 |
|
Exploring the molecular origin of blood clot flexibility
January 15, 2007(PHILADELPHIA) - How do blood clots maintain that precise balance of stiffness for wound healing and flexibility to go with the flow? Researchers at the University of Pennsylvania School of Medicine and the School of Arts and Sciences have shown that a well-known protein structure acts as a molecular spring, explaining one way that clots may stretch and bend under such physical stresses as blood flow. They report their findings in a Letter in the latest online edition of the Biophysical Journal. This knowledge will inform researchers about clot physiology in such conditions as wound healing, stroke, and cardiovascular disease.
Clots are a three-dimensional network of fibers, made up primarily of the blood protein fibrinogen, which is converted to fibrin during clotting. A blood clot needs to have the right degree of stiffness and plasticity to stem the flow of blood when tissue is damaged, yet be flexible enough so that it does not block blood flow and cause heart attacks and strokes.
In previous research, senior author John W. Weisel, PhD, Professor of Cell and Developmental Biology, measured the elastic properties of individual fibers and found that the fibers, which are long and very thin, bend much more easily than they stretch, suggesting that clots deform in flowing blood or under other stresses, primarily by the bending of their fibers.
The current research extends those earlier findings to the molecular level, suggesting a way that individual fibers flex-by the unraveling of the three, tightly twisted rod-like regions within fibrinogen molecules, called alpha-helical coiled-coils. The researchers measured this change by pulling engineered strands of fibrinogen molecules using an atomic force microscope. This alpha-helical coiled-coil "spring" is a common motif in protein structure, first identified more than 50 years ago and so its stretchiness may have broader implications in biology and medicine.
By understanding mechanical processes at the molecular level, it may eventually be possible to see how they relate to the mechanical properties of single fibers and a whole clot. This knowledge may enable researchers to make predictions about the function of differently formed fibrin clots in the circulating blood or in a wound. For example, when clots are not stiff enough, problems with bleeding arise, and when clots are too stiff, there may be problems with thrombosis, which results when clots block the flow of blood. First author André Brown, a physics graduate student at Penn, notes that this research is a first step towards understanding the mechanics of the relationship between clot elasticity and disease.
Recent research by other scientists showed that a fibrin fiber could stretch four to five times its original length before snapping. "This is among the most extensible, or stretchy, of polymers that anyone has ever found," says Weisel. "But, how is the stretching happening at a molecular level? We think part of it has to be the unfolding of certain parts of the fibrin molecule, otherwise how can it stretch so much?"
Previous research from senior coauthor Dennis Discher, PhD, Professor in the Physics and Cell & Molecular Biology graduate groups, suggested the possibility that alpha-helical structures in some blood-cell proteins unfold at low levels of mechanical force. But "it wasn't known before that the coiled coil region of the fibrinogen molecule would be the part to unfold under the stress induced by the atomic force microscope," notes Brown.
Once the origins of the mechanical properties of clots are well understood, it may be possible to modulate those properties, note the study authors. "If we can change a certain parameter perhaps we can make a clot that's more or less stiff," explains Weisel. For example, various peptides or proteins, such as antibodies, bind specifically to fibrin, affecting clot structure. The idea would be to use such compounds in people to alter the properties of the clot, so it can be less obstructive and more easily dissolved.
In the future, the researchers will examine other processes at the molecular and fiber levels that may be responsible for the mechanical properties of clots to eventually develop a model that can then be used to predict the effect of changes at one scale on clot properties at other scales. Such a model should be useful for developing prophylactic and therapeutic treatments for many aspects of cardiovascular disease and stroke, suggest the investigators.
University of Pennsylvania School of Medicine
The current research extends those earlier findings to the molecular level, suggesting a way that individual fibers flex-by the unraveling of the three, tightly twisted rod-like regions within fibrinogen molecules, called alpha-helical coiled-coils. The researchers measured this change by pulling engineered strands of fibrinogen molecules using an atomic force microscope. This alpha-helical coiled-coil "spring" is a common motif in protein structure, first identified more than 50 years ago and so its stretchiness may have broader implications in biology and medicine.
By understanding mechanical processes at the molecular level, it may eventually be possible to see how they relate to the mechanical properties of single fibers and a whole clot. This knowledge may enable researchers to make predictions about the function of differently formed fibrin clots in the circulating blood or in a wound. For example, when clots are not stiff enough, problems with bleeding arise, and when clots are too stiff, there may be problems with thrombosis, which results when clots block the flow of blood. First author André Brown, a physics graduate student at Penn, notes that this research is a first step towards understanding the mechanics of the relationship between clot elasticity and disease.
Recent research by other scientists showed that a fibrin fiber could stretch four to five times its original length before snapping. "This is among the most extensible, or stretchy, of polymers that anyone has ever found," says Weisel. "But, how is the stretching happening at a molecular level? We think part of it has to be the unfolding of certain parts of the fibrin molecule, otherwise how can it stretch so much?"
