-suppressive treatments and the spectrum of opportunistic infections can be survived.[15][16] In recent years, survival rates have been gradually improving across almost all populations and sub-populations receiving transplants.[32]

Mortality for allogeneic stem cell transplantation can be estimated using the prediction model created by Sorror et al.,[33] using the Hematopoietic Cell Transplantation-Specific Comorbidity Index (HCT-CI). The HCT-CI was derived and validated by investigators at the Fred Hutchinson Cancer Research Center (Seattle, WA). The HCT-CI modifies and adds to a well-validated comorbidity index, the Charlson Comorbidity Index (CCI) (Charlson et al.[34]) The CCI was previously applied to patients undergoing allogeneic HCT but appears to provide less survival prediction and discrimination than the HCT-CI scoring system.

The risks of a complication depend on patient characteristics, health care providers and the apheresis procedure, and the colony-stimulating factor used (G-CSF). G-CSF drugs include filgrastim (Neupogen, Neulasta), and lenograstim (Graslopin).

Filgrastim is typically dosed in the 10 microgram/kg level for 45 days during the harvesting of stem cells. The documented adverse effects of filgrastim include splenic rupture (indicated by left upper abdominal or shoulder pain, risk 1 in 40000), Adult respiratory distress syndrome (ARDS), alveolar hemorrage, and allergic reactions (usually expressed in first 30 minutes, risk 1 in 300).[35][36][37] In addition, platelet and hemoglobin levels dip post-procedure, not returning to normal until one month.[37]

The question of whether geriatrics (patients over 65) react the same as patients under 65 has not been sufficiently examined. Coagulation issues and inflammation of atherosclerotic plaques are known to occur as a result of G-CSF injection. G-CSF has also been described to induce genetic changes in mononuclear cells of normal donors.[36] There is evidence that myelodysplasia (MDS) or acute myeloid leukaemia (AML) can be induced by GCSF in susceptible individuals.[38]

Blood was drawn peripherally in a majority of patients, but a central line to jugular/subclavian/femoral veins may be used in 16 percent of women and 4 percent of men. Adverse reactions during apheresis were experienced in 20 percent of women and 8 percent of men, these adverse events primarily consisted of numbness/tingling, multiple line attempts, and nausea.[37]

A study involving 2408 donors (1860 years) indicated that bone pain (primarily back and hips) as a result of filgrastim treatment is observed in 80 percent of donors by day 4 post-injection.[37] This pain responded to acetaminophen or ibuprofen in 65 percent of donors and was characterized as mild to moderate in 80 percent of donors and severe in 10 percent.[37] Bone pain receded post-donation to 26 percent of patients 2 days post-donation, 6 percent of patients one week post-donation, and <2 percent 1 year post-donation. Donation is not recommended for those with a history of back pain.[37] Other symptoms observed in more than 40 percent of donors include myalgia, headache, fatigue, and insomnia.[37] These symptoms all returned to baseline 1 month post-donation, except for some cases of persistent fatigue in 3 percent of donors.[37]

In one metastudy that incorporated data from 377 donors, 44 percent of patients reported having adverse side effects after peripheral blood HSCT.[38] Side effects included pain prior to the collection procedure as a result of GCSF injections, post-procedural generalized skeletal pain, fatigue and reduced energy.[38]

A study that surveyed 2408 donors found that serious adverse events (requiring prolonged hospitalization) occurred in 15 donors (at a rate of 0.6 percent), although none of these events were fatal.[37] Donors were not observed to have higher than normal rates of cancer with up to 48 years of follow up.[37] One study based on a survey of medical teams covered approximately 24,000 peripheral blood HSCT cases between 1993 and 2005, and found a serious cardiovascular adverse reaction rate of about 1 in 1500.[36] This study reported a cardiovascular-related fatality risk within the first 30 days HSCT of about 2 in 10000. For this same group, severe cardiovascular events were observed with a rate of about 1 in 1500. The most common severe adverse reactions were pulmonary edema/deep vein thrombosis, splenic rupture, and myocardial infarction. Haematological malignancy induction was comparable to that observed in the general population, with only 15 reported cases within 4 years.[36]

Georges Math, a French oncologist, performed the first European bone marrow transplant in November 1958 on five Yugoslavian nuclear workers whose own marrow had been damaged by irradiation caused by a criticality accident at the Vina Nuclear Institute, but all of these transplants were rejected.[39][40][41][42][43] Math later pioneered the use of bone marrow transplants in the treatment of leukemia.[43]

Stem cell transplantation was pioneered using bone-marrow-derived stem cells by a team at the Fred Hutchinson Cancer Research Center from the 1950s through the 1970s led by E. Donnall Thomas, whose work was later recognized with a Nobel Prize in Physiology or Medicine. Thomas' work showed that bone marrow cells infused intravenously could repopulate the bone marrow and produce new blood cells. His work also reduced the likelihood of developing a life-threatening complication called graft-versus-host disease.[44]

The first physician to perform a successful human bone marrow transplant on a disease other than cancer was Robert A. Good at the University of Minnesota in 1968.[45] In 1975, John Kersey, M.D., also of the University of Minnesota, performed the first successful bone marrow transplant to cure lymphoma. His patient, a 16-year-old-boy, is today the longest-living lymphoma transplant survivor.[46]

At the end of 2012, 20.2 million people had registered their willingness to be a bone marrow donor with one of the 67 registries from 49 countries participating in Bone Marrow Donors Worldwide. 17.9 million of these registered donors had been ABDR typed, allowing easy matching. A further 561,000 cord blood units had been received by one of 46 cord blood banks from 30 countries participating. The highest total number of bone marrow donors registered were those from the USA (8.0 million), and the highest number per capita were those from Cyprus (15.4 percent of the population).[47]

Within the United States, racial minority groups are the least likely to be registered and therefore the least likely to find a potentially life-saving match. In 1990, only six African-Americans were able to find a bone marrow match, and all six had common European genetic signatures.[48]

Africans are more genetically diverse than people of European descent, which means that more registrations are needed to find a match. Bone marrow and cord blood banks exist in South Africa, and a new program is beginning in Nigeria.[48] Many people belonging to different races are requested to donate as there is a shortage of donors in African, Mixed race, Latino, Aboriginal, and many other communities.

In 2007, a team of doctors in Berlin, Germany, including Gero Htter, performed a stem cell transplant for leukemia patient Timothy Ray Brown, who was also HIV-positive.[49] From 60 matching donors, they selected a [CCR5]-32 homozygous individual with two genetic copies of a rare variant of a cell surface receptor. This genetic trait confers resistance to HIV infection by blocking attachment of HIV to the cell. Roughly one in 1000 people of European ancestry have this inherited mutation, but it is rarer in other populations.[50][51] The transplant was repeated a year later after a leukemia relapse. Over three years after the initial transplant, and despite discontinuing antiretroviral therapy, researchers cannot detect HIV in the transplant recipient's blood or in various biopsies of his tissues.[52] Levels of HIV-specific antibodies have also declined, leading to speculation that the patient may have been functionally cured of HIV. However, scientists emphasise that this is an unusual case.[53] Potentially fatal transplant complications (the "Berlin patient" suffered from graft-versus-host disease and leukoencephalopathy) mean that the procedure could not be performed in others with HIV, even if sufficient numbers of suitable donors were found.[54][55]

In 2012, Daniel Kuritzkes reported results of two stem cell transplants in patients with HIV. They did not, however, use donors with the 32 deletion. After their transplant procedures, both were put on antiretroviral therapies, during which neither showed traces of HIV in their blood plasma and purified CD4 T cells using a sensitive culture method (less than 3 copies/mL). However, the virus was once again detected in both patients some time after the discontinuation of therapy.[56]

Since McAllister's 1997 report on a patient with multiple sclerosis (MS) who received a bone marrow transplant for CML,[57] over 600 reports have been published describing HSCTs performed primarily for MS.[58] These have been shown to "reduce or eliminate ongoing clinical relapses, halt further progression, and reduce the burden of disability in some patients" that have aggressive highly active MS, "in the absence of chronic treatment with disease-modifying agents".[58]

Clincs performing HSCT includes Northwestern University and Karolinska University Hospital.

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9thInternational Conference on Hematology

Date: November 02-04, 2017

Venue: Las Vegas, USA

Hematology 2016 has been designed with many interesting and informative scientific sessions; it includes all possible aspects of Hematology research.

Hematology

Erythrocytesare also known as red blood cells which carry oxygen to the body and collect carbon dioxide from the body by the use of hemoglobin and its life span of 120 days. along the side the leucocytes helps in protecting the healthy cells because the W.B.C (leucocytes) act as the defending cells in protecting the immune system from the foreign cells. Theseleucocytesare multipotent cells in bone marrow and there life span is of 3-4 days where the yellow blood cells are called as thrombocytes they are where small and irregular in shape they have life span of 5-9 days they are mostly seen in mammals they help in clotting of blood which are in fibrin form called as thrombosis these lead to heart stroke, blockage of blood in blood mostly in arms and legs. where C.B.C is known ascomplete blood countis done to know the number of cells in a body these are mainly done by lab technician presently they are been tested by automatic analyzer the high and low amount of cells will lead to many diseases. Decrease of R.B.C in the body these causes of anemia which leads to weakness, feeling of tired, shortness of breath and person will be noticeably pale. Formation of blood cellular components are called as Hematopoiesis and all the cellular blood components are derived from hematopoiesis stem cells in a healthy individual nearly 10111012new blood cells are produced these help in steady peripheral circulation. If there is a increases of R.B.C in the body these causes polycythemia these can be measured through hematocrit level.

