New Blood Types Discovered

You probably know your blood type: A, B, AB or O. You may even know if you're Rhesus positive or negative. But how about the Langereis blood type? Or the Junior blood type? Positive or negative? Most people have never even heard of these.

Yet this knowledge could be "a matter of life and death," says University of Vermont biologist Bryan Ballif.

While blood transfusion problems due to Langereis and Junior blood types are rare worldwide, several ethnic populations are at risk, Ballif notes. "More than 50,000 Japanese are thought to be Junior negative and may encounter blood transfusion problems or mother-fetus incompatibility," he writes.

 But the molecular basis of these two blood types has remained a mystery — until now.

In the February issue of Nature Genetics, Ballif and his colleagues report on their discovery of two proteins on red blood cells responsible for these lesser-known blood types.

Ballif identified the two molecules as specialized transport proteins named ABCB6 and ABCG2.

"Only 30 proteins have previously been identified as responsible for a basic blood type," Ballif notes, "but the count now reaches 32."

The last new blood group proteins to be discovered were nearly a decade ago, Ballif says, "so it's pretty remarkable to have two identified this year."

Both of the newly identified proteins are also associated with anticancer drug resistance, so the findings may also have implications for improved treatment of breast and other cancers.

As part of the international effort, Ballif, assistant professor in UVM's biology department, used a mass spectrometer funded by the Vermont Genetics Network. With this machine, he analyzed proteins purified by his longtime collaborator, Lionel Arnaud at the French National Institute for Blood Transfusion in Paris, France.

Ballif and Arnaud, in turn, relied on antibodies to Langereis and Junior blood antigens developed by Yoshihiko Tani at the Japanese Red Cross Osaka Blood Center and Toru Miyasaki at the Japanese Red Cross Hokkaido Blood Center.

After the protein identification in Vermont, the work returned to France. There Arnaud and his team conducted cellular and genetic tests confirming that these proteins were responsible for the Langereis and Junior blood types. "He was able to test the gene sequence," Ballif says, "and, sure enough, we found mutations in this particular gene for all the people in our sample who have these problems."

Beyond the ABO blood type and the Rhesus (Rh) blood type, the International Blood Transfusion Society recognizes twenty-eight additional blood types with names like Duffy, Kidd, Diego and Lutheran. But Langereis and Junior have not been on this list. Although the antigens for the Junior and Langereis (or Lan) blood types were identified decades ago in pregnant women having difficulties carrying babies with incompatible blood types, the genetic basis of these antigens has been unknown until now.

Therefore, "very few people learn if they are Langereis or Junior positive or negative," Ballif says.

"Transfusion support of individuals with an anti-Lan antibody is highly challenging," the research team wrote in Nature Genetics, "partly because of the scarcity of compatible blood donors but mainly because of the lack of reliable reagents for blood screening." And Junior-negative blood donors are extremely rare too. That may soon change.

With the findings from this new research, health care professionals will now be able to more rapidly and confidently screen for these novel blood group proteins, Ballif wrote in a recent news article. "This will leave them better prepared to have blood ready when blood transfusions or other tissue donations are required," he notes.

"Now that we know these proteins, it will become a routine test," he says.

This science may be especially important to organ transplant patients. "As we get better and better at transplants, we do everything we can to make a good match," Ballif says. But sometimes a tissue or organ transplant, that looked like a good match, doesn't work — and the donated tissue is rejected, which can lead to many problems or death.

"We don't always know why there is rejection," Ballif says, "but it may have to do with these proteins."

The rejection of donated tissue or blood is caused by the way the immune system distinguishes self from not-self. "If our own blood cells don't have these proteins, they're not familiar to our immune system," Ballif says, so the new blood doesn't "look like self" to the complex cellular defenses of the immune system. "They'll develop antibodies against it," Ballif says, and try to kill off the perceived invaders. In short, the body starts to attack itself.

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"Then you may be out of luck," says Ballif, who notes that in addition to certain Japanese populations, European Gypsies are also at higher risk for not carrying the Langereis and Junior blood type proteins.

"There are people in the United States who have these challenges too," he says, "but it's more rare."

Ballif and his international colleagues are not done with their search. "We're following up on more unknown blood types," he says. "There are probably on the order of 10 to 15 more of these unknown blood type systems — where we know there is a problem but we don't know what the protein is that is causing the problem."

Although these other blood systems are very rare, "if you're that one individual, and you need a transfusion," Ballif says, "there's nothing more important for you to know."

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Posted in: biology,blood,blood type

Nano-Bio-Bandage Can Stop Your Bleeding Almost Immediately

Bleeding out on the battlefield--far from the trauma wards and triage units that might save their lives--is a scenario that soldiers simply have to live with (and try like hell to avoid). But thanks to a nanoscale breakthrough at MIT, the chances of it happening could be significantly reduced. Researchers there have created a nanoscale coating that can stop bleeding nearly instantaneously using a clotting agent already found naturally in blood.

That agent, called thrombin, is coated onto sponges that can be easily packed by soldiers and field medics (or civilian medical personnel for that matter) and shaped to fit just about any kind of wound. Those pre-coated sponges are a pretty big improvement over tourniquets and gauze, which are limited in their ability to stop every kind of bleeding. 