Previous research from senior coauthor Dennis Discher, PhD, Professor in the Physics and Cell & Molecular Biology graduate groups, suggested the possibility that alpha-helical structures in some blood-cell proteins unfold at low levels of mechanical force. But "it wasn't known before that the coiled coil region of the fibrinogen molecule would be the part to unfold under the stress induced by the atomic force microscope," notes Brown.
Once the origins of the mechanical properties of clots are well understood, it may be possible to modulate those properties, note the study authors. "If we can change a certain parameter perhaps we can make a clot that's more or less stiff," explains Weisel. For example, various peptides or proteins, such as antibodies, bind specifically to fibrin, affecting clot structure. The idea would be to use such compounds in people to alter the properties of the clot, so it can be less obstructive and more easily dissolved.
In the future, the researchers will examine other processes at the molecular and fiber levels that may be responsible for the mechanical properties of clots to eventually develop a model that can then be used to predict the effect of changes at one scale on clot properties at other scales. Such a model should be useful for developing prophylactic and therapeutic treatments for many aspects of cardiovascular disease and stroke, suggest the investigators.
University of Pennsylvania School of Medicine
Blood Clot Current Events and Blood Clot News RSSNew tool for helping pediatric heart surgery
A team of researchers at the University of California, San Diego and Stanford University has developed a way to simulate blood flow on the computer to optimize surgical designs.
Canadian scientists link fat hormone to death from potentially deadly blood infection
A new Canadian study has found that lower-than-normal levels of a naturally-occurring fat hormone may increase the risk of death from sepsis-an overwhelming infection of the blood which claims thousands of lives each year.
Lung scintigraphy more reliable than CTA in excluding pulmonary embolism in pregnant patients
A medical imaging procedure known as lung scintigraphy may be more reliable than pulmonary CT angiography (CTA) for identifying or excluding pulmonary embolism (PE) in pregnant patients.
Clots traveling from lower veins may not be the cause of pulmonary embolism in trauma patients
A report from a team of Massachusetts General Hospital (MGH) physicians calls into question the longstanding belief that pulmonary embolism (PE) - the life-threatening blockage of a major blood vessel in the lungs - is caused in trauma patients by a blood clot traveling from vessels deep within the legs or lower torso.
Women with Atrial Fibrillation Are at Significantly Higher Risk of Stroke and Death Compared to Men and Receive Less Attention
Even though the incidence of atrial fibrillation is higher in men than women, a review of past studies and medical literature completed by cardiac experts at Rush University Medical Center shows that women are more likely than men to experience symptomatic attacks, a higher frequency of recurrences, and significantly higher heart rates during atrial fibrillation, which increases the risk of stroke.
Image-guided treatment for deep venous thrombosis could improve patients' long-term outcomes
Deep Venous Thrombosis (DVT) is a serious condition that involves the formation of a blood clot inside of a deep vein usually in the legs. A patient with DVT is typically treated with anticoagulants (blood thinners) however researchers have found that image-guided interventional radiology procedures may play a more central role in the long-term treatment of DVT.
Two treatment innovations improve heart function after heart attack
Supersaturated oxygen (SSO2) administered during catheter-based treatments for heart attack can significantly reduce heart muscle damage, according to a new study reported in Circulation: Cardiovascular Interventions, a journal of the American Heart Association.
Scientists Find New No-Needle Approach to Prevent Blood Clots
The dean of the University of Oklahoma College of Public Health and a team of scientists worldwide have found a better way to prevent deadly blood clots after joint replacement surgery - a major problem that results in thousands of unnecessary deaths each year. The research appears this week in the New England Journal of Medicine.
The risk of developing deep vein thrombosis during a flight is often overestimated
The risk of developing deep vein thrombosis during a long flight is often overestimated.
Fatigue common after myocardial infarction
Half of all patients who undergo myocardial infarction are experiencing onerous fatigue four months after the infarction.