Blood Disorders

Hemophilia Ais a genetic deficiency in clottingfactor VIII,which causes increased bleeding and usually affects males. About 70% of the time it is inherited as an X-linked recessive trait, but around 30% of cases arise from spontaneous mutations. Hemophilia B is ablood clottingdisorder caused by amutationof thefactor IXgene, leading to a deficiency of factor IX. It is the second-most common form ofhaemophilia, rarer thanhaemophilia A. It is sometimes calledChristmas disease, named afterStephen Christmas, the first patient described with this disease.In addition, the first report of its identification was published in the Christmas edition of theBritish Medical Journal.Hemophilia C is a mild form of haemophiliaaffecting both sexes. However, it predominantly occurs in Jews ofAshkenazidescent. It is the fourth most common coagulationdisorder aftervon Willebrand's diseaseandhaemophiliaAandB.In theUSAit is thought to affect 1 in 100,000 of the adult population, making it 10% as common as haemophilia A. Idiopathic thrombocytopenic purpura(ITP), also known asimmune thrombocytopenia,primary immune thrombocytopenia,primary immune thrombocytopenic purpuraorautoimmune thrombocytopenic purpura, is defined as isolated low platelet count (thrombocytopenia) with normalbone marrowand the absence of other causes of thrombocytopeniaVon Willebrand diseasesis the most common hereditarycoagulationabnormality described in humans. Platelets also called "thrombocytes" areblood cellswhose function (along with thecoagulation factors) is to stop bleeding by clumping and clogging blood vessel injuries.Platelets have nocell nucleus: Coagulation is highlyconservedthroughout biology; in allmammals, coagulation involves both a cellular (platelet) and aprotein(coagulation factor) component and these are occoured due togenetic blood disorders

Hematologic Malignancies

Lymphatic leukemiawhich effect the white blood cells(w.b.c) they are closely related to the lymphomas and some of them are unitary diseases which related to the adult T cells leukemia these come under the lymphoproliferative disorders. Mostly they involve in the B-cell sub type lymphocytes. The myeloid leukemia is preferred to the granulocyte precursor in the bone marrow and spinal cord and these arises the abnormal growth in the blood from tissues in the bone marrow. They are mainly related to the hematopoietic cells and these sub title into acute and chronic lymphoblastic leukemia. The acute leukemia is that rapidly producing immature blood cells as they are bulk number of cells healthy cells are not produced in bone marrow due this spill over the blood stream which spread to other body parts. Where as in chronic leukemia highly bulid of matured cells are formed but still abnormal white cells are formed these can not be treated immediately mostly seen in older people. The cancer which originate from white blood cells are called as lymphoma and this disorder is mainly seen inHodgkin lymphomathese diseases is treated by radiation and chemotherapy, orhematopoietic stem cell transplantation. The cancer which starts with in the cell are called as Non Hodgkin lymphocytes and these lymphocytes are of lymph nodes. The bone marrow which develops too many white blood cells leads tomultiple myleoma. The further details on malignance are been discussed inHematology oncology conference-2015.

Hematology and immunology

Blood groupsare of ABO type and but at present the Rh blood grouping of 50 well defined antigens in which 5 are more important they are D,C,c,E and e and Rh factors are of Rh positive and Rh negative which refers to the D-antigen. These D-antigen helps in prevention of erythroblast fetalis lacking of Rh antigen it defined as negative and presences of Rh antigen in blood leads to positive these leads to rh incompatibility. The prevention treatment of diseases related to the blood is called as the Hematology. The hematologists conduct works on cancer to. The disorder of immune system leading to hypersensitivity is called asClinical Immunologyand the abnormal growth of an infection are known as Inflammation and the arise of an abnormal immune response to the body or an immune suppression are known as Auto immune disorder. The stem cell therapy is used to treat or prevent a disease or a condition mostly Bone marrow stem cell therapy is seen and recently umbilical cord therapy Stem cell transplantation strategies remains a dangerous procedure with many possible complications; it is reserved for patients with life-threatening diseases.

Blood Transplantation

Theumbilical cordis a conduit between the developingembryoorfetusand theplacenta. The umbilical vein supplies the fetus with nutrient-richbloodfrom theplacenta The hematopoitic bone marrow transplant, the HSC are removed from a large bone of the donor, typically thepelvis, through a largeneedlethat reaches the center of the bone. Acute myeloid leukemia is a cancerof themyeloidline of blood cells, characterized by the rapid growth of abnormalwhite blood cellsthat accumulate in thebone marrowand interfere withthe production of normal blood cells and the Thrombosis is the formation of ablood clot inside ablood vessel, obstructing the flow ofbloodthrough thecirculatory system. TheHemostaticis a process which causes bleeding to stop, meaning to keep blood within a damaged blood vessel this is the first stage of wound healing. Metabolic syndromeis a disorder of energy utilization and storage, diagnosed by a co-occurrence of three out of five of the following medical conditions, obesity,elevated blood pressure,elevated fasting plasma glucose,high serum triglycerides, and lowhigh-density lipoprotein(HDL) levels. Metabolic syndrome increases the risk developingcardiovascular diseaseanddiabetes.

Diagnosis and Treatment

Palliative careis amultidisciplinary approachto specialisedmedical carefor people with seriousillnesses The spleen, similar in structure to a largelymph node, acts as a blood filter. Anticoagulants(antithrombics) are a class of drugs that work to prevent thecoagulation(clotting) of blood. Some anticoagulants are used in medical equipment, such astest tubes ,blood transfusionbags, andrenal dialysisequipment. Anvena cava filteris a type of vascular filter, amedicaldevice that is implanted byinterventional radiologistsor vascular surgeons into theinferior vena cavato presumably prevent life-threateningpulmonary emboliistherapyusingionizing radiation, generally as part of cancer treatmentto control or killmalignantcells. Radiation therapy may be curative in a number of types of cancer if they are localized to one area of the body. The subspecialty ofoncologythat focuses on radiotherapy is calledradiation oncology. Translational research is another term fortranslated researchandtranslational science, Applying knowledge from basic science is a major stumbling block in science, partially due to the compartmentalization within science. Targeted drug delivery is a method of deliveringmedicationto a patient in a manner that increases theconcentrationof the medication in some parts of the body relative to others.

New Drug Development in Haematology

The development of antibiotic resistance in particular stems from the drugs targeting only specific bacterial molecules. Because the drugisso specific, any mutation in these molecules will interfere with or negate its destructive effect, resulting in antibiotic resistance. Known asDrug deliveryConditions treated with combination therapy includetuberculosis,leprosy,cancer,malaria, andHIV/AIDS. One major benefit of combination therapies is that they reduce development ofdrug resistance, since a pathogen or tumor is less likely to have resistance to multiple drugs simultaneously.Artemisinin-based monotherapies for malaria are explicitly discouraged to avoid the problem of developing resistance to the newer treatment. Drug Induced Blood Disorders causes of sickle cell anemia,pale skin non steroids antiinflammatory drugswhich causes ulcers Using drug repositioning, pharmaceutical companies have achieved a number successes, for examplePfizer'sViagrainerectile dysfunctionandCelgene'sthalidomidein severe erythema nodosum leprosum. Smaller companies, including Ore Pharmaceuticals,Biovista, Numedicus,Melior Discoveryand SOM Biotech are also performing drug repositioning on a systematic basis. These companies use a combination of approaches including in silico biology and in vivo/in vitro experimentation to assess a compound and develop and confirm hypotheses concerning its usage for new indications.

Hematology Research

Lymphatic diseasesthis is a type of cancer of the lymphatic system. It can start almost any where in the body. It's believed to be caused by HIV, Epstein-Barr Syndrome, age and family history. Symptoms include weight loss, fever, swollen lymph nodes, night sweats, itchy skin, fatigue, chest pain, coughing and/or trouble swallowing. Thelymphatic systemis part of thecirculatory system, comprising a network oflymphatic vesselsthat carry a clear fluid called lymph directionally towards the heart. The lymphatic system was first described in the seventeenth century independently byOlaus RudbeckandThomas Bartholin. Unlike thecardiovascular systemthe lymphatic system is not a closed system. The human circulatory system processes an average of 20 litres ofbloodper day throughcapillary filtrationwhich removesplasmawhile leaving theblood cells. Roughly 17 litres of the filtered plasma get reabsorbed directly into the blood vessels, while the remaining 3 litres are left behind in theinterstitial fluid. One of the main functions of the lymph system is to provide an accessory return route to the blood for the surplus 3 litres. Lymphatic diseases are ofNon-Hodgkin's Lymphoma, Hodgkins. Thethymusis a specialized primarylymphoidorgan of theimmune system. Within the thymus,T cellsor Tlymphocytesmature. T cells are critical to theadaptive immune system, where the body adapts specifically to foreign invaders.One of the example of lymph node development. Formation oflymph nodeinto the tumor which lead to cancer called oncology.

Various Aspects of Haematology

Pediatric Haematology and Oncologyis an internationalpeer-reviewedmedical journalthat covers all aspects ofpediatrichematologyandoncology. The journal covers immunology, pathology, and pharmacology in relation to blood diseases and cancer in children and shows how basic experimental research can contribute to the understanding of clinical problems. Physicians specialized in hematology are known ashematologistsorhaematologists. Their routine work mainly includes the care and treatment of patients with hematological diseases, although some may also work at the hematology laboratory viewingblood filmsandbone marrowslides under themicroscope, interpreting various hematological test results andblood clotting testresults. In some institutions, hematologists also manage the hematology laboratory. Physicians who work in hematology laboratories, and most commonly manage them, are pathologists specialized in the diagnosis of hematological diseases, referred to as hematopathologistsorhaematopathologists.Experimental Hematologyis apeer-reviewedmedical journalofhematology, which publishesoriginal researcharticles and reviews, as well as the abstracts of the annual proceedings of theSociety for Hematology and Stem Cells and they should be done under theHematology guidlines.

Blood Based Products

Ablood substituteis a substance used to mimic and fulfill some functions ofbiologicalblood. It aims to provide an alternative toblood transfusion, which is transferring blood orblood-based productsfrom one person into another. Thus far, there are no well-acceptedoxygen-carryingblood substitutes, which is the typical objective of ared blood celltransfusion; however, there are widely available non-bloodvolume expandersfor cases where only volume restoration is required. These are helping doctors and surgeons avoid the risks of disease transmission and immune suppression, address the chronic blood donor shortage, and address the concerns of Jehovah's Witnesses and others who have religious objections to receiving transfused blood.Pathogen reductionusing riboflavin and UV lightis a method by which infectiouspathogensinblood for transfusionare inactivated by addingriboflavinand irradiating withUV light. This method reduces the infectious levels of disease-causing agents that may be found in donated blood components, while still maintaining good quality blood components for transfusion. This type of approach to increase blood safety is also known as pathogen inactivation in the industry. Anartificial cellorminimal cellis an engineered particle that mimics one or many functions of abiological cell. The term does not refer to a specific physical entity, but rather to the idea that certain functions or structures of biological cells can be replaced or supplemented with a synthetic entity. Often, artificial cells are biological or polymeric membranes which enclose biologically active materials. As such,nanoparticles,liposomes,polymersomes, microcapsules and a number of other particles have qualified as artificial cells.Manufacturing of semi synthetic products of drugs are known as therapeutic biological products.Anticoagulants(antithrombics) are a class of drugs that work to prevent thecoagulation(clotting) of blood. Such substances occur naturally in leeches and blood-sucking insects.