Tourniquets obviously can’t be used on many parts of the body (the neck is a good example), and other glues and chemically treated bandages designed for dressing battlefield wounds come with their own complications and shortcomings. 

Thrombin A clotting agent already found in the blood, thrombin is being layered onto sponges that can stop bleeding almost immediately. via Wikimedia

Thrombin, on the other hand, is already used by the body to stop bleeding. Civilian hospitals also use it already, but it’s in liquid form so sponges must be soaked immediately before they are applied to the wound, making them impractical for the battlefield.

MIT’s sponge instead uses a spray-on biological nanoscale coating using alternating layers of thrombin and tannic acid, which results in a film that contains a large amount of functional thrombin with a shelf life that makes it feasible to pack them into the field. Both substances are already FDA approved, the researchers say, which means the sponges could quickly find their way into wider use.

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That’s good news for soldiers, and potentially good news for anyone who sustains a trauma far from the emergency room. The MIT lab is now working on a sponge that combines a blood-clotting coating with an antibiotic layer in a single sponge to help fight off infection even as a dressing stops the initial bleeding.
Environment Clean Generations 

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Posted in: biology,blood,environment,nano bandage

Artificial Blood is Getting Closer

Researchers at Edinburgh University in Scotland have announced that they believe the type of artificial blood they are working on could be ready for testing in humans in as little as two or three years. Made from growing stem cells taken from adult human bone marrow, the blood they create would be of the rare type “O-negative” that some 98% of people in need could use.

Researchers have for years been experimenting with different processes and materials to recreate what natures provides every individual free of charge; a liquid material capable of carrying oxygen and other nutrients through veins and arteries during times of blood loss, generally due to injury or surgery. The reason the need is so great is because of the great demand. People are injured every day, and develop problems that require surgery to fix, and sometimes the supply of blood from donors isn’t enough to keep up with demand, especially in less developed countries. Plus, there is the always constant threat of infections transferred via blood transfusions, such as HIV, Hepatitis and vCJD, also known as mad cow disease when it infects people.

The team in Edinburgh, led by Professor Marc Turner, has been working on a technique whereby stem cells are taken from the bone marrow of healthy adults and are then grown in a lab into a material that very closely resembles red blood cells grown normally in the human body. They think their process has been sufficiently refined to predict that their results will be ready for clinical trials in as little as two or three years. The next step would be combing their results with the results of others around the world who are working on ways create a form of artificial hemoglobin. If all goes according to plan, the use of such artificial blood could become a routine part of emergency medical practices in about ten years time.

The problem with the artificial blood, however, is even if all works out as planned it still wouldn’t be the perfect replacement everyone really wants. Artificial blood, while clearly a lifesaver in medical emergencies would not likely ever be a permanent replacement for blood; it would still be just a stop-gap type measure. This is why research will continue to focus on a true artificial blood that could in theory completely replace all the blood a person needs and function just as their natural blood does, without any advertise side effects or complications.

That is not to say that a stop-gap temporary blood replacement wouldn’t be important. If this new type of artificial blood pans out, millions of lives would be saved the world over. And that certainly, is no small thing.

 by "environment clean generations"

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Posted in: Artificial Blood is Getting Closer,biology,blood,edingurgh,environment clean generations,people,surgery

Snake's blood makes the heart grow

Snake oil might be best avoided but snake blood may be just what the doctor ordered. Injecting snake-blood plasma into mice increased the size of their heart. The discovery could prove key in the treatment of heart damage.

In humans, an enlarged heart is normally a sign that the body is in trouble. Heart attacks, high blood pressure and defects in heart valves all force the heart to work harder and grow to manage the extra load. Growth can scar the heart and decrease the efficiency of nutrient absorption in heart cells.

The heart of the Burmese python, a subspecies of Indian python, also grows. After eating a large meal, the organ nearly doubles in size to pump recently digested nutrients around its body. This growth, however, has no negative side effects and is reversible.

Similarly, heart growth in humans is not always negative. A hormone called insulin-like growth factor 1 (IGF-1), produced during exercise, causes the heart to swell in order to meet increased bodily demand for oxygen. When growth occurs in this way, there is no scarring.

After eating, a snake's blood contains a cocktail of fatty acids, some of which Leslie Leinwand from the University of Colorado at Boulder, suspected were causing the heart to grow.

To see if this enriched blood could have the same effect on other animals' cells, Leinwand coated in vitro rat heart-muscle cells with the blood plasma of recently fed snakes and found that they produced a greater volume of IGF-1 while also increasing in size. The cells were able to process fats more effectively and had a faster metabolism. The snake plasma also caused the rat cells to produce less NFAT – a protein created when hearts are stressed.

The team next identified three fatty acids that appeared key to these helpful effects. They injected these fatty acids into healthy mice. After one week, the hearts of these mice had increased in size and showed no sign of scar tissue.

Leinwand believes that the discovery could lead to new treatments to strengthen hearts damaged by heart attack. She now plans to test the fatty acids on mice with heart disease to see if cell death in the heart can be slowed or even reversed.

 by "environment clean generations"

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