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Nexavar® In Combination With Chemotherapy Shown To Extend Progression-Free Survival In Patients With Advanced Breast Cancer
Bayer HealthCare AG and Onyx Pharmaceuticals, Inc. announced that their first cooperative group-sponsored randomized Phase II trial in advanced metastatic breast cancer met its primary endpoint of progression-free survival. The study evaluated Nexavar® (sorafenib) tablets in combination with the oral chemotherapeutic, capecitabine, in patients with locally advanced or metastatic HER-2 negative breast cancer. Study findings demonstrated that the median progression-free survival was extended in patients treated with Nexavar and capecitabine compared to patients receiving capecitabine and placebo. These results were statistically significant (p-value = 0.0006). In this trial, the safety and tolerability of the combination was as expected and did not show any new or unexpected toxicities. A complete data analysis from this study is expected to be presented at an upcoming scientific meeting.
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Behavioral Effects Of Addiction Enhanced By Cocaine-Linked Genes
New research sheds light on how cocaine regulates gene expression in a crucial reward region of the brain to elicit long-lasting changes in behavior. The study, published by Cell Press in the May 14th issue of the journal Neuron, provides exciting insight into the molecular pathways regulated by cocaine and may lead to new strategies for battling drug addiction.
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Study Examines Effects Of Stress On Weight Gain In US Population
Stressing out can cause people to gain weight, according to a study appearing in the July 15 issue of the American Journal of Epidemiology. This new study is believed to be one of the first of its kind to look at the relationship between weight gain and multiple types of stress - job-related demands, difficulty paying bills, strained family relationships, depression or anxiety disorder - in the U.S. population.
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Team Uncovers The Molecular Basis For The Regulation Of Blood Clotting

By applying cutting-edge techniques in single-molecule manipulation, researchers at Harvard University have uncovered a fundamental feedback mechanism that the body uses to regulate the clotting of blood. The finding, which could lead to a new physical, quantitative, and predictive model of how the body works to respond to injury, has implications for the treatment of bleeding disorders. A team, co-led by Timothy A. Springer, Latham Family Professor of Pathology at Harvard Medical School and Children"s Hospital Boston, and Wesley P. Wong, Rowland Junior Fellow and a Principal Investigator at the Rowland Institute at Harvard, reported its discovery about the molecular basis for the feedback loop responsible for hemostasis in the June 5th issue of Science. "The human body has an incredible ability to heal from life"s scrapes and bruises," explains Wong. "A central aspect of this response to damage is the ability to bring bleeding to end, a process known as hemostasis. Yet regulating hemostasis is a complex balancing act." Too much hemostatic activity can lead to an excess of blood clots, resulting in a potentially deadly condition known as thrombosis. If too little hemostatic activity occurs in the body, a person may bleed to death. To achieve the proper balance, the body relies on a largely mechanical feedback system that relies on the miniscule forces applied by the circulation system on a molecular "force sensor" known as the A2 domain of the blood clotting protein von Willebrand factor (VWF). By manipulating single molecules of this A2 domain, the researchers found that the A2 domain acts as a highly sensitive force sensor, responding to very weak tensile forces by unfolding, and losing much of its complex three-dimensional organization. This unfolding event allows the cutting of the molecule by an enzyme known as ADAMTS13. "In the body, these cutting events decrease hemostatic potential and also enable blood clots to be trimmed in size. The system is so finely tuned that the A2 shear sensor is able to regulate the size of VWF within the blood stream, maintaining the optimal size for responding properly to traumas," says Wong. To make the discovery, the team relied upon an "optical tweezers" system developed in Wong"s lab. The tweezers are capable of applying miniscule forces to individual molecules while observing nanoscale changes in their length. Such manipulations enabled the researchers to characterize both the unfolding and refolding rates of single A2 molecules under force, as well as their interaction with the enzyme. The molecular construct was created in Dr. Springer"s lab, and consisted of an A2 domain connected to two DNA handles for manipulation. This elegant molecular system allowed the VWF "shear sensor" to be carefully studied and tested in isolation. Ultimately, this work enhances the understanding of how the body is able to regulate the formation of blood clots, and is step towards a physical, quantitative, and predictive model of how the body responds to injury. It also gives insight into how bleeding disorders, such as type 2A von Willebrand disease, disrupt this regulation system, potentially leading to new avenues for treatment and diagnosis. Notes: Wong and Springer"s co-authors include Xiaohui Zhang, Kenneth Halvorsen, and Cheng-Zhong Zhang. The authors acknowledge the support of the National Institutes of Health, the American Heart Association, and the Rowland Junior Fellows program. Michael Patrick Rutter Harvard University


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