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Open Access

Article

The Arabidopsis CERK1associated kinase PBL27 connects chitin perception to MAPK activation

These authors contributed equally to this work as first authors

These authors contributed equally to this work as third authors

Chitin receptor CERK1 transmits immune signals to the intracellular MAPK cascade in plants. This occurs via phosphorylation of MAPKKK5 by the CERK1associated kinase PBL27, providing a missing link between pathogen perception and signaling output.

Chitin receptor CERK1 transmits immune signals to the intracellular MAPK cascade in plants. This occurs via phosphorylation of MAPKKK5 by the CERK1associated kinase PBL27, providing a missing link between pathogen perception and signaling output.

CERK1associated kinase PBL27 interacts with MAPKKK5 at the plasma membrane.

Chitin perception induces disassociation of PBL27 and MAPKKK5.

PBL27 functions as a MAPKKK kinase.

Phosphorylation of MAPKKK5 by PBL27 is enhanced upon phosphorylation of PBL27 by CERK1.

Phosphorylation of MAPKKK5 by PBL27 is required for chitininduced MAPK activation in planta.

Kenta Yamada, Koji Yamaguchi, Tomomi Shirakawa, Hirofumi Nakagami, Akira Mine, Kazuya Ishikawa, Masayuki Fujiwara, Mari Narusaka, Yoshihiro Narusaka, Kazuya Ichimura, Yuka Kobayashi, Hidenori Matsui, Yuko Nomura, Mika Nomoto, Yasuomi Tada, Yoichiro Fukao, Tamo Fukamizo, Kenichi Tsuda, Ken Shirasu, Naoto Shibuya, Tsutomu Kawasaki

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Do you ever wonder what makes up blood? Unless you need to have blood drawn, donate it or have to stop its flow after an injury, you probably don't think much about it. But blood is the most commonly tested part of the body, and it is truly the river of life. Every cell in the body gets its nutrients from blood. Understanding blood will help you as your doctor explains the results of your blood tests. In addition, you will learn amazing things about this incredible fluid and the cells in it.

Blood is a mixture of two components: cells and plasma. The heart pumps blood through the arteries, capillaries and veins to provide oxygen and nutrients to every cell of the body. The blood also carries away waste products.

The adult human body contains approximately 5 liters (5.3 quarts) of blood; it makes up 7 to 8 percent of a person's body weight. Approximately 2.75 to 3 liters of blood is plasma and the rest is the cellular portion.

Plasma is the liquid portion of the blood. Blood cells like red blood cells float in the plasma. Also dissolved in plasma are electrolytes, nutrients and vitamins (absorbed from the intestines or produced by the body), hormones, clotting factors, and proteins such as albumin and immunoglobulins (antibodies to fight infection). Plasma distributes the substances it contains as it circulates throughout the body.

The cellular portion of blood contains red blood cells (RBCs), white blood cells (WBCs) and platelets. The RBCs carry oxygen from the lungs; the WBCs help to fight infection; and platelets are parts of cells that the body uses for clotting. All blood cells are produced in the bone marrow. As children, most of our bones produce blood. As we age this gradually diminishes to just the bones of the spine (vertebrae), breastbone (sternum), ribs, pelvis and small parts of the upper arm and leg. Bone marrow that actively produces blood cells is called red marrow, and bone marrow that no longer produces blood cells is called yellow marrow. The process by which the body produces blood is called hematopoiesis. All blood cells (RBCs, WBCs and platelets) come from the same type of cell, called the pluripotential hematopoietic stem cell. This group of cells has the potential to form any of the different types of blood cells and also to reproduce itself. This cell then forms committed stem cells that will form specific types of blood cells.

We'll learn more about red blood cells in detail next.

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Muscle is a soft tissue found in most animals. Muscle cells contain protein filaments of actin and myosin that slide past one another, producing a contraction that changes both the length and the shape of the cell. Muscles function to produce force and motion. They are primarily responsible for maintaining and changing posture, locomotion, as well as movement of internal organs, such as the contraction of the heart and the movement of food through the digestive system via peristalsis.

Muscle tissues are derived from the mesodermal layer of embryonic germ cells in a process known as myogenesis. There are three types of muscle, skeletal or striated, cardiac, and smooth. Muscle action can be classified as being either voluntary or involuntary. Cardiac and smooth muscles contract without conscious thought and are termed involuntary, whereas the skeletal muscles contract upon command.[1] Skeletal muscles in turn can be divided into fast and slow twitch fibers.

Muscles are predominantly powered by the oxidation of fats and carbohydrates, but anaerobic chemical reactions are also used, particularly by fast twitch fibers. These chemical reactions produce adenosine triphosphate (ATP) molecules that are used to power the movement of the myosin heads.[2]

The term muscle is derived from the Latin musculus meaning "little mouse" perhaps because of the shape of certain muscles or because contracting muscles look like mice moving under the skin.[3][4]

The anatomy of muscles includes gross anatomy, which comprises all the muscles of an organism, and microanatomy, which comprises the structures of a single muscle.

Muscle tissue is a soft tissue, and is one of the four fundamental types of tissue present in animals. There are three types of muscle tissue recognized in vertebrates:

Cardiac and skeletal muscles are "striated" in that they contain sarcomeres that are packed into highly regular arrangements of bundles; the myofibrils of smooth muscle cells are not arranged in sarcomeres and so are not striated. While the sarcomeres in skeletal muscles are arranged in regular, parallel bundles, cardiac muscle sarcomeres connect at branching, irregular angles (called intercalated discs). Striated muscle contracts and relaxes in short, intense bursts, whereas smooth muscle sustains longer or even near-permanent contractions.

Skeletal (voluntary) muscle is further divided into two broad types: slow twitch and fast twitch:

The density of mammalian skeletal muscle tissue is about 1.06kg/liter.[8] This can be contrasted with the density of adipose tissue (fat), which is 0.9196kg/liter.[9] This makes muscle tissue approximately 15% denser than fat tissue.

All muscles are derived from paraxial mesoderm. The paraxial mesoderm is divided along the embryo's length into somites, corresponding to the segmentation of the body (most obviously seen in the vertebral column.[10] Each somite has 3 divisions, sclerotome (which forms vertebrae), dermatome (which forms skin), and myotome (which forms muscle). The myotome is divided into two sections, the epimere and hypomere, which form epaxial and hypaxial muscles, respectively. The only epaxial muscles in humans are the erector spinae and small intervertebral muscles, and are innervated by the dorsal rami of the spinal nerves. All other muscles, including those of the limbs are hypaxial, and inervated by the ventral rami of the spinal nerves.[10]

During development, myoblasts (muscle progenitor cells) either remain in the somite to form muscles associated with the vertebral column or migrate out into the body to form all other muscles. Myoblast migration is preceded by the formation of connective tissue frameworks, usually formed from the somatic lateral plate mesoderm. Myoblasts follow chemical signals to the appropriate locations, where they fuse into elongate skeletal muscle cells.[10]

Skeletal muscles are sheathed by a tough layer of connective tissue called the epimysium. The epimysium anchors muscle tissue to tendons at each end, where the epimysium becomes thicker and collagenous. It also protects muscles from friction against other muscles and bones. Within the epimysium are multiple bundles called fascicles, each of which contains 10 to 100 or more muscle fibers collectively sheathed by a perimysium. Besides surrounding each fascicle, the perimysium is a pathway for nerves and the flow of blood within the muscle. The threadlike muscle fibers are the individual muscle cells (myocytes), and each cell is encased within its own endomysium of collagen fibers. Thus, the overall muscle consists of fibers (cells) that are bundled into fascicles, which are themselves grouped together to form muscles. At each level of bundling, a collagenous membrane surrounds the bundle, and these membranes support muscle function both by resisting passive stretching of the tissue and by distributing forces applied to the muscle.[11] Scattered throughout the muscles are muscle spindles that provide sensory feedback information to the central nervous system. (This grouping structure is analogous to the organization of nerves which uses epineurium, perineurium, and endoneurium).

This same bundles-within-bundles structure is replicated within the muscle cells. Within the cells of the muscle are myofibrils, which themselves are bundles of protein filaments. The term "myofibril" should not be confused with "myofiber", which is a simply another name for a muscle cell. Myofibrils are complex strands of several kinds of protein filaments organized together into repeating units called sarcomeres. The striated appearance of both skeletal and cardiac muscle results from the regular pattern of sarcomeres within their cells. Although both of these types of muscle contain sarcomeres, the fibers in cardiac muscle are typically branched to form a network. Cardiac muscle fibers are interconnected by intercalated discs,[12] giving that tissue the appearance of a syncytium.

The filaments in a sarcomere are composed of actin and myosin.

The gross anatomy of a muscle is the most important indicator of its role in the body. There is an important distinction seen between pennate muscles and other muscles. In most muscles, all the fibers are oriented in the same direction, running in a line from the origin to the insertion. However, In pennate muscles, the individual fibers are oriented at an angle relative to the line of action, attaching to the origin and insertion tendons at each end. Because the contracting fibers are pulling at an angle to the overall action of the muscle, the change in length is smaller, but this same orientation allows for more fibers (thus more force) in a muscle of a given size. Pennate muscles are usually found where their length change is less important than maximum force, such as the rectus femoris.

Skeletal muscle is arranged in discrete muscles, an example of which is the biceps brachii (biceps). The tough, fibrous epimysium of skeletal muscle is both connected to and continuous with the tendons. In turn, the tendons connect to the periosteum layer surrounding the bones, permitting the transfer of force from the muscles to the skeleton. Together, these fibrous layers, along with tendons and ligaments, constitute the deep fascia of the body.

The muscular system consists of all the muscles present in a single body. There are approximately 650 skeletal muscles in the human body,[13] but an exact number is difficult to define. The difficulty lies partly in the fact that different sources group the muscles differently and partly in that some muscles, such as palmaris longus, are not always present.

A muscular slip is a narrow length of muscle that acts to augment a larger muscle or muscles.

The muscular system is one component of the musculoskeletal system, which includes not only the muscles but also the bones, joints, tendons, and other structures that permit movement.

The three types of muscle (skeletal, cardiac and smooth) have significant differences. However, all three use the movement of actin against myosin to create contraction. In skeletal muscle, contraction is stimulated by electrical impulses transmitted by the nerves, the motoneurons (motor nerves) in particular. Cardiac and smooth muscle contractions are stimulated by internal pacemaker cells which regularly contract, and propagate contractions to other muscle cells they are in contact with. All skeletal muscle and many smooth muscle contractions are facilitated by the neurotransmitter acetylcholine.