More Blood Clot Current Events and Blood Clot News Articles
 |
BLOOD CLOT: In Combat with the Patrols Platoon, 3 Para, Afghanistan 2006 by Jake Scott (Author) "As you know 'blood clot' means blood cells coming together to form a strong clot that forms and sticks together to keep the wound sealed enabling it to repair. The Parachute Regiment's 'blood clot' acts the same, whether downtown scrapping or in some far away country fighting alongside each other. Our maroon berets come together, they stick together, they close ranks forming the blood clot and fight against anything that comes their way." (Jake Scott) When the 3 Para battle group departed for Helmand Province, south Afghanistan, nobody really knew what to expect. Within a month of being on the ground the first of many contacts between the Taliban and British forces began. The British government and media were in shock - for the men on the ground it was what they were trained for.... |
 |
Celox First Aid Temporary Traumatic Wound Treatment - 15g Pouch by SAMMedical CELOXTM is the newest generation of emergency hemostatic agents. Simpler to use and safer than older technologies, CELOX granules quickly control even severe arterial bleeding. Just pour it in, pack it, and apply pressure. No specific training is required. CELOX is not exothermic and won't burn the victim or caregiver. And CELOX works in hypothermic conditions and clots Heparinized blood. CELOX is safe to use for the entire body including head, neck and chest wounds. Most importantly, CELOX can be used instantly and without hesitation as a fast, safe and simple emergency treatment for serious bleeding. Average Time to Clot Whole Blood: 30.5 Seconds Average Time to Clot Heparinized Blood: 48 Seconds Controls Major Arterial Bleeding CELOXs unusual properties have been confirmed in wound... |
 |
Z-Med QuikClot - Home (1 pack) by Z-Medica QuikClot Sport brand hemostatic agent is based on the same QuikClot brand hemostatic agent used by the US military, federal agencies, EMS, police and fire departments everywhere. Remove the QuikClot Sport from the package, apply to the wound using pressure and stop the bleeding fast. QuikClot Sport is ideal for schools, individual and team sports, wilderness medicine and even home use. This product is the perfect size for scalp lacerations or bleeding where a bandage is not enough. Every home first aid kit and sports athletic trainer's first aid kit should contain QuikClot Sport brand hemostatic. |
 |
Blood Clot Lovindeer (Primary Contributor) |
 |
Deadly Blood Clots: The Dangers of Venous Thromboembolism (Home Use) Part of the award winning public television series Healthy Body/Healthy Mind. The dangers of blood clots are well known: they can cause heart attacks, strokes and other potentially fatal conditions. But there's another medical hazard that occurs when the blood clot lives quietly deep in the veins of the legs. And when a part of this blood clot breaks off and travels to the lung the result can be almost instantaneous death. This type of blood clot is called deep vein thrombosis and when it travels to the lungs its called pulmonary embolism. And these are two manifestations of the condition known as venous thromboembolism. In this program we will examine the symptoms and risk factors of venous thromboembolism, see who should be tested for clotting disorders and highlight the latest... |
 |
Blood Clots & Strokes: A Guide for Parents & Little Folks by Maureen Andrew M.D. (Author), Maureen Andrew (Author), Maureen Andrew (Author) Blood clots occur in children who have major primary illnesses. For many parents, the news of a blood clot is another in a long line of complication. In some children, the clot is a surprise complication which impairs otherwise good recovery. Less commonly, the clot or stroke is a sudden devasting blow to an otherwise well child. Blood Clots and Strokes: A Guide for Parents and Little Folks is formatted as specific questions and answers which allow for quick and easy reference, by the parents. The questions used in the text are those most commonly asked. Blood Clots and Strokes: A Guide for Parents and Little Folks will endeavor to provide parents with an understanding which will enable them to appreciate the need for individual consideration in the care of their children. |
 |
Arriva Travel-Tec- SCT Travel Legwear (Womens, Black) by Sox Shop LIMITED TIME OFFER! We are so confident that you will love these socks, we are offering them at nearly half of what they retail for! Combined with the circulatory advantages of Smart Compression Technology®, Travel-Tec Holofiber® Legwear provides unparalleled comfort for all of life's journeys. We have done our research and find our socks to be competitivly priced, as travel legwear(with compression) can cost upwards of $50! These socks represent the best in comfort and value, as they contain the most allowable amount of linear compression (12-16mmHG) in a non-medical product. We stand behind all our products with our No Risk Guarantee and are confident you will not find a better travel sock, especially with the benefits of holofiber and SCT(Smart Compression Technology). Holofiber... |
 |
Olympian Labs Nattokinase, 100mg by Olympian Labs Nattokinase is a serine protease type enzyme derived from fermented soybeans. Research has shown nattokinase to support healthy coagulation of blood and enhance fibrinolytic (breaking up of clots) activity. Fibrin is a protein that, when activated, forms fibrinogen which is responsible for blood clotting. OL uses only the highly bioavailable, proprietary extract of natto. |
|
Deadly Blood Clots: The Dangers Of Venous Thromboembolism Directed By: Information Television Network | |
 |
Formula BAC+, 1 fl oz by Wisdom of the Ages BAC stands for Blood Anti-Clot. The major herbs composing this tincture have been used in China for thousands of years to assist the body in the treatment of blood-related disorders without side-effects. They are used to help circulation, treat heart problems, reduce cholesterol in the arteries and alleviate varicose veins. This tincture acts as a tonic for both the liver and the heart, strengthening the heart without affecting the heart rate. BAC+ has been shown effective in helping many chronic disorders. |
| © 2009 BrightSurf.com |