The action a muscle generates is determined by the origin and insertion locations. The cross-sectional area of a muscle (rather than volume or length) determines the amount of force it can generate by defining the number of sarcomeres which can operate in parallel.[citation needed] The amount of force applied to the external environment is determined by lever mechanics, specifically the ratio of in-lever to out-lever. For example, moving the insertion point of the biceps more distally on the radius (farther from the joint of rotation) would increase the force generated during flexion (and, as a result, the maximum weight lifted in this movement), but decrease the maximum speed of flexion. Moving the insertion point proximally (closer to the joint of rotation) would result in decreased force but increased velocity. This can be most easily seen by comparing the limb of a mole to a horse - in the former, the insertion point is positioned to maximize force (for digging), while in the latter, the insertion point is positioned to maximize speed (for running).

Muscular activity accounts for much of the body's energy consumption. All muscle cells produce adenosine triphosphate (ATP) molecules which are used to power the movement of the myosin heads. Muscles have a short-term store of energy in the form of creatine phosphate which is generated from ATP and can regenerate ATP when needed with creatine kinase. Muscles also keep a storage form of glucose in the form of glycogen. Glycogen can be rapidly converted to glucose when energy is required for sustained, powerful contractions. Within the voluntary skeletal muscles, the glucose molecule can be metabolized anaerobically in a process called glycolysis which produces two ATP and two lactic acid molecules in the process (note that in aerobic conditions, lactate is not formed; instead pyruvate is formed and transmitted through the citric acid cycle). Muscle cells also contain globules of fat, which are used for energy during aerobic exercise. The aerobic energy systems take longer to produce the ATP and reach peak efficiency, and requires many more biochemical steps, but produces significantly more ATP than anaerobic glycolysis. Cardiac muscle on the other hand, can readily consume any of the three macronutrients (protein, glucose and fat) aerobically without a 'warm up' period and always extracts the maximum ATP yield from any molecule involved. The heart, liver and red blood cells will also consume lactic acid produced and excreted by skeletal muscles during exercise.

At rest, skeletal muscle consumes 54.4 kJ/kg(13.0kcal/kg) per day. This is larger than adipose tissue (fat) at 18.8kJ/kg (4.5kcal/kg), and bone at 9.6kJ/kg (2.3kcal/kg).[14]

The efferent leg of the peripheral nervous system is responsible for conveying commands to the muscles and glands, and is ultimately responsible for voluntary movement. Nerves move muscles in response to voluntary and autonomic (involuntary) signals from the brain. Deep muscles, superficial muscles, muscles of the face and internal muscles all correspond with dedicated regions in the primary motor cortex of the brain, directly anterior to the central sulcus that divides the frontal and parietal lobes.

In addition, muscles react to reflexive nerve stimuli that do not always send signals all the way to the brain. In this case, the signal from the afferent fiber does not reach the brain, but produces the reflexive movement by direct connections with the efferent nerves in the spine. However, the majority of muscle activity is volitional, and the result of complex interactions between various areas of the brain.

Nerves that control skeletal muscles in mammals correspond with neuron groups along the primary motor cortex of the brain's cerebral cortex. Commands are routed though the basal ganglia and are modified by input from the cerebellum before being relayed through the pyramidal tract to the spinal cord and from there to the motor end plate at the muscles. Along the way, feedback, such as that of the extrapyramidal system contribute signals to influence muscle tone and response.

Deeper muscles such as those involved in posture often are controlled from nuclei in the brain stem and basal ganglia.

The afferent leg of the peripheral nervous system is responsible for conveying sensory information to the brain, primarily from the sense organs like the skin. In the muscles, the muscle spindles convey information about the degree of muscle length and stretch to the central nervous system to assist in maintaining posture and joint position. The sense of where our bodies are in space is called proprioception, the perception of body awareness. More easily demonstrated than explained, proprioception is the "unconscious" awareness of where the various regions of the body are located at any one time. This can be demonstrated by anyone closing their eyes and waving their hand around. Assuming proper proprioceptive function, at no time will the person lose awareness of where the hand actually is, even though it is not being detected by any of the other senses.

Several areas in the brain coordinate movement and position with the feedback information gained from proprioception. The cerebellum and red nucleus in particular continuously sample position against movement and make minor corrections to assure smooth motion.

The efficiency of human muscle has been measured (in the context of rowing and cycling) at 18% to 26%. The efficiency is defined as the ratio of mechanical work output to the total metabolic cost, as can be calculated from oxygen consumption. This low efficiency is the result of about 40% efficiency of generating ATP from food energy, losses in converting energy from ATP into mechanical work inside the muscle, and mechanical losses inside the body. The latter two losses are dependent on the type of exercise and the type of muscle fibers being used (fast-twitch or slow-twitch). For an overall efficiency of 20 percent, one watt of mechanical power is equivalent to 4.3 kcal per hour. For example, one manufacturer of rowing equipment calibrates its rowing ergometer to count burned calories as equal to four times the actual mechanical work, plus 300 kcal per hour,[15] this amounts to about 20 percent efficiency at 250 watts of mechanical output. The mechanical energy output of a cyclic contraction can depend upon many factors, including activation timing, muscle strain trajectory, and rates of force rise & decay. These can be synthesized experimentally using work loop analysis.

A display of "strength" (e.g. lifting a weight) is a result of three factors that overlap: physiological strength (muscle size, cross sectional area, available crossbridging, responses to training), neurological strength (how strong or weak is the signal that tells the muscle to contract), and mechanical strength (muscle's force angle on the lever, moment arm length, joint capabilities).

Vertebrate muscle typically produces approximately 2533N (5.67.4lbf) of force per square centimeter of muscle cross-sectional area when isometric and at optimal length.[16] Some invertebrate muscles, such as in crab claws, have much longer sarcomeres than vertebrates, resulting in many more sites for actin and myosin to bind and thus much greater force per square centimeter at the cost of much slower speed. The force generated by a contraction can be measured non-invasively using either mechanomyography or phonomyography, be measured in vivo using tendon strain (if a prominent tendon is present), or be measured directly using more invasive methods.

The strength of any given muscle, in terms of force exerted on the skeleton, depends upon length, shortening speed, cross sectional area, pennation, sarcomere length, myosin isoforms, and neural activation of motor units. Significant reductions in muscle strength can indicate underlying pathology, with the chart at right used as a guide.

Since three factors affect muscular strength simultaneously and muscles never work individually, it is misleading to compare strength in individual muscles, and state that one is the "strongest". But below are several muscles whose strength is noteworthy for different reasons.

Humans are genetically predisposed with a larger percentage of one type of muscle group over another. An individual born with a greater percentage of Type I muscle fibers would theoretically be more suited to endurance events, such as triathlons, distance running, and long cycling events, whereas a human born with a greater percentage of Type II muscle fibers would be more likely to excel at sprinting events such as 100 meter dash.[citation needed]

Exercise is often recommended as a means of improving motor skills, fitness, muscle and bone strength, and joint function. Exercise has several effects upon muscles, connective tissue, bone, and the nerves that stimulate the muscles. One such effect is muscle hypertrophy, an increase in size. This is used in bodybuilding.

Various exercises require a predominance of certain muscle fiber utilization over another. Aerobic exercise involves long, low levels of exertion in which the muscles are used at well below their maximal contraction strength for long periods of time (the most classic example being the marathon). Aerobic events, which rely primarily on the aerobic (with oxygen) system, use a higher percentage of Type I (or slow-twitch) muscle fibers, consume a mixture of fat, protein and carbohydrates for energy, consume large amounts of oxygen and produce little lactic acid. Anaerobic exercise involves short bursts of higher intensity contractions at a much greater percentage of their maximum contraction strength. Examples of anaerobic exercise include sprinting and weight lifting. The anaerobic energy delivery system uses predominantly Type II or fast-twitch muscle fibers, relies mainly on ATP or glucose for fuel, consumes relatively little oxygen, protein and fat, produces large amounts of lactic acid and can not be sustained for as long a period as aerobic exercise. Many exercises are partially aerobic and partially anaerobic; for example, soccer and rock climbing involve a combination of both.

The presence of lactic acid has an inhibitory effect on ATP generation within the muscle; though not producing fatigue, it can inhibit or even stop performance if the intracellular concentration becomes too high. However, long-term training causes neovascularization within the muscle, increasing the ability to move waste products out of the muscles and maintain contraction. Once moved out of muscles with high concentrations within the sarcomere, lactic acid can be used by other muscles or body tissues as a source of energy, or transported to the liver where it is converted back to pyruvate. In addition to increasing the level of lactic acid, strenuous exercise causes the loss of potassium ions in muscle and causing an increase in potassium ion concentrations close to the muscle fibres, in the interstitium. Acidification by lactic acid may allow recovery of force so that acidosis may protect against fatigue rather than being a cause of fatigue.[18]

Delayed onset muscle soreness is pain or discomfort that may be felt one to three days after exercising and generally subsides two to three days later. Once thought to be caused by lactic acid build-up, a more recent theory is that it is caused by tiny tears in the muscle fibers caused by eccentric contraction, or unaccustomed training levels. Since lactic acid disperses fairly rapidly, it could not explain pain experienced days after exercise.[19]

Independent of strength and performance measures, muscles can be induced to grow larger by a number of factors, including hormone signaling, developmental factors, strength training, and disease. Contrary to popular belief, the number of muscle fibres cannot be increased through exercise. Instead, muscles grow larger through a combination of muscle cell growth as new protein filaments are added along with additional mass provided by undifferentiated satellite cells alongside the existing muscle cells.[13]

Biological factors such as age and hormone levels can affect muscle hypertrophy. During puberty in males, hypertrophy occurs at an accelerated rate as the levels of growth-stimulating hormones produced by the body increase. Natural hypertrophy normally stops at full growth in the late teens. As testosterone is one of the body's major growth hormones, on average, men find hypertrophy much easier to achieve than women. Taking additional testosterone or other anabolic steroids will increase muscular hypertrophy.

Muscular, spinal and neural factors all affect muscle building. Sometimes a person may notice an increase in strength in a given muscle even though only its opposite has been subject to exercise, such as when a bodybuilder finds her left biceps stronger after completing a regimen focusing only on the right biceps. This phenomenon is called cross education.[citation needed]

Inactivity and starvation in mammals lead to atrophy of skeletal muscle, a decrease in muscle mass that may be accompanied by a smaller number and size of the muscle cells as well as lower protein content.[20] Muscle atrophy may also result from the natural aging process or from disease.

In humans, prolonged periods of immobilization, as in the cases of bed rest or astronauts flying in space, are known to result in muscle weakening and atrophy. Atrophy is of particular interest to the manned spaceflight community, because the weightlessness experienced in spaceflight results is a loss of as much as 30% of mass in some muscles.[21][22] Such consequences are also noted in small hibernating mammals like the golden-mantled ground squirrels and brown bats.[23]

During aging, there is a gradual decrease in the ability to maintain skeletal muscle function and mass, known as sarcopenia. The exact cause of sarcopenia is unknown, but it may be due to a combination of the gradual failure in the "satellite cells" that help to regenerate skeletal muscle fibers, and a decrease in sensitivity to or the availability of critical secreted growth factors that are necessary to maintain muscle mass and satellite cell survival. Sarcopenia is a normal aspect of aging, and is not actually a disease state yet can be linked to many injuries in the elderly population as well as decreasing quality of life.[24]

There are also many diseases and conditions that cause muscle atrophy. Examples include cancer and AIDS, which induce a body wasting syndrome called cachexia. Other syndromes or conditions that can induce skeletal muscle atrophy are congestive heart disease and some diseases of the liver.

Neuromuscular diseases are those that affect the muscles and/or their nervous control. In general, problems with nervous control can cause spasticity or paralysis, depending on the location and nature of the problem. A large proportion of neurological disorders, ranging from cerebrovascular accident (stroke) and Parkinson's disease to CreutzfeldtJakob disease, can lead to problems with movement or motor coordination.

Symptoms of muscle diseases may include weakness, spasticity, myoclonus and myalgia. Diagnostic procedures that may reveal muscular disorders include testing creatine kinase levels in the blood and electromyography (measuring electrical activity in muscles). In some cases, muscle biopsy may be done to identify a myopathy, as well as genetic testing to identify DNA abnormalities associated with specific myopathies and dystrophies.

A non-invasive elastography technique that measures muscle noise is undergoing experimentation to provide a way of monitoring neuromuscular disease. The sound produced by a muscle comes from the shortening of actomyosin filaments along the axis of the muscle. During contraction, the muscle shortens along its longitudinal axis and expands across the transverse axis, producing vibrations at the surface.[25]

The evolutionary origin of muscle cells in metazoans is a highly debated topic. In one line of thought scientists have believed that muscle cells evolved once and thus all animals with muscles cells have a single common ancestor. In the other line of thought, scientists believe muscles cells evolved more than once and any morphological or structural similarities are due to convergent evolution and genes that predate the evolution of muscle and even the mesoderm - the germ layer from which many scientists believe true muscle cells derive.

Schmid and Seipel argue that the origin of muscle cells is a monophyletic trait that occurred concurrently with the development of the digestive and nervous systems of all animals and that this origin can be traced to a single metazoan ancestor in which muscle cells are present. They argue that molecular and morphological similarities between the muscles cells in cnidaria and ctenophora are similar enough to those of bilaterians that there would be one ancestor in metazoans from which muscle cells derive. In this case, Schmid and Seipel argue that the last common ancestor of bilateria, ctenophora, and cnidaria was a triploblast or an organism with three germ layers and that diploblasty, meaning an organism with two germ layers, evolved secondarily due to their observation of the lack of mesoderm or muscle found in most cnidarians and ctenophores. By comparing the morphology of cnidarians and ctenophores to bilaterians, Schmid and Seipel were able to conclude that there were myoblast-like structures in the tentacles and gut of some species of cnidarians and in the tentacles of ctenophores. Since this is a structure unique to muscle cells, these scientists determined based on the data collected by their peers that this is a marker for striated muscles similar to that observed in bilaterians. The authors also remark that the muscle cells found in cnidarians and ctenophores are often contests due to the origin of these muscle cells being the ectoderm rather than the mesoderm or mesendoderm. The origin of true muscles cells is argued by others to be the endoderm portion of the mesoderm and the endoderm. However, Schmid and Seipel counter this skepticism about whether or not the muscle cells found in ctenophores and cnidarians are true muscle cells by considering that cnidarians develop through a medusa stage and polyp stage. They observe that in the hydrozoan medusa stage there is a layer of cells that separate from the distal side of the ectoderm to form the striated muscle cells in a way that seems similar to that of the mesoderm and call this third separated layer of cells the ectocodon. They also argue that not all muscle cells are derived from the mesendoderm in bilaterians with key examples being that in both the eye muscles of vertebrates and the muscles of spiralians these cells derive from the ectodermal mesoderm rather than the endodermal mesoderm. Furthermore, Schmid and Seipel argue that since myogenesis does occur in cnidarians with the help of molecular regulatory elements found in the specification of muscles cells in bilaterians that there is evidence for a single origin for striated muscle.[26]

In contrast to this argument for a single origin of muscle cells, Steinmetz et al. argue that molecular markers such as the myosin II protein used to determine this single origin of striated muscle actually predate the formation of muscle cells. This author uses an example of the contractile elements present in the porifera or sponges that do truly lack this striated muscle containing this protein. Furthermore, Steinmetz et al. present evidence for a polyphyletic origin of striated muscle cell development through their analysis of morphological and molecular markers that are present in bilaterians and absent in cnidarians, ctenophores, and bilaterians. Steimetz et al. showed that the traditional morphological and regulatory markers such as actin, the ability to couple myosin side chains phosphorylation to higher concentrations of the positive concentrations of calcium, and other MyHC elements are present in all metazoans not just the organisms that have been shown to have muscle cells. Thus, the usage of any of these structural or regulatory elements in determining whether or not the muscle cells of the cnidarians and ctenophores are similar enough to the muscle cells of the bilaterians to confirm a single lineage is questionable according to Steinmetz et al. Furthermore, Steinmetz et al. explain that the orthologues of the MyHc genes that have been used to hypothesize the origin of striated muscle occurred through a gene duplication event that predates the first true muscle cells (meaning striated muscle), and they show that the MyHc genes are present in the sponges that have contractile elements but no true muscle cells. Furthermore, Steinmetz et all showed that the localization of this duplicated set of genes that serve both the function of facilitating the formation of striated muscle genes and cell regulation and movement genes were already separated into striated myhc and non-muscle myhc. This separation of the duplicated set of genes is shown through the localization of the striated myhc to the contractile vacuole in sponges while the non-muscle myhc was more diffusely expressed during developmental cell shape and change. Steinmetz et al. found a similar pattern of localization in cnidarians with except with the cnidarian N. vectensis having this striated muscle marker present in the smooth muscle of the digestive track. Thus, Steinmetz et al. argue that the pleisiomorphic trait of the separated orthologues of myhc cannot be used to determine the monophylogeny of muscle, and additionally argue that the presence of a striated muscle marker in the smooth muscle of this cnidarian shows a fundamentally different mechanism of muscle cell development and structure in cnidarians.[27]

Steinmetz et al. continue to argue for multiple origins of striated muscle in the metazoans by explaining that a key set of genes used to form the troponin complex for muscle regulation and formation in bilaterians is missing from the cnidarians and ctenophores, and of 47 structural and regulatory proteins observed, Steinmetz et al. were not able to find even on unique striated muscle cell protein that was expressed in both cnidarians and bilaterians. Furthermore, the Z-disc seemed to have evolved differently even within bilaterians and there is a great deal diversity of proteins developed even between this clade, showing a large degree of radiation for muscle cells. Through this divergence of the Z-disc, Steimetz et al. argue that there are only four common protein components that were present in all bilaterians muscle ancestors and that of these for necessary Z-disc components only an actin protein that they have already argued is an uninformative marker through its pleisiomorphic state is present in cnidarians. Through further molecular marker testing, Steinmetz et al. observe that non-bilaterians lack many regulatory and structural components necessary for bilaterians muscle formation and do not find any unique set of proteins to both bilaterians and cnidarians and ctenophores that are not present in earlier, more primitive animals such as the sponges and amoebozoans. Through this analysis the authors conclude that due to the lack of elements that bilaterians muscles are dependent on for structure and usage, nonbilaterian muscles must be of a different origin with a different set regulatory and structural proteins.[27]

In another take on the argument, Andrikou and Arnone use the newly available data on gene regulatory networks to look at how the hierarchy of genes and morphogens and other mechanism of tissue specification diverge and are similar among early deuterostomes and protostomes. By understanding not only what genes are present in all bilaterians but also the time and place of deployment of these genes, Andrikou and Arnone discuss a deeper understanding of the evolution of myogenesis.[28]

In their paper Andrikou and Arnone argue that to truly understand the evolution of muscle cells the function of transcriptional regulators must be understood in the context of other external and internal interactions. Through their analysis, Andrikou and Arnone found that there were conserved orthologues of the gene regulatory network in both invertebrate bilaterians and in cnidarians. They argue that having this common, general regulatory circuit allowed for a high degree of divergence from a single well functioning network. Andrikou and Arnone found that the orthologues of genes found in vertebrates had been changed through different types of structural mutations in the invertebrate deuterostomes and protostomes, and they argue that these structural changes in the genes allowed for a large divergence of muscle function and muscle formation in these species. Andrikou and Arnone were able to recognize not only any difference due to mutation in the genes found in vertebrates and invertebrates but also the integration of species specific genes that could also cause divergence from the original gene regulatory network function. Thus, although a common muscle patterning system has been determined, they argue that this could be due to a more ancestral gene regulatory network being coopted several times across lineages with additional genes and mutations causing very divergent development of muscles. Thus it seems that myogenic patterning framework may be an ancestral trait. However, Andrikou and Arnone explain that the basic muscle patterning structure must also be considered in combination with the cis regulatory elements present at different times during development. In contrast with the high level of gene family apparatuses structure, Andrikou and Arnone found that the cis regulatory elements were not well conserved both in time and place in the network which could show a large degree of divergence in the formation of muscle cells. Through this analysis, it seems that the myogenic GRN is an ancestral GRN with actual changes in myogenic function and structure possibly being linked to later coopts of genes at different times and places.[28]

Evolutionarily, specialized forms of skeletal and cardiac muscles predated the divergence of the vertebrate/arthropod evolutionary line.[29][dead link] This indicates that these types of muscle developed in a common ancestor sometime before 700 million years ago (mya). Vertebrate smooth muscle was found to have evolved independently from the skeletal and cardiac muscle types.

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14th International Conference on Clinical & Experimental Cardiology is among the Worlds leading Scientific Conference. The three day event on Cardiology practices will host 60+ Scientific and technical sessions and sub-sessions on cutting edge research and latest research innovations in the field of cardiology and cardiac surgeries across the globe. This year annual Cardiology conference will comprises of 14 major sessions designed to offer comprehensive sessions that address current issues in various field of Cardiology. The attendees can find some- Exclusive Sessions and Panel discussions on latest innovations in Cardiac Surgeries and Heart Failure. This is the excellent platform to showcase the latest products and formulations in the field of Cardiology.

Theme:The Science of Heart Discovery

Scientific sessions:

Track: Clinical Cardiology

Cardiology is a branch of medicine dealing with disorders of the heart be it human or animal. The field includes medical diagnosis and treatment of congenital heart defects, coronary artery disease, heart failure, valvular heart disease and electrophysiology. Physicians who specialize in this field of medicine are called cardiologists, a specialty of internal medicine. Pediatric cardiologists are pediatricians who specialize in cardiology. Physicians who specialize in cardiac surgery are called cardiothoracic surgeons or cardiac surgeons, a specialty of general surgery. Clinical Cardiology is an American journal about Cardiology founded in 1978. It provides a forum for the coordination of clinical research in diagnostics, cardiovascular medicine and cardiovascular surgery.

RelevantConferences:9thArrhythmiasConference July 14-15, 2016 Brisbane, Australia;CardioVascular MedicineConference August 01-02, 2016 Manchester, UK;EchocardiographyConference July 18-19, 2016 Berlin, Germany; 8th Global Cardiologists Annual Meeting July 18-20, 2016 Berlin, Germany; Atherosclerosis and Clinical Cardiology Conference July 11-12, 2016 Philadelphia, Pennsylvania, USA; Ischemic Heart Diseases Conference October 20-21, 2016 Chicago, Illinois, USA; Hypertension & Health Care Conference August 11-12, 2016 Toronto, Canada; 11thCardiac Conference September 12-13, 2016 Philadelphia, Pennsylvania, USA; 13thEuropean Cardiology Congress October 17-19, 2016 Rome, Italy; 19th Annual Update on Pediatric and Congenital Cardiovascular Disease February 24- 28, 2016, Orlando, USA; American Cardiology Congress 2016; ACC Annual Meeting 2016; American Cardiology Congress 2016; European Cardiology Congress August 27 - 31, 2016 Rome, Italy; International Conference and Expo on Cardiology and Cardiac surgery April 04-06, 2016, Dubai, UAE; 21st World Congress on Heart Disease, July 30-August 1, 2016, Boston, MA, USA.

Track:Heart Failure

Heart failure is a condition caused by the heart failing to pump enough blood around the body at the right pressure. It usually occurs because the heart muscle has become too weak or stiff to work properly. If you have heart failure, it does not mean your heart is about to stop working. It means the heart needs some support to do its job, usually in the form of medicines. Breathlessness, feeling very tired and ankle swelling is the main symptoms of heart failure. But all of these symptoms can have other causes, only some of which are serious. The symptoms of heart failure can develop quickly (acute heart failure). If this happens, you will need to be treated in hospital. But they can also develop gradually (chronic heart failure). The most common causes are heart attack, high blood pressure, cardiomyopathy (diseases of the heart muscle. Sometimes these are inherited from your family and sometimes they are caused by other things, such as viral infections).

RelevantConferences:9thArrhythmiasConference July 14-15, 2016 Brisbane, Australia;CardioVascular MedicineConference August 01-02, 2016 Manchester, UK;EchocardiographyConference July 18-19, 2016 Berlin, Germany; 8th Global Cardiologists Annual Meeting July 18-20, 2016 Berlin, Germany; Atherosclerosis and Clinical Cardiology Conference July 11-12, 2016 Philadelphia, Pennsylvania, USA; Ischemic Heart Diseases Conference October 20-21, 2016 Chicago, Illinois, USA; Hypertension & Health Care Conference August 11-12, 2016 Toronto, Canada; 11thCardiac Conference September 12-13, 2016 Philadelphia, Pennsylvania, USA; 13thEuropean Cardiology Congress October 17-19, 2016 Rome, Italy; 19th Annual Update on Pediatric and Congenital Cardiovascular Disease February 24- 28, 2016, Orlando, USA; American Cardiology Congress 2016; ACC Annual Meeting 2016; American Cardiology Congress 2016; European Cardiology Congress August 27 - 31, 2016 Rome, Italy; International Conference and Expo on Cardiology and Cardiac surgery April 04-06, 2016, Dubai, UAE; 21st World Congress on Heart Disease, July 30-August 1, 2016, Boston, MA, USA.

Track:Heart Diseases

Heart disease include heart diseases that is any type of disorder that affects the heart. Heart disease meetings comes under cardiology conferences that comprises the heart diseases tracks that means the same as cardiac disease but not the cardiovascular diseases. This condition results from a buildup of plaque on the inside of the arteries, which reduces blood flow to the heart and increases the risk of a heart attack and other heart complications. In this sub topic Heart disease we have different types of heart diseases i.e. Coronary heart diseases, Pediatric heart diseases, Congenital Heart Diseases, myocardial infarction etc.

RelevantConferences:9thArrhythmiasConference July 14-15, 2016 Brisbane, Australia;CardioVascular MedicineConference August 01-02, 2016 Manchester, UK;EchocardiographyConference July 18-19, 2016 Berlin, Germany; 8th Global Cardiologists Annual Meeting July 18-20, 2016 Berlin, Germany; Atherosclerosis and Clinical Cardiology Conference July 11-12, 2016 Philadelphia, Pennsylvania, USA; Ischemic Heart Diseases Conference October 20-21, 2016 Chicago, Illinois, USA; Hypertension & Health Care Conference August 11-12, 2016 Toronto, Canada; 11thCardiac Conference September 12-13, 2016 Philadelphia, Pennsylvania, USA; 13thEuropean Cardiology Congress October 17-19, 2016 Rome, Italy; 19th Annual Update on Pediatric and Congenital Cardiovascular Disease February 24- 28, 2016, Orlando, USA; American Cardiology Congress 2016; ACC Annual Meeting 2016; American Cardiology Congress 2016; European Cardiology Congress August 27 - 31, 2016 Rome, Italy; International Conference and Expo on Cardiology and Cardiac surgery April 04-06, 2016, Dubai, UAE; 21st World Congress on Heart Disease, July 30-August 1, 2016, Boston, MA, USA.

Track:Obesity and Heart

People with a body mass index (BMI) of 30 or higher are considered obese. The term obesity is used to describe the health condition of anyone significantly above his or her ideal healthy weight. Obesity increases the risk for heart disease and stroke. But it harms more than just the heart and blood vessel system. It's also a major cause of gallstones, osteoarthritis and respiratory problems. Obesity is intimately intertwined with multiple health conditions that underlie cardiovascular disease including high blood pressure, diabetes, and abnormal blood cholesterol. In addition, weight gain is a frequent consequence of heart-damaging lifestyle choices such as lack of exercise and a fat-laden diet. Obesity also can lead to heart failure. This is a serious condition in which your heart can't pump enough blood to meet your body's needs.

RelevantConferences:9thArrhythmiasConference July 14-15, 2016 Brisbane, Australia;CardioVascular MedicineConference August 01-02, 2016 Manchester, UK;EchocardiographyConference July 18-19, 2016 Berlin, Germany; 8th Global Cardiologists Annual Meeting July 18-20, 2016 Berlin, Germany; Atherosclerosis and Clinical Cardiology Conference July 11-12, 2016 Philadelphia, Pennsylvania, USA; Ischemic Heart Diseases Conference October 20-21, 2016 Chicago, Illinois, USA; Hypertension & Health Care Conference August 11-12, 2016 Toronto, Canada; 11thCardiac Conference September 12-13, 2016 Philadelphia, Pennsylvania, USA; 13thEuropean Cardiology Congress October 17-19, 2016 Rome, Italy; 19th Annual Update on Pediatric and Congenital Cardiovascular Disease February 24- 28, 2016, Orlando, USA; American Cardiology Congress 2016; ACC Annual Meeting 2016; American Cardiology Congress 2016; European Cardiology Congress August 27 - 31, 2016 Rome, Italy; International Conference and Expo on Cardiology and Cardiac surgery April 04-06, 2016, Dubai, UAE; 21st World Congress on Heart Disease, July 30-August 1, 2016, Boston, MA, USA.

Track:Cardiac Drugs

Cardiac Drugs are the drugs which are used in any way to treat conditions of the heart or the circulatory or vascular system. Many classes of cardiovascular agents are available to treat the various cardiovascular conditions. They are a complicated group of drugs with many being used for multiple heart conditions. Prescription drugs and medicines for diseases relating to the structure and function of the heart and blood vessels. In this sub topic we have Sodium, potassium, calcium channel blockers, ACE-inhibitors and Cardiac biomarkers. There are 6 associations and societies and the main association for Cardiac Therapeutic Agents in USA. 50 universities are working on Cardiac Therapeutic Agents. There are 120 Companies in USA that are making Cardiac Therapeutic Agents in Cardiology. 3new drugs were introduced in 2015. There are many types of cardiovascular drugs in the market that include Cardiac glycosides, antiarrhythmic agents, antianginal agents and antihypertensive agents.

RelevantConferences:9thArrhythmiasConference July 14-15, 2016 Brisbane, Australia;CardioVascular MedicineConference August 01-02, 2016 Manchester, UK;EchocardiographyConference July 18-19, 2016 Berlin, Germany; 8th Global Cardiologists Annual Meeting July 18-20, 2016 Berlin, Germany; Atherosclerosis and Clinical Cardiology Conference July 11-12, 2016 Philadelphia, Pennsylvania, USA; Ischemic Heart Diseases Conference October 20-21, 2016 Chicago, Illinois, USA; Hypertension & Health Care Conference August 11-12, 2016 Toronto, Canada; 11thCardiac Conference September 12-13, 2016 Philadelphia, Pennsylvania, USA; 13thEuropean Cardiology Congress October 17-19, 2016 Rome, Italy; 19th Annual Update on Pediatric and Congenital Cardiovascular Disease February 24- 28, 2016, Orlando, USA; American Cardiology Congress 2016; ACC Annual Meeting 2016; American Cardiology Congress 2016; European Cardiology Congress August 27 - 31, 2016 Rome, Italy; International Conference and Expo on Cardiology and Cardiac surgery April 04-06, 2016, Dubai, UAE; 21st World Congress on Heart Disease, July 30-August 1, 2016, Boston, MA, USA.

Track:Cardiac Imaging and technology

Advances in imaging technology have sparked fundamental changes in the approach to cardiac care. One of the most accurate diagnostic techniques cardiac imaging employs new, non-invasive and minimally invasive radiology technology to produce three-dimensional images of the heart. The imaging tools help to discover medical problems that several years ago were undetectable using conventional methods of diagnosis. Cardiac imaging techniques include coronary catheterization, echocardiogram, and intravascular ultrasound.

RelevantConferences:9thArrhythmiasConference July 14-15, 2016 Brisbane, Australia;CardioVascular MedicineConference August 01-02, 2016 Manchester, UK;EchocardiographyConference July 18-19, 2016 Berlin, Germany; 8th Global Cardiologists Annual Meeting July 18-20, 2016 Berlin, Germany; Atherosclerosis and Clinical Cardiology Conference July 11-12, 2016 Philadelphia, Pennsylvania, USA; Ischemic Heart Diseases Conference October 20-21, 2016 Chicago, Illinois, USA; Hypertension & Health Care Conference August 11-12, 2016 Toronto, Canada; 11thCardiac Conference September 12-13, 2016 Philadelphia, Pennsylvania, USA; 13thEuropean Cardiology Congress October 17-19, 2016 Rome, Italy; 19th Annual Update on Pediatric and Congenital Cardiovascular Disease February 24- 28, 2016, Orlando, USA; American Cardiology Congress 2016; ACC Annual Meeting 2016; American Cardiology Congress 2016; European Cardiology Congress August 27 - 31, 2016 Rome, Italy; International Conference and Expo on Cardiology and Cardiac surgery April 04-06, 2016, Dubai, UAE; 21st World Congress on Heart Disease, July 30-August 1, 2016, Boston, MA, USA.

Track:Women & CVD

Cardiovascular disease (CVD) heart disease and stroke is the biggest killer of women globally, killing more women than all cancers, tuberculosis, HIV/AIDS and malaria combined. Heart disease is the leading cause of death for women in the United States, killing 292,188 women in 2009 thats 1 in every 4 female deaths. While some women have no symptoms, others experience angina (dull, heavy to sharp chest pain or discomfort), pain in the neck/jaw/throat or pain in the upper abdomen or back. These may occur during rest, begin during physical activity, or be triggered by mental stress. Sometimes heart disease may be silent and not diagnosed until a woman experiences signs or symptoms of a heart attack, heart failure, an arrhythmia or stroke. Women with diabetes have higher CVD mortality rates than men with diabetes. Women who engage in physical activity for less than an hour per week have 1.48 times the risk of developing coronary heart disease, compared to women who do more than three hours of physical activity per week. Go Red for Women is a major international awareness campaign dedicated to the prevention, diagnosis and control of heart disease and stroke in women.

RelevantConferences:9thArrhythmiasConference July 14-15, 2016 Brisbane, Australia;CardioVascular MedicineConference August 01-02, 2016 Manchester, UK;EchocardiographyConference July 18-19, 2016 Berlin, Germany; 8th Global Cardiologists Annual Meeting July 18-20, 2016 Berlin, Germany; Atherosclerosis and Clinical Cardiology Conference July 11-12, 2016 Philadelphia, Pennsylvania, USA; Ischemic Heart Diseases Conference October 20-21, 2016 Chicago, Illinois, USA; Hypertension & Health Care Conference August 11-12, 2016 Toronto, Canada; 11thCardiac Conference September 12-13, 2016 Philadelphia, Pennsylvania, USA; 13thEuropean Cardiology Congress October 17-19, 2016 Rome, Italy; 19th Annual Update on Pediatric and Congenital Cardiovascular Disease February 24- 28, 2016, Orlando, USA; American Cardiology Congress 2016; ACC Annual Meeting 2016; American Cardiology Congress 2016; European Cardiology Congress August 27 - 31, 2016 Rome, Italy; International Conference and Expo on Cardiology and Cardiac surgery April 04-06, 2016, Dubai, UAE; 21st World Congress on Heart Disease, July 30-August 1, 2016, Boston, MA, USA.

Track:Pediatric Cardiology

Pediatric Cardiology is responsible for the diagnosis of congenital heart defects, performing diagnostic procedures such as echocardiograms, cardiac catheterizations, and for the ongoing management of the sequel of heart disease in infants, children and adolescents. The division is actively involved in research aimed at preventing both congenital and acquired heart disease in children. Finally, the division is committed to educating the next generation of physicians, and offers advanced training in pediatric cardiology.

RelevantConferences:9thArrhythmiasConference July 14-15, 2016 Brisbane, Australia;CardioVascular MedicineConference August 01-02, 2016 Manchester, UK;EchocardiographyConference July 18-19, 2016 Berlin, Germany; 8th Global Cardiologists Annual Meeting July 18-20, 2016 Berlin, Germany; Atherosclerosis and Clinical Cardiology Conference July 11-12, 2016 Philadelphia, Pennsylvania, USA; Ischemic Heart Diseases Conference October 20-21, 2016 Chicago, Illinois, USA; Hypertension & Health Care Conference August 11-12, 2016 Toronto, Canada; 11thCardiac Conference September 12-13, 2016 Philadelphia, Pennsylvania, USA; 13thEuropean Cardiology Congress October 17-19, 2016 Rome, Italy; 19th Annual Update on Pediatric and Congenital Cardiovascular Disease February 24- 28, 2016, Orlando, USA; American Cardiology Congress 2016; ACC Annual Meeting 2016; American Cardiology Congress 2016; European Cardiology Congress August 27 - 31, 2016 Rome, Italy; International Conference and Expo on Cardiology and Cardiac surgery April 04-06, 2016, Dubai, UAE; 21st World Congress on Heart Disease, July 30-August 1, 2016, Boston, MA, USA.

Track:Cardiac Nursing

Cardiac nursing is a nursing specialty that works with patients who suffer from various conditions of the cardiovascular system. Cardiac nurses help treat conditions such as unstable angina, cardiomyopathy, coronary artery disease, congestive heart failure, myocardial infarction and cardiac dysrhythmia under the direction of a cardiologist. Cardiac nurses perform postoperative care on a surgical unit, stress test evaluations, cardiac monitoring, vascular monitoring, and health assessments. Cardiac nurses work in many different environments, including coronary care units (CCU), cardiac catheterization, intensive care units (ICU), operating theatres, cardiac rehabilitation centers, clinical research, cardiac surgery wards, cardiovascular intensive care units (CVICU), and cardiac medical wards.

RelevantConferences:9thArrhythmiasConference July 14-15, 2016 Brisbane, Australia;CardioVascular MedicineConference August 01-02, 2016 Manchester, UK;EchocardiographyConference July 18-19, 2016 Berlin, Germany; 8th Global Cardiologists Annual Meeting July 18-20, 2016 Berlin, Germany; Atherosclerosis and Clinical Cardiology Conference July 11-12, 2016 Philadelphia, Pennsylvania, USA; Ischemic Heart Diseases Conference October 20-21, 2016 Chicago, Illinois, USA; Hypertension & Health Care Conference August 11-12, 2016 Toronto, Canada; 11thCardiac Conference September 12-13, 2016 Philadelphia, Pennsylvania, USA; 13thEuropean Cardiology Congress October 17-19, 2016 Rome, Italy; 19th Annual Update on Pediatric and Congenital Cardiovascular Disease February 24- 28, 2016, Orlando, USA; American Cardiology Congress 2016; ACC Annual Meeting 2016; American Cardiology Congress 2016; European Cardiology Congress August 27 - 31, 2016 Rome, Italy; International Conference and Expo on Cardiology and Cardiac surgery April 04-06, 2016, Dubai, UAE; 21st World Congress on Heart Disease, July 30-August 1, 2016, Boston, MA, USA.

Track:Diabetic Cardiovascular Diseases

The term diabetic heart disease (DHD) refers to heart disease that develops in people who have diabetes. Diabetes is a disease in which the body's blood glucose (sugar) level is too high. Normally, the body breaks down food into glucose and carries it to cells throughout the body. The cells use a hormone called insulin to turn the glucose into energy. There is a clear-cut relationship between diabetes and cardiovascular disease. Coronary heart disease is recognized to be the cause of death for 80% of people with diabetes; however, the NHS states that heart attacks are largely preventable. Cardiovascular disease is the leading cause of mortality for people with diabetes. Hypertension, abnormal blood lipids and obesity, all risk factors in their own right for cardiovascular disease, occur more frequently in people with diabetes. Several advances in treating heart disease over the past two decades have improved the chances of surviving a heart attack or stroke. However, as the incidence of diabetes steadily increases, so does the number of new cases of heart disease and cardiovascular complications.

RelevantConferences:9thArrhythmiasConference July 14-15, 2016 Brisbane, Australia;CardioVascular MedicineConference August 01-02, 2016 Manchester, UK;EchocardiographyConference July 18-19, 2016 Berlin, Germany; 8th Global Cardiologists Annual Meeting July 18-20, 2016 Berlin, Germany; Atherosclerosis and Clinical Cardiology Conference July 11-12, 2016 Philadelphia, Pennsylvania, USA; Ischemic Heart Diseases Conference October 20-21, 2016 Chicago, Illinois, USA; Hypertension & Health Care Conference August 11-12, 2016 Toronto, Canada; 11thCardiac Conference September 12-13, 2016 Philadelphia, Pennsylvania, USA; 13thEuropean Cardiology Congress October 17-19, 2016 Rome, Italy; 19th Annual Update on Pediatric and Congenital Cardiovascular Disease February 24- 28, 2016, Orlando, USA; American Cardiology Congress 2016; ACC Annual Meeting 2016; American Cardiology Congress 2016; European Cardiology Congress August 27 - 31, 2016 Rome, Italy; International Conference and Expo on Cardiology and Cardiac surgery April 04-06, 2016, Dubai, UAE; 21st World Congress on Heart Disease, July 30-August 1, 2016, Boston, MA, USA.

Track:Cardiac Surgery

Cardiovascular surgery is surgery on the heart or great vessels performed by cardiac surgeons. Frequently, it is done to treat complications of ischemic heart disease (for example, coronary artery bypass grafting), correct congenital heart disease, or treat valvular heart disease from various causes including endocarditis, rheumatic heart disease and atherosclerosis. It also includes heart transplantation. The development of cardiac surgery and cardiopulmonary bypass techniques has reduced the mortality rates of these surgeries to relatively low ranks. Coronary artery bypass grafting (CABG) is the most common type of heart surgery. CABG improves blood flow to the heart. Surgeons use CABG to treat people who have severe coronary heart disease (CHD).

RelevantConferences:9thArrhythmiasConference July 14-15, 2016 Brisbane, Australia;CardioVascular MedicineConference August 01-02, 2016 Manchester, UK;EchocardiographyConference July 18-19, 2016 Berlin, Germany; 8th Global Cardiologists Annual Meeting July 18-20, 2016 Berlin, Germany; Atherosclerosis and Clinical Cardiology Conference July 11-12, 2016 Philadelphia, Pennsylvania, USA; Ischemic Heart Diseases Conference October 20-21, 2016 Chicago, Illinois, USA; Hypertension & Health Care Conference August 11-12, 2016 Toronto, Canada; 11thCardiac Conference September 12-13, 2016 Philadelphia, Pennsylvania, USA; 13thEuropean Cardiology Congress October 17-19, 2016 Rome, Italy; 19th Annual Update on Pediatric and Congenital Cardiovascular Disease February 24- 28, 2016, Orlando, USA; American Cardiology Congress 2016; ACC Annual Meeting 2016; American Cardiology Congress 2016; European Cardiology Congress August 27 - 31, 2016 Rome, Italy; International Conference and Expo on Cardiology and Cardiac surgery April 04-06, 2016, Dubai, UAE; 21st World Congress on Heart Disease, July 30-August 1, 2016, Boston, MA, USA.

Track:Current Research in Cardiology

Advances in medicine means that if CHD is detected at an early stage it can be treated successfully to extend the survival rate. Successful treatment is more likely if the disease is detected at its earliest stages. Our current research focuses on the early detection of CHD in order to halt or reverse the progress of the disease. The ongoing research includes pioneering the use of heart scanning in the early diagnosis of heart disease in diabetics, Development of Nuclear Cardiology techniques for the detection of heart disease, Drug development and evaluation of treatments used in heart disease, Identification of novel biological markers to predict the presence of heart disease, analysis of ethnic and socio-economic differences in heart disease risk.

RelevantConferences:9thArrhythmiasConference July 14-15, 2016 Brisbane, Australia;CardioVascular MedicineConference August 01-02, 2016 Manchester, UK;EchocardiographyConference July 18-19, 2016 Berlin, Germany; 8th Global Cardiologists Annual Meeting July 18-20, 2016 Berlin, Germany; Atherosclerosis and Clinical Cardiology Conference July 11-12, 2016 Philadelphia, Pennsylvania, USA; Ischemic Heart Diseases Conference October 20-21, 2016 Chicago, Illinois, USA; Hypertension & Health Care Conference August 11-12, 2016 Toronto, Canada; 11thCardiac Conference September 12-13, 2016 Philadelphia, Pennsylvania, USA; 13thEuropean Cardiology Congress October 17-19, 2016 Rome, Italy; 19th Annual Update on Pediatric and Congenital Cardiovascular Disease February 24- 28, 2016, Orlando, USA; American Cardiology Congress 2016; ACC Annual Meeting 2016; American Cardiology Congress 2016; European Cardiology Congress August 27 - 31, 2016 Rome, Italy; International Conference and Expo on Cardiology and Cardiac surgery April 04-06, 2016, Dubai, UAE; 21st World Congress on Heart Disease, July 30-August 1, 2016, Boston, MA, USA.

Track:Cardiologists Training & Education

Cardiologists provide health care to prevent, diagnose and treat diseases and conditions of the heart and cardiovascular system, including the arteries. Because the field of cardiology encompasses so many different types of diseases and procedures, there are many different types of cardiology one may choose to practice depending on his or her interests and skill sets, and the type of work theyd like to do. Cardiologists receive extensive education, including four years of medical school and three years of training in general internal medicine. After this, a cardiologist spends three or more years in specialized training. Many cardiologists are specially trained in this technique, but others specialize in office diagnosis, the performance and interpretation of echocardiograms, ECGs, and exercise tests. Still others have special skill in cholesterol management or cardiac rehabilitation and fitness. All cardiologists know how and when these tests are needed and how to manage cardiac emergencies.

RelevantConferences:9thArrhythmiasConference July 14-15, 2016 Brisbane, Australia;CardioVascular MedicineConference August 01-02, 2016 Manchester, UK;EchocardiographyConference July 18-19, 2016 Berlin, Germany; 8th Global Cardiologists Annual Meeting July 18-20, 2016 Berlin, Germany; Atherosclerosis and Clinical Cardiology Conference July 11-12, 2016 Philadelphia, Pennsylvania, USA; Ischemic Heart Diseases Conference October 20-21, 2016 Chicago, Illinois, USA; Hypertension & Health Care Conference August 11-12, 2016 Toronto, Canada; 11thCardiac Conference September 12-13, 2016 Philadelphia, Pennsylvania, USA; 13thEuropean Cardiology Congress October 17-19, 2016 Rome, Italy; 19th Annual Update on Pediatric and Congenital Cardiovascular Disease February 24- 28, 2016, Orlando, USA; American Cardiology Congress 2016; ACC Annual Meeting 2016; American Cardiology Congress 2016; European Cardiology Congress August 27 - 31, 2016 Rome, Italy; International Conference and Expo on Cardiology and Cardiac surgery April 04-06, 2016, Dubai, UAE; 21st World Congress on Heart Disease, July 30-August 1, 2016, Boston, MA, USA.

Track:Advances in Cardiologists Education

Advances in Cardiology Education presents the current thinking of international experts regarding the underlying mechanisms of cardiovascular risk and the pathogenesis and pathophysiology of heart and its related disorders. This session gives new insights into the relationship between arterial stiffness, cardiovascular diagnosis, vascular study and atherosclerosis, but also establishes the possible interactions with age and other cardiovascular factors such as high blood pressure, diabetes and hyperlipidemia.

RelevantConferences:9thArrhythmiasConference July 14-15, 2016 Brisbane, Australia;CardioVascular MedicineConference August 01-02, 2016 Manchester, UK;EchocardiographyConference July 18-19, 2016 Berlin, Germany; 8th Global Cardiologists Annual Meeting July 18-20, 2016 Berlin, Germany; Atherosclerosis and Clinical Cardiology Conference July 11-12, 2016 Philadelphia, Pennsylvania, USA; Ischemic Heart Diseases Conference October 20-21, 2016 Chicago, Illinois, USA; Hypertension & Health Care Conference August 11-12, 2016 Toronto, Canada; 11thCardiac Conference September 12-13, 2016 Philadelphia, Pennsylvania, USA; 13thEuropean Cardiology Congress October 17-19, 2016 Rome, Italy; 19th Annual Update on Pediatric and Congenital Cardiovascular Disease February 24- 28, 2016, Orlando, USA; American Cardiology Congress 2016; ACC Annual Meeting 2016; American Cardiology Congress 2016; European Cardiology Congress August 27 - 31, 2016 Rome, Italy; International Conference and Expo on Cardiology and Cardiac surgery April 04-06, 2016, Dubai, UAE; 21st World Congress on Heart Disease, July 30-August 1, 2016, Boston, MA, USA.

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Cardiac Stem Cells Comments Off on Cardiology Conferences | Events | Meetings | Florida | USA … | September 8th, 2016

An illustration of GRNOPC1, a drug based on human embryonic stem cells, which contains oligodendrocyte progenitor cells.

Geron/UC Irvine

The hope: that one day this treatment may help the paralyzed walk again.

On Friday at the Shepherd Center, a spinal cord and brain injury rehabilitation center in Atlanta, a patient with a recent spinal cord injury made medical history: The paraplegic was injected with two million embryonic stem cells.

The goal: To regenerate spinal cord tissue.

The process, reports CBS Station KPIX correspondent Dr. Kim Mulvihill, involves coaxing the cells into becoming specialized nerve cells, and then injecting them directly into the injured area of the spinal cord.

The embryonic stem cells come from a donated human embryo left over from a fertility treatment, an embryo that would have otherwise been discarded.

Embryonic stem cells have been at the center of funding controversies because the research involves destroying the embryos, which some have argued is akin to abortion. But, many researchers consider embryonic stem cells the most versatile types of stem cells, as they can morph into any type of cell.

While there are some restrictions on federal funding for stem cell lines for research, companies such as Geron do not use federal funding and are therefore free from those restrictions.

The study is approved by the FDA but is privately funded.

The drug - known as GRNOPC1 - contains cells called oligodendrocyte progenitor cells. Those progenitor cells turn into oligodendrocytes, a type of cell that produces myelin, a coating that allows impulses to move along nerves. When those cells are lost because of injury, paralysis can follow.

If GRNOPC1 works, the progenitor cells will produce new oligodendrocytes in the injured area of the patient's spine, potentially allowing for new movement.

The therapy will be injected into the patients' spines one to two weeks after they suffer an injury between their third and 10th thoracic vertebrae, or roughly the middle to upper back. Later trials would include patients with less severe spinal injuries and damage to other parts of the spine.

In lab animals, the results were dramatic - paralyzed rodents moved again.

Dr. Thomas Okarma, President and CEO of Geron, told CBS Station KPIX, "This therapy goes far beyond the reach of pills or scalpels and will achieve a new level of healing with a single injection of healthy replacement cells."

So far, Geron of Menlo Park, Calif., has spent $175 million in developing this treatment.

However, Dr. Arnold Kriegstein, who heads Regeneration Medicine & Stem Cell Research at University of California-San Francisco, told KPIX, "People are just so different from rodents."

Though optimistic, he urged caution. "I think that people looking at the outcome of this trial should really lower their expectations if they're really thinking people will get out of their wheelchairs. It's unlikely to happen."

The drug still faces many years of testing for effectiveness and tolerance if all goes well in the early stage study.

This initial trial is not aimed at a cure for patients, but to establish if the treatment is safe.

Patients must be treated within 14 days of a spinal cord injury and they must undergo short term immune suppression therapy to make sure their bodies don't reject the cells.

If the treatment is deemed safe, the next trial will aim at testing effectiveness and will use a higher quantity of stem cells.

Shepherd Center is one of seven potential sites in the United States for the trial.

The company has said it plans to enroll eight to 10 patients in the study at sites nationwide. The trial will take about two years, with each patient being studied for one year.

Geron is among several companies focusing on embryonic stem cell therapy. Advanced Cell Technology Inc. hopes to develop the embryonic stem cell therapy called retinal pigment epithelium, or RPE. That therapy is designed to treat Stargart disease, an inherited condition that affects children and can lead to blindness in adulthood.

Meanwhile, other companies such as StemCells Inc. are focusing on adult stem cells, which can be gathered from a person's skin.

For more info: clinicaltrials.goc - Safety Study of GRNOPC1 in Spinal Cord Injury

2010 CBS Interactive Inc. All Rights Reserved. This material may not be published, broadcast, rewritten, or redistributed. The Associated Press contributed to this report.

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Embryonic Stem Cell Test on Spinal Cord Injury - CBS News

Spinal Cord Stem Cells Comments Off on Embryonic Stem Cell Test on Spinal Cord Injury – CBS News | October 4th, 2015